Recuperative generation-absorption system and recuperative second-type absorption heat pump

Abstract

A recuperative generation-absorption system is formed by generator, the first absorber, the second absorber, the first solution heat exchanger, the second solution heat exchanger, the steam bleeding chamber, the solution pump and the second solution pump or added the third solution pump too. In the system, the first solution pump connects generator, the first solution heat exchanger, the first absorber, the steam bleeding chamber in turn. After that, the second solution pump connects the second solution heat exchanger, the second absorber, the first absorber, the first solution heat exchanger and generator one by one. Then the tandem cycle is formed. The independent cycle can be formed as follows. The first solution pump connects generator, the first solution heat exchanger, the first absorber and the second solution pump connects the steam bleeding chamber, the second solution heat exchanger and the second absorber in file.

Description

BACKGROUND OF THE PRESENT INVENTION

1. Field of Invention

The present invention belongs to the area of low-temperature residual heat utilization.

2. Description of Related Arts

Under the premise that the heat pump can promote the residual heat temperature to the needed level of the user, adopting the absorption heat pump (AHP) technology to develop residual heat can bring a better energy conservation, environmental protection and economic interest. Promoting the heating temperature of the heat pump, using the lower temperature of the waste heat resources and improving the utilization rate of the waste heat resources are the main directions of people's efforts.

To get a higher heating temperature and performance index of the AHP, people explored several different effects and different stages units at first and different heat pump processes are compounded by many ways such as adding the heating-side, increasing the process of heating and so on. Then they got more meticulous effects and stages which are corresponding to the corresponding performance index. However, these single-effect or single-stage units own some deficiencies that each single-effect or single-stage units has the right work parameter and performance index just in a particular situation. For example, a single two level units has a high heating temperature while its performance index is low.

Seeing from the internal process of the units, the key to improve the heating temperature of the second-type absorption heat pump is to enhance the export solution concentration of the absorber. That means to promote the export solution concentration of the generator. It can improve the heating temperature of the corresponding units by using the recuperative principle to the generation-absorption process of the solution, establishing the recuperative generation-absorption system and compounding with different effects and different stages units. At the same time, adopting the way of recuperative heat can realize two-terminal heating or multiterminal heating of the second-type absorption heat pump which is useful for improving the performance index of the units.

SUMMARY OF THE PRESENT INVENTION

An main object of the present invention is to provide a recuperative generation-absorption system of solution tandem cycle and a recuperative generation-absorption system of solution independent loop at first, then add some components in the two recuperative generation-absorption systems to gain the second-type absorption heat pump with a higher heating temperature which can be called the recuperative second-type absorption heat pump too. The specific contents of the present invention are described as follows.

1. One of the recuperative generation-absorption systems in this invention is the solution tandem cycle recuperative generation-absorption system which can be mainly formed by the generator, the first absorber, the second absorber, the first solution heat exchanger, the second solution heat exchanger, the steam bleeding chamber, the first solution pump, the second solution pump or plus the third solution pump.

The concentrated solution pipe of generator passes through the first solution pump, the first solution heat exchanger and the first absorber and then connects the steam bleeding chamber. The concentrated solution pipe of the steam bleeding chamber passes through the second solution pump, the second solution heat exchanger and then connects the second absorber. The dilute solution pipe of the second absorber passes through the second solution heat exchanger, the third solution pump if the system has it and then connects the first absorber. The dilute solution pipe of the first absorber passes through the first solution heat exchanger and then connects generator.

Generator has the pipe of residual heat medium or the pipe of thermal driving medium and the channel of refrigerant vapor which separately connect external. The first absorber has the pipe of heated medium and the channel of refrigerant vapor which separately connect external. The second absorber has the channel of refrigerant vapor and the channel of heated medium which separately connect external. The steam bleeding chamber has the channel of refrigerant vapor which connects external.

The dilute solution of generator is heated by the residual heat medium or the thermal driving medium and releases refrigerant vapor. The concentrated solution of generator flows through the first solution pump, the first solution heat exchanger, the first absorber in which it absorbs heat and a part of it is vaporization and then enters the steam bleeding chamber which releases refrigerant vapor. The concentrated solution pipe of the steam bleeding chamber flows through the second solution pump, the second solution heat exchanger and then enters the second absorber in which it absorbs the refrigerant vapor coming from outside the system and releases heat to the heated medium at the same time.

The dilute solution of the second absorber flows through the second solution heat exchanger, the third solution pump if the system has it and then enters the first absorber in which it absorbs the refrigerant vapor coming from outside the system and heats up the solution which flows through the first absorber and meets the heat demand of heated medium. The dilute solution of the first absorber flows through the first solution heat exchanger and then flows back to generator in which it releases refrigerant vapor. Then we gain the recuperative generation-absorption system of solution tandem cycle.

When the first absorber haven't the pipe of heated medium connected external, the heat which is released by absorbing the refrigerant vapor in the first absorber is used to heat the solution which flows through the first absorber.

2. One or two of the recuperative generation-absorption systems in this invention is solution independent loop recuperative generation-absorption system which can be mainly formed by generator, the first absorber, the second absorber, the first solution heat exchanger, the second solution heat exchanger, the steam bleeding chamber, the first solution pump, the second solution pump.

The concentrated solution pipe of generator passes through the first solution pump, the first solution heat exchanger and then connects the first absorber. The dilute solution pipe of the first absorber passes through the first solution heat exchanger and then connects generator. The dilute solution pipe of the second absorber passes through the second solution heat exchanger, the first absorber and then connects the steam bleeding chamber. The concentrated solution pipe of the steam bleeding chamber passes through the second solution pump, the second solution heat exchanger and then connects the second absorber.

Generator has the pipe of residual heat medium or the pipe of thermal driving medium and the channel of refrigerant vapor which separately connect external. The first absorber has the pipe of heated medium and the channel of refrigerant vapor which separately connect external. The second absorber has the channel of refrigerant vapor and the channel of heated medium which separately connect external. The steam bleeding chamber has the channel of refrigerant vapor which connects external.

The dilute solution of generator is heated by the residual heat medium or the thermal driving medium and releases refrigerant vapor at the same time. The concentrated solution of generator flows through the first solution pump, the first solution heat exchanger and then enters the first absorber in which it absorbs the refrigerant vapor coming from outside the system and heats up the solution which flows through the first absorber and meets the heat demand of heated medium. The dilute solution of the first absorber flows through the first solution heat exchanger and then flows back to generator. The solution which flows through the first absorber absorbs heat and a part of it is vaporization and then enters the steam bleeding chamber which releases refrigerant vapor. The concentrated solution pipe of the steam bleeding chamber flows through the second solution pump, the second solution heat exchanger and then enters the second absorber in which it absorbs the refrigerant vapor coming from outside the system and releases heat to the heated medium at the same time. The dilute solution of the second absorber flows through the second solution heat exchanger, the first absorber and then enters the steam bleeding chamber. Then we gain the recuperative generation-absorption system with solution independent loop.

When the first absorber haven't the pipe of heated medium connected external, the heat which is released by absorbing the refrigerant vapor in the first absorber is used to heat the solution which flows through the first absorber.

In a specific and complete second-type absorption unit, the refrigerant vapor and solution all belong to the working medium of unit. In the above generation-absorption system, the first absorber absorbs the refrigerant vapor of outside the system and releases heat to the solution which flows through the first absorber. Then the solution which enters the first absorber absorbs refrigerant vapor and releases heat. The heat is released by working medium. That the solution which flows through the first absorber absorbs heat can be regarded as absorption heat by working medium. This process is called recuperative heat in terms. In the cycle, working medium releases heat in a process which can be used to meet the absorption of heat by working medium in another process. The generation-absorption systems in this invention are recuperative generation-absorption systems.

According to the needed terminal temperature of heated medium, we need to adjust the amount of vapor released by the solution in the steam bleeding chamber. It depends on the quantity of heating load absorbed by the solution which flows through the first absorber. The less the heating load is, the less the amount of refrigerant vapor which separated from the solution in the steam bleeding chamber is. At the same time, the concentration of solution which enters the second absorber increases less and the terminal temperature of heated medium is promoted much less too. What's more, the corresponding performance index of the second absorber is more close to the first absorber's on the condition that the quantity of refrigerant vapor absorbed by the first absorber and the second absorber is consistent. In a certain range, the second-type absorption heat pump which is combined with this invention can achieve high-temperature heating with a higher performance index.

3. The first one of the recuperative generation-absorption systems in this invention, which is described in 1 or 2 of claims, is the recuperative single-stage single-effect second-type absorption heat pump which can be mainly formed by adding condenser, the first evaporator, liquid refrigerant pump, the second evaporator, the throttle and taking residual heat medium as thermal driving medium.

That the refrigerant vapor channel of generator connects external can be considered as that the refrigerant vapor channel of generator connects condenser. That the refrigerant vapor channel of the steam bleeding chamber connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber connects condenser. That the refrigerant vapor channel of the first absorber connects external can be considered as that the refrigerant vapor channel of the second evaporator connects the first absorber. That the refrigerant vapor channel of the second absorber connects external can be considered as that the refrigerant vapor channel of the first evaporator connects the second absorber. The liquid refrigerant channel of condenser passes through liquid refrigerant pump and then connects the first evaporator. The liquid refrigerant channel of the first evaporator passes through the throttle and then connects the second evaporator. Condenser has the pipe of cooling medium which connects external. The first evaporator and the second evaporator also have the pipe of residual heat medium which separately connects external.

When the system hasn't the second evaporator and the throttle, the channel of refrigerant vapor in the first evaporator separately connects the first absorber and the second absorber.

4. The second one of the recuperative generation-absorption systems in this invention, which is described in 1 or 2 of claims, is the recuperative single-stage single-effect second-type absorption heat pump in which absorption-evaporator separately provide refrigerant vapor to the first absorber and the second absorber. And it can be formed by adding condenser, evaporator, absorption—evaporator, liquid refrigerant pump, the throttle, the third solution heat exchanger and taking residual heat medium as thermal driving medium. We can change that the dilute solution pipe of the first absorber passes through the first solution heat exchanger and then connects generator to that the dilute solution pipe passes through the first solution heat exchanger and then connects generator after that the dilute solution pipe of the first absorber passes through the third solution heat exchanger and then connects absorption-evaporator.

We adjust that the concentrated solution pipe of generator passes through the first solution pump, the first solution heat exchanger and then connects the first absorber or the concentrated solution pipe of generator passes through the first solution pump, the first solution heat exchanger, the first absorber and then connects the steam bleeding chamber to that the concentrated solution pipe of generator passes through the first solution pump, the first solution heat exchanger, the third solution heat exchanger and then connects the first absorber or the concentrated solution pipe of generator passes through the first solution pump, the first solution heat exchanger, the third solution heat exchanger, the first absorber and then connects the steam bleeding chamber.

That the refrigerant vapor channel of generator connects external can be considered as that the refrigerant vapor channel of generator connects condenser. That the refrigerant vapor channel of the steam bleeding chamber connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber connects condenser. That the refrigerant vapor channel of the first absorber and the second absorber separately connects external can be considered as that the refrigerant vapor channel of absorption-evaporator separately connects the first absorber and the second absorber after that the liquid refrigerant channel of condenser passes through liquid refrigerant pump and then connects absorption-evaporator. The liquid refrigerant pipe of liquid refrigerant pump passes through the throttle and then connects evaporator. The refrigerant vapor channel of evaporator connects absorption-evaporator. Condenser has the pipe of cooling medium connects external. Evaporator has the pipe of residual heat medium which connects external.

5. The second one of the recuperative generation-absorption systems in this invention, which is described in 1 or 2 of claims, is the recuperative single generator two-stage second-type absorption heat pump in which absorption-evaporator separately provide refrigerant vapor to the first absorber and the second absorber. And it can be formed by adding condenser, evaporator, absorption-evaporator, the first liquid refrigerant pump, the second liquid refrigerant pump, the third solution heat exchanger and taking residual heat medium as thermal driving medium.

We adjust that the dilute solution pipe of the first absorber passes through the first solution heat exchanger and then connects generator to that the dilute solution pipe of absorption-evaporator passes through the first solution heat exchanger and then connects generator after that the dilute solution pipe of the first absorber passes through the third solution heat exchanger and then connects absorption-evaporator.

We adjust that the concentrated solution pipe of generator passes through the first solution pump, the first solution heat exchanger and then connects the first absorber or the concentrated solution pipe of generator passes through the first solution pump, the first solution heat exchanger, the first absorber and then connects the steam bleeding chamber to that the concentrated solution pipe of generator passes through the first solution pump, the first solution heat exchanger, the third solution heat exchanger and then connects the first absorber or the concentrated solution pipe of generator passes through the first solution pump, the first solution heat exchanger, the third solution heat exchanger, the first absorber and then connects the steam bleeding chamber.

That the refrigerant vapor channel of generator connects external can be considered as that the refrigerant vapor channel of generator connects condenser. That the refrigerant vapor channel of the steam bleeding chamber connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber connects condenser. That the refrigerant vapor channel of the first absorber and the second absorber separately connects external can be considered as that the refrigerant vapor channel of absorption-evaporator separately connects the first absorber and the second absorber after that the liquid refrigerant channel of evaporator passes through the second liquid refrigerant pump and then connects absorption-evaporator. Condenser has the pipe of liquid refrigerant which passes through the first liquid refrigerant pump and then connects evaporator. Evaporator has the refrigerant vapor channel which connects absorption-evaporator. Condenser has the pipe of cooling medium which connects external. Evaporator has the pipe of residual heat medium which connects external.

6. The fourth one of the recuperative generation-absorption systems in this invention, which is described in 1 or 2 of claims, is the recuperative single generator three-stage second-type absorption heat pump in which two-stage absorption-evaporator separately provide refrigerant vapor to the first absorber and the second absorber. And it can be formed by adding condenser, evaporator, one-level absorption-evaporator, two-stage absorption—evaporator, the liquid refrigerant pump, the first throttle, the second throttle, the third solution heat exchanger, the fourth solution heat exchanger and taking residual heat medium as thermal driving medium.

We adjust that the dilute solution pipe of the first absorber passes through the first solution heat exchanger and then connects generator to that the dilute solution pipe of the first absorber passes through the third solution heat exchanger and then connects two-stage absorption-evaporator. The dilute solution pipe of two-stage absorption-evaporator passes through the fourth solution heat exchanger and then connects one-level absorption-evaporator. The dilute solution pipe of one-level absorption-evaporator passes through the first solution heat exchanger and then connects generator.

We adjust that the concentrated solution pipe of generator passes through the first solution pump, the first solution heat exchanger and then connects the first absorber or the concentrated solution pipe of generator passes through the first solution pump, the first solution heat exchanger, the first absorber and then connects the steam bleeding chamber to that the concentrated solution pipe of generator passes through the first solution pump, the first solution heat exchanger, the fourth solution heat exchanger, the third solution heat exchanger and then connects the first absorber or the concentrated solution pipe of generator passes through the first solution pump, the first solution heat exchanger, the fourth solution heat exchanger, the third solution heat exchanger, the first absorber and then connects the steam bleeding chamber.

That the refrigerant vapor channel of generator connects external can be considered as that the refrigerant vapor channel of generator connects condenser. That the refrigerant vapor channel of the steam bleeding chamber connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber connects condenser. That the refrigerant vapor channel of the first absorber and the second absorber separately connects external can be considered as that the channel of refrigerant vapor separately connects the first absorber and the second absorber after that the liquid refrigerant channel of condenser passes through the liquid refrigerant pump and then connects two-stage absorption-evaporator. The liquid refrigerant pipe of the liquid refrigerant pump passes through the first throttle and then connects evaporator. The refrigerant vapor channel of evaporator and then connects one-level absorption-evaporator. The refrigerant vapor pipe of the one-level absorption-evaporator connects two-stage absorption-evaporator after that the liquid refrigerant pipe of the liquid refrigerant pump passes through the second throttle and then connects one-level absorption-evaporator.

7. The fifth one of the recuperative generation-absorption systems in this invention, which is described in 1 or 2 of claims, is the recuperative single generator three-stage second-type absorption heat pump in which two-stage absorption-evaporator separately provide refrigerant vapor to the first absorber and the second absorber. And it can be formed by adding condenser, evaporator, one-level absorption-evaporator, two-stage absorption-evaporator, the first liquid refrigerant pump, the third solution heat exchanger, the fourth solution heat exchanger, the second liquid refrigerant pump, the third liquid refrigerant pump and taking residual heat medium as thermal driving medium.

We adjust that the dilute solution pipe of the first absorber passes through the first solution heat exchanger and then connects generator to that the dilute solution pipe of the first absorber passes through the third solution heat exchanger and then connects two-stage absorption-evaporator. The dilute solution pipe of two-stage absorption-evaporator passes through the fourth solution heat exchanger and then connects one-level absorption-evaporator. The dilute solution pipe of one-level absorption-evaporator passes through the first solution heat exchanger and then connects generator.

We adjust that the concentrated solution pipe of generator passes through the first solution pump, the first solution heat exchanger and then connects the first absorber or the concentrated solution pipe of generator passes through the first solution pump, the first solution heat exchanger, the first absorber and then connects the steam bleeding chamber to that the concentrated solution pipe of generator passes through the first solution pump, the first solution heat exchanger, the fourth solution heat exchanger, the third solution heat exchanger and then connects the first absorber or the concentrated solution pipe of generator passes through the first solution pump, the first solution heat exchanger, the fourth solution heat exchanger, the third solution heat exchanger, the first absorber and then connects the steam bleeding chamber.

That the refrigerant vapor channel of generator connects external can be considered as that the refrigerant vapor channel of generator connects condenser. That the refrigerant vapor channel of the steam bleeding chamber connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber connects condenser. That the refrigerant vapor channel of the first absorber and the second absorber separately connects external can be considered as that the refrigerant vapor channel of two-stage absorption-evaporator separately connects the first absorber and the second absorber after that evaporator passes through the second liquid refrigerant pump, the third liquid refrigerant pump and then connects two-stage absorption-evaporator. The refrigerant vapor channel of the one-level absorption-evaporator connects two-stage absorption-evaporator after that the liquid refrigerant pipe of the second liquid refrigerant pump connects one-level absorption-evaporator.

The liquid refrigerant pipe of condenser passes through the first liquid refrigerant pump and then connects evaporator. Evaporator has the channel of refrigerant vapor which connects one-level absorption-evaporator. Condenser has the pipe of cooling medium which connects external. Evaporator has the pipe of residual heat medium which connects external.

8. The sixth one of the recuperative generation-absorption systems in this invention, which is described in 1 or 2 of claims, is the recuperative two-generator two-stage second-type absorption heat pump in which absorption-evaporator separately provide refrigerant vapor to the first absorber, the second absorber and generator. And it can be formed by adding condenser, evaporator, absorption-evaporator, the first liquid refrigerant pump, the first throttle, low-temperature generator, the fourth liquid refrigerant pump, the second throttle and the third solution heat exchanger.

We adjust that the dilute solution pipe of the first absorber passes through the first solution heat exchanger and then connects generator to that the dilute solution pipe of the first absorber passes through the first solution heat exchanger and then connects absorption-evaporator. The dilute solution pipe of absorption-evaporator passes through the third solution heat exchanger and then connects low-temperature generator. The concentrated solution pipe of low-temperature generator passes through the fourth liquid refrigerant pump, the third solution heat exchanger and then connects generator.

That the refrigerant vapor channel of the first absorber, the second absorber connects external can be considered as that the refrigerant vapor channel of absorption-evaporator separately connects the first absorber and the second absorber after that the liquid refrigerant pipe of condenser passes through the liquid refrigerant pump and then connects absorption-evaporator. That the thermal driving medium pipe of generator connects external can be considered as that the liquid refrigerant pipe of the liquid refrigerant pump connects absorption-evaporator, the refrigerant vapor pipe of absorption-evaporator connects generator and the liquid refrigerant pipe of generator passes through the first throttle and then connects condenser. A part of the refrigerant vapor produced by absorption-evaporator can be used as thermal driving medium. That the refrigerant vapor channel of generator connects external can be considered as that the refrigerant vapor channel of generator connects condenser. That the refrigerant vapor channel of the steam bleeding chamber connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber connects condenser. The liquid refrigerant pipe of the liquid refrigerant pump passes through the second throttle and then connects evaporator. Evaporator has the pipe of residual heat medium which connects external and the channel of refrigerant vapor which connects absorption-evaporator. Low-temperature generator has the pipe of residual heat medium which connects external and the channel of refrigerant vapor which connects condenser.

9. The seventh one of the recuperative generation-absorption systems in this invention, which is described in 1 or 2 of claims, is the recuperative two-generator two-stage second-type absorption heat pump in which absorption-evaporator separately provide refrigerant vapor to the first absorber, the second absorber and generator. And it can be formed by adding condenser, evaporator, absorption-evaporator, the first liquid refrigerant pump, throttle, low-temperature generator, the fourth liquid refrigerant pump, the second liquid refrigerant pump and the third solution heat exchanger.

We adjust that the dilute solution pipe of the first absorber passes through the first solution heat exchanger and then connects generator to that the dilute solution pipe of the first absorber passes through the first solution heat exchanger and then connects absorption-evaporator. The dilute solution pipe of absorption—evaporator passes through the third solution heat exchanger and then connects low-temperature generator. The concentrated solution pipe of low-temperature generator passes through the fourth liquid refrigerant pump, the third solution heat exchanger and then connects generator.

That the refrigerant vapor channel of the first absorber, the second absorber connects external can be considered as that the refrigerant vapor channel of absorption-evaporator separately connects the first absorber and the second absorber after that the liquid refrigerant pipe of evaporator passes through the second liquid refrigerant pump and then connects absorption-evaporator. That the thermal driving medium pipe of generator connects external can be considered as that the liquid refrigerant pipe of the second liquid refrigerant pump connects absorption-evaporator, the refrigerant vapor pipe of absorption-evaporator connects generator and the liquid refrigerant pipe of generator passes through the first throttle and then connects condenser. A part of the refrigerant vapor produced by absorption-evaporator can be used as thermal driving medium.

That the refrigerant vapor channel of generator connects external can be considered as that the refrigerant vapor channel of generator connects condenser. That the refrigerant vapor channel of the steam bleeding chamber connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber connects condenser. The liquid refrigerant pipe of condenser passes through the first liquid refrigerant pump and then connects evaporator. Evaporator has the pipe of residual heat medium which connects external and the channel of refrigerant vapor which connects absorption-evaporator. Low-temperature generator has the pipe of residual heat medium which connects external and the channel of refrigerant vapor which connects condenser.

10. The eighth one of the recuperative generation-absorption systems in this invention, which is described in 1 of claims, is the recuperative single stage tandem double-effect second-type absorption heat pump which can be formed by adding the second generator, condenser, the first evaporator, the first throttle, the liquid refrigerant pump, the second evaporator, the second throttle.

Taking the second generator as high-pressure generator, We adjust that the concentrated solution pipe of the first generator passes through the first solution pump, the first solution heat exchanger, the first absorber and then connects the steam bleeding chamber to that the concentrated solution pipe of the first generator passes through the first solution pump and then connects the second generator. The concentrated solution pipe of the second generator passes through the first solution heat exchanger, the first absorber and then connects the steam bleeding chamber.

After that the thermal driving medium pipe of the first generator connects external can be considered as that the refrigerant vapor channel of the second generator connects the first generator, the liquid refrigerant pipe of the first generator passes through the first throttle and then connects condenser. Using the refrigerant vapor produced by the second generator as the thermal driving medium of the first generator, that the refrigerant vapor channel of the first generator connects external can be considered as that the refrigerant vapor channel of the first generator connects condenser.

That the refrigerant vapor channel of the steam bleeding chamber connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber connects condenser. That the refrigerant vapor channel of the first absorber connects external can be considered as that the refrigerant vapor channel of the second evaporator connects the first absorber. That the refrigerant vapor channel of the second absorber connects external can be considered as that the refrigerant vapor channel of the first evaporator connects the second absorber. The liquid refrigerant pipe of condenser passes through the liquid refrigerant pump and then connects the first evaporator. The liquid refrigerant pipe of the first evaporator passes through the second throttle and then connects the second evaporator. Condenser has the pipe of cooling medium which connects external. The second generator, the first evaporator and the second evaporator has the pipe of residual heat medium which separately connects external. When the system hasn't the second evaporator and the second throttle, the refrigerant vapor channel of the first evaporator separately connects the first absorber and the second absorber.

11. The ninth one of the recuperative generation-absorption systems in this invention, which is described in 2 of claims, is the recuperative single stage tandem double-effect second-type absorption heat pump which can be formed by adding the third solution pump, the second generator, condenser, the first evaporator, the first throttle, the liquid refrigerant pump, the second evaporator and the second throttle.

Taking the second generator as high-pressure generator, we adjust that the concentrated solution pipe of the first generator passes through the first solution pump, the first solution heat exchanger and then connects the first absorber to that the concentrated solution pipe of the first generator passes through the first solution pump and then connects the second generator. The concentrated solution pipe of the second generator passes through the third solution pump, the first solution heat exchanger and then connects the first absorber.

After that the thermal driving medium pipe of the first generator connects external can be considered as that the refrigerant vapor channel of the second generator connects the first generator, the liquid refrigerant pipe of the first generator passes through the first throttle and then connects condenser. Using the refrigerant vapor produced by the second generator (as the thermal driving medium of the first generator, that the refrigerant vapor channel of the first generator connects external can be considered as that the refrigerant vapor channel of the first generator connects condenser.

That the refrigerant vapor channel of the steam bleeding chamber connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber connects condenser. That the refrigerant vapor channel of the first absorber connects external can be considered as that the refrigerant vapor channel of the second evaporator connects the first absorber. That the refrigerant vapor channel of the second absorber connects external can be considered as that the refrigerant vapor channel of the first evaporator connects the second absorber. The liquid refrigerant pipe of condenser passes through the liquid refrigerant pump and then connects the first evaporator. The liquid refrigerant pipe of the first evaporator passes through the second throttle and then connects the second evaporator. Condenser has the pipe of cooling medium which connects external. The second generator, the first evaporator and the second evaporator have the pipe of residual heat medium which separately connects external. When the system hasn't the second evaporator and the second throttle, the refrigerant vapor channel of the first evaporator separately connects the first absorber and the second absorber.

12. The tenth one of the recuperative generation-absorption systems in this invention, which is described in 2 of claims, is the recuperative single stage tandem double-effect second-type absorption heat pump which can be formed by adding the second generator, condenser, the first evaporator, the first throttle, the liquid refrigerant pump, the second evaporator, the second throttle and the third solution heat exchanger.

Taking the second generator as low-pressure generator, We adjust that the concentrated solution pipe of the first generator passes through the first solution pump, the first solution heat exchanger and then connects the first absorber or the concentrated solution pipe of the first generator passes through the first solution pump, the first solution heat exchanger, the first absorber and then connects the steam bleeding chamber to that the concentrated solution pipe of the first generator passes through the third solution heat exchanger and then connects the second generator. The concentrated solution pipe of the second generator passes through the first solution pump, the third solution heat exchanger and the first solution heat exchanger and then connects the first absorber. Or The concentrated solution pipe of the second generator passes through the first solution pump, the third solution heat exchanger, the first solution heat exchanger, the first absorber and then connects the steam bleeding chamber.

After that the refrigerant vapor channel of the first generator connects external can be considered as that the refrigerant vapor channel of the first generator connects the second generator, the liquid refrigerant pipe of the second generator passes through the first throttle and then connects condenser. Using the refrigerant vapor produced by the first generator as the thermal driving medium of the second generator, the refrigerant vapor channel of the second generator connects condenser.

That the refrigerant vapor channel of the steam bleeding chamber connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber connects condenser. That the refrigerant vapor channel of the first absorber connects external can be considered as that the refrigerant vapor channel of the second evaporator connects the first absorber. That the refrigerant vapor channel of the second absorber connects external can be considered as that the refrigerant vapor channel of the first evaporator connects the second absorber. The liquid refrigerant pipe of condenser passes through the liquid refrigerant pump and then connects the first evaporator. The liquid refrigerant pipe of the first evaporator passes through the second throttle and then connects the second evaporator. Condenser has the pipe of cooling medium which connects external. The first evaporator and the second evaporator have the pipe of residual heat medium which separately connects external. When the system hasn't the second evaporator and the second throttle, the refrigerant vapor channel of the first evaporator separately connects the first absorber and the second absorber.

13. The eleventh one of the recuperative generation-absorption systems in this invention, which is described in 1 of claims, is the recuperative single stage parallel double-effect second-type absorption heat pump which can be formed by adding the second generator, condenser, the first evaporator, the first throttle, the liquid refrigerant pump, the second evaporator, the second throttle and the third solution heat exchanger.

Taking the second generator as high-pressure generator, after that the concentrated solution pipe of the second generator passes through the third solution heat exchanger, it joins with the solution pipe which passes through the first solution pump, the first solution heat exchanger from the first generator. The dilute solution pipe of the first absorber passes through the third solution heat exchanger and then connects the second generator.

After that the refrigerant vapor channel of the first generator connects external can be considered as that the refrigerant vapor channel of the second generator connects the first generator, the liquid refrigerant pipe of the first generator passes through the first throttle and then connects condenser. Using the refrigerant vapor produced by the second generator as the thermal driving medium of the first generator, that the refrigerant vapor channel of the first generator connects external can be considered as that the refrigerant vapor channel of the first generator connects condenser.

That the refrigerant vapor channel of the steam bleeding chamber connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber connects condenser. That the refrigerant vapor channel of the first absorber connects external can be considered as that the refrigerant vapor channel of the second evaporator connects the first absorber. That the refrigerant vapor channel of the second absorber connects external can be considered as that the refrigerant vapor channel of the first evaporator connects the second absorber. The liquid refrigerant pipe of condenser passes through the liquid refrigerant pump and then connects the first evaporator. The liquid refrigerant pipe of the first evaporator passes through the second throttle and then connects the second evaporator. Condenser has the pipe of cooling medium which connects external. The second generator, the first evaporator and the second evaporator have the pipe of residual heat medium which separately connects external. When the system hasn't the second evaporator and the second throttle, the refrigerant vapor channel of the first evaporator separately connects the first absorber and the second absorber.

14. The twelfth one of the recuperative generation-absorption systems in this invention, which is described in 2 of claims, is the recuperative single stage parallel double-effect second-type absorption heat pump which can be formed by adding the third solution pump, the second generator, condenser, the first evaporator, the first throttle, the liquid refrigerant pump, the second evaporator, the second throttle and the third solution heat exchanger.

Taking the second generator as low-pressure generator, the concentrated solution pipe of the second generator passes through the third solution pump, the third solution heat exchanger and then connects the first absorber. The dilute solution pipe of the first absorber passes through the third solution heat exchanger and then connects the second generator.

After that the refrigerant vapor channel of the first generator connects external can be considered as that the refrigerant vapor channel of the first generator connects the second generator, the liquid refrigerant pipe of the second generator passes through the first throttle and then connects condenser. Using the refrigerant vapor produced by the first generator as the thermal driving medium of the second generator, the refrigerant vapor channel of the second generator connects condenser.

That the refrigerant vapor channel of the steam bleeding chamber connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber connects condenser. That the refrigerant vapor channel of the first absorber connects external can be considered as that the refrigerant vapor channel of the second evaporator connects the first absorber. That the refrigerant vapor channel of the second absorber connects external can be considered as that the refrigerant vapor channel of the first evaporator connects the second absorber. The liquid refrigerant pipe of condenser passes through the liquid refrigerant pump and then connects the first evaporator. The liquid refrigerant pipe of the first evaporator passes through the second throttle and then connects the second evaporator. Condenser has the pipe of cooling medium which connects external. The first evaporator and the second evaporator have the pipe of residual heat medium which separately connects external. When the system hasn't the second evaporator and the second throttle, the refrigerant vapor channel of the first evaporator separately connects the first absorber and the second absorber.

15. The thirteenth one of the recuperative generation-absorption systems in this invention, which is described in 1 of claims, is the recuperative single stage parallel double-effect second-type absorption heat pump which can be formed by adding the second generator, condenser, the first evaporator, the first throttle, the liquid refrigerant pump, the second evaporator, the second throttle, the third solution heat exchanger and the fourth solution pump.

Taking the second generator as low-pressure generator, the concentrated solution pipe of the second generator passes through the fourth solution pump, the third solution heat exchanger and then connects the first absorber. The dilute solution pipe of the first absorber passes through the third solution heat exchanger and then connects the second generator.

After that the refrigerant vapor channel of the first generator connects external can be considered as that the refrigerant vapor channel of the first generator connects the second generator, the liquid refrigerant pipe of the second generator passes through the first throttle and then connects condenser. Using the refrigerant vapor produced by the first generator as the thermal driving medium of the second generator, the refrigerant vapor channel of the second generator connects condenser.

That the refrigerant vapor channel of the steam bleeding chamber connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber connects condenser. That the refrigerant vapor channel of the first absorber connects external can be considered as that the refrigerant vapor channel of the second evaporator connects the first absorber. That the refrigerant vapor channel of the second absorber connects external can be considered as that the refrigerant vapor channel of the first evaporator connects the second absorber. The liquid refrigerant pipe of condenser passes through the liquid refrigerant pump and then connects the first evaporator. The liquid refrigerant pipe of the first evaporator passes through the second throttle and then connects the second evaporator. Condenser has the pipe of cooling medium which connects external. The first evaporator and the second evaporator have the pipe of residual heat medium which separately connects external. When the system hasn't the second evaporator and the second throttle, the refrigerant vapor channel of the first evaporator separately connects the first absorber and the second absorber.

16. The fourteenth one of the recuperative generation-absorption systems in this invention, which is described in 1 of claims, is the recuperative single stage parallel double-effect second-type absorption heat pump which can be formed by adding the second generator, condenser, the first evaporator, the first throttle, the liquid refrigerant pump, the second evaporator, the second throttle, the third solution heat exchanger and the fourth solution pump.

Taking the second generator as high-pressure generator, the concentrated solution pipe of the second generator passes through the fourth solution pump, the third solution heat exchanger and then connects the first absorber. The dilute solution pipe of the first absorber passes through the third solution heat exchanger and then connects the second generator.

After that the thermal driving medium channel of the first generator connects external can be considered as that the refrigerant vapor channel of the second generator connects the first generator, the liquid refrigerant pipe of the first generator passes through the first throttle and then connects condenser. Using the refrigerant vapor produced by the second generator as the thermal driving medium of the first generator, that the refrigerant vapor channel of the first generator connects external can be considered as that the refrigerant vapor channel of the first generator connects condenser.

That the refrigerant vapor channel of the steam bleeding chamber connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber connects condenser. That the refrigerant vapor channel of the first absorber connects external can be considered as that the refrigerant vapor channel of the second evaporator connects the first absorber. That the refrigerant vapor channel of the second absorber connects external can be considered as that the refrigerant vapor channel of the first evaporator connects the second absorber. The liquid refrigerant pipe of condenser passes through the liquid refrigerant pump and then connects the first evaporator. The liquid refrigerant pipe of the first evaporator passes through the second throttle and then connects the second evaporator. Condenser has the pipe of cooling medium which connects external. The second generator, the first evaporator and the second evaporator have the pipe of residual heat medium which separately connects external. When the system hasn't the second evaporator and the second throttle, the refrigerant vapor channel of the first evaporator separately connects the first absorber and the second absorber.

17. The fifteenth one of the recuperative generation-absorption systems in this invention, which is described in 1 of claims, is the recuperative single stage tandem triple effect second-type absorption heat pump which can be formed by adding the second generator, the third generator, condenser, the first evaporator, the fourth solution pump, the first throttle, the second throttle, the liquid refrigerant pump, the second evaporator, the third throttle.

We adjust that the concentrated solution pipe of the first generator passes through the first solution pump, the first solution heat exchanger, the first absorber and then connects the steam bleeding chamber to that the concentrated solution pipe of the first generator passes through the first solution pump and then connects the third generator. The concentrated solution pipe of the third generator passes through the fourth solution pump and then connects the second generator. The concentrated solution pipe of the second generator passes through the first solution heat exchanger, the first absorber and then connects the steam bleeding chamber.

After that the thermal driving medium channel of the first generator connects external can be considered as that the refrigerant vapor channel of the third generator connects the first generator, the liquid refrigerant pipe of the first generator passes through the second throttle and then connects condenser. Using the refrigerant vapor produced by the third generator as the thermal driving medium of the first generator, the liquid refrigerant pipe of the third generator passes through the first throttle and then connects condenser after that the refrigerant vapor channel of the second generator connects the third generator.

Using the refrigerant vapor produced by the second generator as the thermal driving medium of the third generator, that the refrigerant vapor channel of the first generator connects external can be considered as that the refrigerant vapor channel of the first generator connects condenser. That the refrigerant vapor channel of the first absorber connects external can be considered as that the refrigerant vapor channel of the second evaporator connects absorber. That the refrigerant vapor channel of the second absorber connects external can be considered as that the refrigerant vapor channel of the first evaporator connects the second absorber.

The liquid refrigerant pipe of condenser passes through the liquid refrigerant pump and then connects the first evaporator. The liquid refrigerant pipe of the first evaporator passes through the third throttle and then connects the second evaporator. Condenser has the pipe of cooling medium which connects external. The second generator, the first evaporator and the second evaporator has the pipe of residual heat medium which separately connects external. When the system hasn't the second evaporator and the third throttle, the refrigerant vapor channel of the first evaporator separately connects the first absorber and the second absorber.

18. The sixteenth one of the recuperative generation-absorption systems in this invention, which is described in 2 of claims, is the recuperative single stage tandem triple effect second-type absorption heat pump which can be formed by adding the third solution pump, the second generator, the third generator, condenser, the first evaporator, the fourth solution pump, the first throttle, the second throttle, the liquid refrigerant pump, the second evaporator, the third throttle.

We adjust that the concentrated solution pipe of the first generator passes through the first solution pump, the first solution heat exchanger and then connects the first absorber to that the concentrated solution pipe of the first generator passes through the first solution pump and then connects the third generator. The concentrated solution pipe of the third generator passes through the fourth solution pump and then connects the second generator. The concentrated solution pipe of the second generator passes through the third solution pump, the first solution heat exchanger and then connects the first absorber.

After that the thermal driving medium channel of the first generator connects external can be considered as that the refrigerant vapor channel of the third generator connects the first generator, the liquid refrigerant pipe of the first generator passes through the second throttle and then connects condenser. Using the refrigerant vapor produced by the third generator as the thermal driving medium of the first generator, the liquid refrigerant pipe of the third generator passes through the first throttle and then connects condenser after that the refrigerant vapor channel of the second generator connects the third generator.

Using the refrigerant vapor produced by the second generator as the thermal driving medium of the third generator, that the refrigerant vapor channel of the first generator connects external can be considered as that the refrigerant vapor channel of the first generator connects condenser. That the refrigerant vapor channel of the first absorber connects external can be considered as that the refrigerant vapor channel of the second evaporator connects absorber. That the refrigerant vapor channel of the second absorber connects external can be considered as that the refrigerant vapor channel of the first evaporator connects the second absorber. That the refrigerant vapor channel of the steam bleeding chamber connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber connects condenser.

The liquid refrigerant pipe of condenser passes through the liquid refrigerant pump and then connects the first evaporator. The liquid refrigerant pipe of the first evaporator passes through the third throttle and then connects the second evaporator. Condenser has the pipe of cooling medium which connects external. The second generator, the first evaporator and the second evaporator have the pipe of residual heat medium which separately connects external. When the system hasn't the second evaporator and the third throttle, the refrigerant vapor channel of the first evaporator separately connects the first absorber and the second absorber.

19. The seventeenth one of the recuperative generation-absorption systems in this invention, which is described in 1 or 2 of claims, is the recuperative single stage tandem triple effect second-type absorption heat pump which can be formed by adding the second generator, the third generator, condenser, the first evaporator, the first throttle, the second throttle, the liquid refrigerant pump, the second evaporator, the third throttle, the third solution heat exchanger, the fourth solution heat exchanger.

We adjust that the concentrated solution pipe of the first generator passes through the first solution pump, the first solution heat exchanger and then connects the first absorber or the concentrated solution pipe of the first generator passes through the first solution pump, the first solution heat exchanger, the first absorber and then connects the steam bleeding chamber to that the concentrated solution pipe of the first generator passes through the third solution heat exchanger and then connects the second generator. The concentrated solution pipe of the second generator passes through the fourth solution heat exchanger and then connects the third generator. The concentrated solution pipe of the third generator passes through the first solution pump, the fourth solution heat exchanger, the third solution heat exchanger, the first solution heat exchanger and then connects the first absorber or The concentrated solution pipe of the third generator passes through the first solution pump, the fourth solution heat exchanger, the third solution heat exchanger, the first solution heat exchanger, the first absorber and then connects the steam bleeding chamber.

After that the refrigerant vapor channel of the first generator connects external can be considered as that the refrigerant vapor channel of the first generator connects the second generator, the liquid refrigerant pipe of the second generator passes through the first throttle and then connects condenser.

Using the refrigerant vapor produced by the first generator as the thermal driving medium of the second generator that the liquid refrigerant channel of the third generator passes through the second throttle and then connects condenser after that the refrigerant vapor channel of the first second generator connects condenser. Using the refrigerant vapor produced by the second generator as the thermal driving medium of the third generator, the refrigerant vapor channel of the third generator connects condenser.

That the refrigerant vapor channel of the first absorber connects external can be considered as that the refrigerant vapor channel of the second evaporator connects absorber. That the refrigerant vapor channel of the second absorber connects external can be considered as that the refrigerant vapor channel of the first evaporator connects the second absorber. That the refrigerant vapor channel of the steam bleeding chamber connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber connects condenser.

The liquid refrigerant pipe of condenser passes through the liquid refrigerant pump and then connects the first evaporator. The liquid refrigerant pipe of the first evaporator passes through the third throttle and then connects the second evaporator. Condenser has the pipe of cooling medium which connects external. The first evaporator and the second evaporator have the pipe of residual heat medium which separately connects external. When the system hasn't the second evaporator and the third throttle, the refrigerant vapor channel of the first evaporator separately connects the first absorber and the second absorber.

20. The eighteenth one of the recuperative generation-absorption systems in this invention, which is described in 2 of claims, is the recuperative single stage parallel triple effect second-type absorption heat pump which can be formed by adding the second generator, the third generator, condenser), the first evaporator, the third solution pump, the fourth solution pump, the first throttle, the second throttle, the liquid refrigerant pump, the second evaporator, the third throttle, the third solution heat exchanger, the fourth solution heat exchanger.

Taking the second generator as medium voltage generator and using the third generator as low-pressure generator, the concentrated solution pipe of the second generator passes through the third solution pump, the third solution heat exchanger and then connects the first absorber. The dilute solution pipe of the first absorber passes through the third solution heat exchanger and then connects the second generator. The concentrated solution pipe of the third generator passes through the fourth solution pump, the fourth solution heat exchanger and then connects the first absorber. The dilute solution pipe of the first absorber passes through the fourth solution heat exchanger and then connects the third generator. That the refrigerant vapor channel of the first generator connects external can be considered as that the liquid refrigerant pipe of the second generator passes through the first throttle and then connects condenser after that the refrigerant vapor channel of the first generator connects the second generator.

Using the refrigerant vapor produced by the first generator as the thermal driving medium of the second generator, the liquid refrigerant pipe of the third generator passes through the second throttle and then connects condenser after that the refrigerant vapor channel of the second generator connects the third generator. Using the refrigerant vapor produced by the second generator as the thermal driving medium of the third generator, the refrigerant vapor channel of the third generator connects condenser.

That the refrigerant vapor channel of the first absorber connects external can be considered as that the refrigerant vapor channel of the second evaporator connects absorber. That the refrigerant vapor channel of the second absorber connects external can be considered as that the refrigerant vapor channel of the first evaporator connects the second absorber. That the refrigerant vapor channel of the steam bleeding chamber connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber connects condenser.

The liquid refrigerant pipe of condenser passes through the liquid refrigerant pump and then connects the first evaporator. The liquid refrigerant pipe of the first evaporator passes through the third throttle and then connects the second evaporator. Condenser has the pipe of cooling medium which connects external. The first evaporator and the second evaporator have the pipe of residual heat medium which separately connects external. When the system hasn't the second evaporator and the third throttle, the refrigerant vapor channel of the first evaporator separately connects the first absorber and the second absorber.

21. The nineteenth one of the recuperative generation-absorption systems in this invention, which is described in 1 of claims, is the recuperative single stage parallel triple effect second-type absorption heat pump which can be formed by adding the second generator, the third generator, condenser, the first evaporator, the first throttle, the second throttle, the liquid refrigerant pump, the second evaporator, the third throttle, the third solution heat exchanger, the fourth solution heat exchanger.

Taking the second generator as high-pressure generator and using the third generator as medium voltage generator, the concentrated solution pipe of the second generator which passes through the third solution heat exchanger and the concentrated solution pipe of the third generator which passes through the fourth solution heat exchanger all join with the solution pipe which passes through the first solution pump, the first solution heat exchanger from the first generator. The dilute solution pipe of the first absorber passes through the third solution heat exchanger and then connects the second generator. The dilute solution pipe of the first absorber passes through the fourth solution heat exchanger and then connects the third generator.

That the refrigerant vapor channel of the first generator connects external can be considered as that the liquid refrigerant pipe of the first generator passes through the second throttle and then connects condenser after that the refrigerant vapor channel of connects the first generator.

Using the refrigerant vapor produced by the third generator as the thermal driving medium of the first generator, the liquid refrigerant pipe of the third generator passes through the first throttle and then connects condenser after that the refrigerant vapor channel of the second generator connects the third generator. Using the refrigerant vapor produced by the second generator as the thermal driving medium of the third generator, that the refrigerant vapor channel of the first generator connects external can be considered as that the refrigerant vapor channel of the first generator connects condenser.

That the refrigerant vapor channel of the first absorber connects external can be considered as that the refrigerant vapor channel of the second evaporator connects absorber. That the refrigerant vapor channel of the second absorber connects external can be considered as that the refrigerant vapor channel of the first evaporator connects the second absorber. That the refrigerant vapor channel of the steam bleeding chamber connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber connects condenser.

The liquid refrigerant pipe of condenser passes through the liquid refrigerant pump and then connects the first evaporator. The liquid refrigerant pipe of the first evaporator passes through the third throttle and then connects the second evaporator. Condenser has the pipe of cooling medium which connects external. The second generator, the first evaporator and the second evaporator have the pipe of residual heat medium which separately connects external. When the system hasn't the second evaporator and the third throttle, the refrigerant vapor channel of the first evaporator separately connects the first absorber and the second absorber.

22. The twentieth one of the recuperative generation-absorption systems in this invention, which is described in 3 and 10 to 21 of claims, is the recuperative second-type absorption heat pump with high-temperature heating-side which can be formed by adding the new added absorption-evaporator, the new added absorber, the new added liquid refrigerant pump, the new added first solution heat exchanger and the new added second solution heat exchanger.

The concentrated solution pipe added by the second solution pump passes through the new added second solution heat exchanger, the new added first solution heat exchanger and then connects the new added absorber. The dilute solution pipe of the new added absorber passes through the new added first solution heat exchanger and then connects the new added absorption-evaporator. The dilute solution pipe of the new added absorption-evaporator passes through the new added second solution heat exchanger and then joins with the solution pipe which hasn't passed through the first absorber.

After that the liquid refrigerant pipe added by the first evaporator passes through the new added liquid refrigerant pump and then connect the new added absorption-evaporator, the refrigerant vapor channel of the new added absorption-evaporator connects the new added absorber. The refrigerant vapor channel added by the first evaporator connects the new added absorption-evaporator. The new added absorber has the pipe of heated medium which connects external. The solution of the steam bleeding chamber which flows through the second solution pump, the new added second solution heat exchanger and the new added first solution heat exchanger is provided to the new added absorber. At the same time, the solution of the new added absorber absorbs the refrigerant vapor coming from the new added absorption-evaporator and releases heat to the heated medium.

The dilute solution of the new added absorber flows through the new added first solution heat exchanger and enters the new added absorption-evaporator. At the same time, the solution of the new added absorption-evaporator absorbs the refrigerant vapor coming from the first evaporator and releases heat to another way of the liquid refrigerant which flows through the new added absorption-evaporator too. The liquid refrigerant becomes refrigerant vapor which is provided to the new added absorber.

After that the dilute solution of the new added absorption-evaporator flows through the new added second solution heat exchanger, it joins with the dilute solution which haven't flowed into the first absorber. Then the dilute solution absorbs heat from the first absorber and then enters the steam bleeding chamber. The new added absorber turns into adjacent high-temperature heating-side of the second absorber.

23. The twenty-first one of the recuperative generation-absorption systems in this invention, which is described in 3 and 10 to 21 of claims, is the recuperative second-type absorption heat pump with high-temperature heating-side which can be formed by adding the new added absorption-evaporator, the new added absorber, the new added throttle, the new added first solution heat exchanger and the new added second solution heat exchanger.

The concentrated solution pipe added by the second solution pump passes through the new added second solution heat exchanger, the new added first solution heat exchanger and then connects the new added absorber. The dilute solution pipe of the new added absorber passes through the new added first solution heat exchanger and then connects the new added absorption-evaporator. The dilute solution pipe of the new added absorption-evaporator passes through the new added second solution heat exchanger and then joins with the solution pipe which hasn't passed through the first absorber.

After that the liquid refrigerant pipe added by condenser connects the new added absorption-evaporator, the refrigerant vapor channel of the new added absorption-evaporator connects the new added absorber.

At the same time, we adjust that condenser which passes through liquid refrigerant pump directly connects the first generator to that condenser which passes through liquid refrigerant pump and the new added throttle connects the first generator. The refrigerant vapor channel added by the first evaporator connects the new added absorption-evaporator. The new added absorber has the pipe of heated medium which connects external. The solution of the steam bleeding chamber which flows through the second solution pump, the new added second solution heat exchanger and the new added first solution heat exchanger is provided to the new added absorber. At the same time, the solution of the new added absorber absorbs the refrigerant vapor coming from the new added absorption-evaporator and releases heat to the heated medium.

The dilute solution of the new added absorber flows through the new added first solution heat exchanger and enters the new added absorption-evaporator. At the same time, the solution of the new added absorption-evaporator absorbs the refrigerant vapor coming from the first evaporator and releases heat to another way of the liquid refrigerant which flows through the new added absorption-evaporator too. The liquid refrigerant becomes refrigerant vapor which is provided to the new added absorber.

After that the dilute solution of the new added absorption-evaporator flows through the new added second solution heat exchanger, it joins with the dilute solution which haven't flowed into the first absorber. Then the dilute solution absorbs heat from the first absorber and then enters the steam bleeding chamber. The new added absorber turns into adjacent high-temperature heating-side of the second absorber.

24. The twenty-second one of the recuperative generation-absorption systems in this invention, which is described in 4 to 5 of claims, is the recuperative second-type absorption heat pump with high-temperature heating-side which can be formed by adding the new added absorption-evaporator, the new added absorber, the new added liquid refrigerant pump, the new added first solution heat exchanger and the new added second solution heat exchanger.

The concentrated solution pipe added by the second solution pump passes through the new added second solution heat exchanger, the new added first solution heat exchanger and then connects the new added absorber. The dilute solution pipe of the new added absorber passes through the new added first solution heat exchanger and then connects the new added absorption-evaporator. The dilute solution pipe of the new added absorption-evaporator passes through the new added second solution heat exchanger and then joins with the solution pipe which hasn't passed through the first absorber.

After that the liquid refrigerant pipe of the first liquid refrigerant pump which passes through the new added liquid refrigerant pump connects the new added absorption-evaporator, the refrigerant vapor channel of the new added absorption-evaporator connects the new added absorber. The refrigerant vapor channel added by absorption-evaporator connects the new added absorption-evaporator. The new added absorber has the pipe of heated medium which connects external. The solution of the steam bleeding chamber which flows through the second solution pump, the new added second solution heat exchanger and the new added first solution heat exchanger is provided to the new added absorber. At the same time, the solution of the new added absorber absorbs the refrigerant vapor coming from the new added absorption-evaporator and releases heat to the heated medium.

The dilute solution of the new added absorber flows through the new added first solution heat exchanger and enters the new added absorption-evaporator. At the same time, the solution of the new added absorption-evaporator absorbs the refrigerant vapor coming from the absorption-evaporator and releases heat to another way of the liquid refrigerant which flows through the new added absorption-evaporator too. The liquid refrigerant becomes refrigerant vapor which is provided to the new added absorber.

After that the dilute solution of the new added absorption-evaporator flows through the new added second solution heat exchanger, it joins with the dilute solution which haven't flowed into the first absorber. Then the dilute solution absorbs heat from the first absorber and then enters the steam bleeding chamber. The new added absorber turns into adjacent high-temperature heating-side of the second absorber.

25. The twenty-third one of the recuperative generation-absorption systems in this invention, which is described in 6 to 7 of claims, is the recuperative second-type absorption heat pump with high-temperature heating-side which can be formed by adding the new added absorption-evaporator, the new added absorber, the new added liquid refrigerant pump, the new added first solution heat exchanger and the new added second solution heat exchanger.

The concentrated solution pipe added by the second solution pump passes through the new added second solution heat exchanger, the new added first solution heat exchanger and then connects the new added absorber. The dilute solution pipe of the new added absorber passes through the new added first solution heat exchanger and then connects the new added absorption-evaporator. The dilute solution pipe of the new added absorption-evaporator passes through the new added second solution heat exchanger and then joins with the solution pipe which hasn't passed through the first absorber.

After that the liquid refrigerant pipe of the first liquid refrigerant pump which passes through the new added liquid refrigerant pump connects the new added absorption-evaporator, the refrigerant vapor channel of the new added absorption-evaporator connects the new added absorber. The refrigerant vapor channel added by two-stage absorption-evaporator connects the new added absorption-evaporator. The new added absorber has the pipe of heated medium which connects external. The solution of the steam bleeding chamber which flows through the second solution pump, the new added second solution heat exchanger and the new added first solution heat exchanger is provided to the new added absorber. At the same time, the solution of the new added absorber absorbs the refrigerant vapor coming from the new added absorption-evaporator and releases heat to the heated medium.

The dilute solution of the new added absorber flows through the new added first solution heat exchanger and enters the new added absorption-evaporator. At the same time, the solution of the new added absorption-evaporator absorbs the refrigerant vapor coming from the first two-stage absorption-evaporator and releases heat to another way of the liquid refrigerant which flows through the new added absorption-evaporator too. The liquid refrigerant becomes refrigerant vapor which is provided to the new added absorber.

After that the dilute solution of the new added absorption-evaporator flows through the new added second solution heat exchanger, it joins with the dilute solution which haven't flowed into the first absorber. Then the dilute solution absorbs heat from the first absorber and then enters the steam bleeding chamber. The new added absorber turns into adjacent high-temperature heating-side of the second absorber.

26. The twenty-fourth one of the recuperative generation-absorption systems in this invention, which is described in 8 to 9 of claims, is the recuperative second-type absorption heat pump with high-temperature heating-side which can be formed by adding the new added absorption-evaporator, the new added absorber, the new added liquid refrigerant pump, the new added first solution heat exchanger and the new added second solution heat exchanger.

The concentrated solution pipe added by the second solution pump passes through the new added second solution heat exchanger, the new added first solution heat exchanger and then connects the new added absorber. The dilute solution pipe of the new added absorber passes through the new added first solution heat exchanger and then connects the new added absorption-evaporator. The dilute solution pipe of the new added absorption-evaporator passes through the new added second solution heat exchanger and then joins with the solution pipe which hasn't passed through the first absorber.

After that the liquid refrigerant pipe of the first liquid refrigerant pump which passes through the new added liquid refrigerant pump connects the new added absorption-evaporator, the refrigerant vapor channel of the new added absorption-evaporator connects the new added absorber. The refrigerant vapor channel added by absorption-evaporator connects the new added absorption-evaporator. The new added absorber has the pipe of heated medium which connects external. The solution of the steam bleeding chamber which flows through the second solution pump, the new added second solution heat exchanger and the new added first solution heat exchanger is provided to the new added absorber. At the same time, the solution of the new added absorber absorbs the refrigerant vapor coming from the new added absorption-evaporator and releases heat to the heated medium.

The dilute solution of the new added absorber flows through the new added first solution heat exchanger and enters the new added absorption-evaporator. At the same time, the solution of the new added absorption-evaporator absorbs the refrigerant vapor coming from absorption-evaporator and releases heat to another way of the liquid refrigerant which flows through the new added absorption-evaporator too. The liquid refrigerant becomes refrigerant vapor which is provided to the new added absorber.

After that the dilute solution of the new added absorption-evaporator flows through the new added second solution heat exchanger, it joins with the dilute solution which haven't flowed into the first absorber. Then the dilute solution absorbs heat from the first absorber and then enters the steam bleeding chamber. The new added absorber turns into adjacent high-temperature heating-side of the second absorber.

BRIEF DESCRIPTION OF THE DRAWINGS

In this invention, FIG. 1 provides the structure and flow diagram of the solution tandem cycle recuperative generation-absorption system.

In this invention, FIG. 2 provides the structure and flow diagram of the solution tandem cycle recuperative generation-absorption system too.

But the difference between FIG. 1 and FIG. 2 is that there is no heated medium in the first absorber which connects external in FIG. 2. What's more, the heat released by the first absorber just heats up the solution which hasn't been vaporized.

In this invention, FIG. 3 provides the structure and flow diagram of the solution independent cycle recuperative generation-absorption system.

In this invention, FIG. 4 provides the structure and flow diagram of the solution independent cycle recuperative generation-absorption system.

But the difference between FIG. 3 and FIG. 4 is that there is no heated medium in the first absorber which connects external in FIG. 4. What's more, the heat released by the first absorber just heats up the solution which hasn't been vaporized.

In this invention, FIG. 5 provides the structure and flow diagram of the recuperative single-stage single-effect second-type absorption heat pump by adopting the solution tandem cycle recuperative generation-absorption system which is shown in FIG. 1.

In this invention, FIG. 6 provides the structure and flow diagram of the recuperative single-stage single-effect second-type absorption heat pump by adopting the solution tandem cycle recuperative generation-absorption system which is shown in FIG. 2.

In this invention, FIG. 7 provides the structure and flow diagram of the recuperative single-stage single-effect second-type absorption heat pump by adopting the solution independent cycle recuperative generation-absorption system which is shown in FIG. 3.

In this invention, FIG. 8 provides the structure and flow diagram of the recuperative single-stage single-effect second-type absorption heat pump by adopting the solution independent cycle recuperative generation-absorption system which is shown in FIG. 4.

In this invention, FIG. 9 provides the structure and flow diagram of the recuperative single generator two-stage second-type absorption heat pump by adopting the solution tandem cycle recuperative generation-absorption system which is shown in FIG. 1.

In this invention, FIG. 10 provides the structure and flow diagram of the recuperative single generator two-stage second-type absorption heat pump by adopting the solution tandem cycle recuperative generation-absorption system which is shown in FIG. 2.

In this invention, FIG. 11 provides the structure and flow diagram of recuperative single generator two-stage second-type absorption heat pump by adopting the solution independent cycle recuperative generation-absorption system which is shown in FIG. 3.

In this invention, FIG. 12 provides the structure and flow diagram of the recuperative single generator two-stage second-type absorption heat pump by adopting the solution independent cycle recuperative generation-absorption system which is shown in FIG. 4.

In this invention, FIG. 13 provides the structure and flow diagram of the recuperative single generator three-stage second-type absorption heat pump by adopting the solution tandem cycle recuperative generation-absorption system which is shown in FIG. 1.

In this invention, FIG. 14 provides the structure and flow diagram of the recuperative single generator three-stage second-type absorption heat pump by adopting the solution independent cycle recuperative generation-absorption system which is shown in FIG. 3.

In this invention, FIG. 15 provides the structure and flow diagram of the recuperative two-generator two-stage second-type absorption heat pump by adopting the solution tandem cycle recuperative generation-absorption system which is shown in FIG. 1.

In this invention, FIG. 16 provides the structure and flow diagram of the recuperative two-generator two-stage second-type absorption heat pump by adopting the solution independent cycle recuperative generation-absorption system which is shown in FIG. 3.

In this invention, FIG. 17 provides the structure and flow diagram of the recuperative single stage tandem double-effect second-type absorption heat pump by adopting the solution tandem cycle recuperative generation-absorption system which is shown in FIG. 1.

In this invention, FIG. 18 provides the structure and flow diagram of the recuperative single stage tandem double-effect second-type absorption heat pump by adopting the solution tandem cycle recuperative generation-absorption system which is shown in FIG. 2.

In this invention, FIG. 19 provides the structure and flow diagram of the recuperative single stage tandem double-effect second-type absorption heat pump by adopting the solution independent cycle recuperative generation-absorption system which is shown in FIG. 3.

In this invention, FIG. 20 provides the structure and flow diagram of the recuperative single stage tandem double-effect second-type absorption heat pump by adopting the solution independent cycle recuperative generation-absorption system which is shown in FIG. 4.

In this invention, FIG. 21 provides the structure and flow diagram of the recuperative single stage tandem double-effect second-type absorption heat pump by adopting the solution tandem cycle recuperative generation-absorption system which is shown in FIG. 1.

In this invention, FIG. 22 provides the structure and flow diagram of the recuperative single stage tandem double-effect second-type absorption heat pump by adopting the solution tandem cycle recuperative generation-absorption system which is shown in FIG. 2.

In this invention, FIG. 23 provides the structure and flow diagram of the recuperative single stage tandem double-effect second-type absorption heat pump by adopting the solution independent cycle recuperative generation-absorption system which is shown in FIG. 3.

In this invention, FIG. 24 provides the structure and flow diagram of the recuperative single stage tandem double-effect second-type absorption heat pump by adopting the solution independent cycle recuperative generation-absorption system which is shown in FIG. 3 too.

But the difference between FIG. 23 and FIG. 24 is that the single evaporator separately supply refrigerant vapor to the first absorber and the second absorber in FIG. 24 while the second evaporator provides refrigerant vapor to the first absorber and the first evaporator supply refrigerant vapor to the second absorber in FIG. 23.

In the recuperative single stage tandem double-effect second-type absorption heat pump shown in FIG. 17 to FIG. 20, the first generator is used as low-pressure generator. In the recuperative single stage tandem double-effect second-type absorption heat pump shown in FIG. 21 to FIG. 24, the first generator is used as the high-pressure generator.

In this invention, FIG. 25 provides the structure and flow diagram of the recuperative single stage parallel double-effect second-type absorption heat pump by adopting the solution tandem cycle recuperative generation-absorption system which is shown in FIG. 1.

In this invention, FIG. 26 provides the structure and flow diagram of the recuperative single stage parallel double-effect second-type absorption heat pump by adopting the solution independent cycle recuperative generation-absorption system which is shown in FIG. 3.

In this invention, FIG. 27 provides the structure and flow diagram of the recuperative single stage parallel double-effect second-type absorption heat pump by adopting the solution tandem cycle recuperative generation-absorption system which is shown in FIG. 1.

In this invention, FIG. 28 provides the structure and flow diagram of the recuperative single stage parallel double-effect second-type absorption heat pump by adopting the solution tandem cycle recuperative generation-absorption system which is shown in FIG. 1 too.

But the difference between FIG. 27 and FIG. 28 is as follows. Firstly, the first generator is used as the high-pressure generator in FIG. 27 while it is used as the low-pressure generator in FIG. 28. Secondly, the single evaporator separately supplies the refrigerant vapor to the first absorber and the second absorber in FIG. 27 while the second evaporator provides the refrigerant vapor to the first absorber and the first evaporator supplies the refrigerant vapor to the second absorber in FIG. 28.

In addition, the different process of the solution among FIG. 27, FIG. 28 and FIG. 25 is as follows. The solution of the first generator and the second generator all flow through the first absorber and then enter the steam bleeding chamber in FIG. 25. The solution of the first generator flows through the first absorber and then enters the steam bleeding chamber in FIG. 27 and FIG. 28.

In this invention, FIG. 29 provides the structure and flow diagram of the recuperative single stage tandem triple effect second-type absorption heat pump by adopting the solution tandem cycle recuperative generation-absorption system which is shown in FIG. 1.

In this invention, FIG. 30 provides the structure and flow diagram of the recuperative single stage tandem triple effect second-type absorption heat pump by adopting the solution tandem cycle recuperative generation-absorption system which is shown in FIG. 1 too.

Compared with FIG. 29 and FIG. 30, the difference between the two is as follows. The single evaporator separately supplies the refrigerant vapor to the first absorber and the second absorber in FIG. 29. In FIG. 30, the second evaporator provides the refrigerant vapor to the first absorber and the first evaporator supplies the refrigerant vapor to the second absorber.

In this invention, FIG. 31 provides the structure and flow diagram of the recuperative single stage tandem triple effect second-type absorption heat pump by adopting the solution independent cycle recuperative generation-absorption system which is shown in FIG. 3.

In this invention, FIG. 32 provides the structure and flow diagram of the recuperative single stage tandem triple effect second-type absorption heat pump by adopting the solution independent cycle recuperative generation-absorption system which is shown in FIG. 3 too.

But the difference between FIG. 31 and FIG. 32 is as follows. Firstly, the first generator is used as the low-pressure generator in FIG. 31 while it is used as the high-pressure generator in FIG. 32. Secondly, the single evaporator separately supplies the refrigerant vapor to the first absorber and the second absorber in FIG. 32. In FIG. 31, the second evaporator provides the refrigerant vapor to the first absorber and the first evaporator supplies the refrigerant vapor to the second absorber.

In this invention, FIG. 33 provides the structure and flow diagram of the recuperative single stage tandem triple effect second-type absorption heat pump by adopting the solution independent cycle recuperative generation-absorption system which is shown in FIG. 3 too.

Compared with FIG. 32 and FIG. 33, the difference between the two is as follows. The single evaporator separately supplies the refrigerant vapor to the first absorber and the second absorber in FIG. 32. But in FIG. 33, the second evaporator provides the refrigerant vapor to the first absorber and the first evaporator supplies the refrigerant vapor to the second absorber.

In this invention, FIG. 34 provides the structure and flow diagram of the recuperative single stage tandem triple effect second-type absorption heat pump by adopting the solution tandem cycle recuperative generation-absorption system which is shown in FIG. 1.

In this invention, FIG. 35 provides the structure and flow diagram of the recuperative single stage parallel triple effect second-type absorption heat pump by adopting the solution independent cycle recuperative generation-absorption system which is shown in FIG. 3.

In this invention, FIG. 36 provides the structure and flow diagram of the recuperative single stage parallel triple effect second-type absorption heat pump by adopting the solution tandem cycle recuperative generation-absorption system which is shown in FIG. 1.

In this invention, FIG. 37 provides the structure and flow diagram of the recuperative single stage parallel triple effect second-type absorption heat pump by adopting the solution tandem cycle recuperative generation-absorption system which is shown in FIG. 1 too.

Compared with FIG. 36 and FIG. 37, the difference between the two is as follows. In FIG. 36, the single evaporator separately supplies the refrigerant vapor to the first absorber and the second absorber. But in FIG. 33, the second evaporator provides the refrigerant vapor to the first absorber and the first evaporator supplies the refrigerant vapor to the second absorber.

In this invention, FIG. 38 provides the structure and flow diagram of the recuperative single stage single-effect second-type absorption heat pump with high-temperature heating-side by adopting the solution independent cycle recuperative generation-absorption system which is shown in FIG. 3.

In this invention, FIG. 39 provides the structure and flow diagram of the recuperative single stage tandem double-effect second-type absorption heat pump with high-temperature heating-side by adopting the solution tandem cycle recuperative generation-absorption system which is shown in FIG. 1.

In the drawings, 1—generator or the first generator, 2—the first absorber, 3—the second absorber, 4—the first solution heat exchanger, 5—the second solution heat exchanger, 6—the steam bleeding chamber, 7—the first solution pump, 8—the second solution pump, 9—the third solution pump, a—the new added absorption-evaporator, b—the new added absorber, c—the new added first solution heat exchanger, d—the new added second solution heat exchanger, e—the new added liquid refrigerant pump, f—the new added throttle.

In FIG. 5 to FIG. 8 and FIG. 38, A1—condenser, B1—evaporator or the first evaporator, C1—liquid refrigerant pump, D1—the second evaporator, E1—throttle.

In FIG. 9 to FIG. 12, A2—condenser, B2—evaporator, C2—absorption-evaporator, D2—liquid refrigerant pump or the first liquid refrigerant pump, E2—throttle, F2—the third solution heat exchanger, G2—the second liquid refrigerant pump.

In FIG. 13 to FIG. 14, A3—condenser, B3—evaporator, C3—absorption-evaporator, D3—two-stage absorption-evaporator, E3—liquid refrigerant pump or the first liquid refrigerant pump, F3—the first throttle, G3—the second throttle, H3—the third solution heat exchanger, 13—the fourth solution heat exchanger, J3—the second liquid refrigerant pump, K3—the third liquid refrigerant pump.

In FIG. 15 to FIG. 16, A4—condenser, B4—evaporator, C4—absorption-evaporator, D4—liquid refrigerant pump or the first liquid refrigerant pump, E4—throttle or the first throttle, F4—low-temperature generator, G4—the fourth solution pump, H4—the second throttle, I4—the third solution heat exchanger, J4—the second liquid refrigerant pump.

In FIG. 17 to FIG. 28 and FIG. 39, A5—the second generator, B5—condenser, C5—evaporator or the first evaporator, D5—throttle or the first throttle, E5—liquid refrigerant pump, F5—the second evaporator, G5—the second throttle, H5—the third solution heat exchanger, I5—the fourth solution pump.

In FIG. 29 to FIG. 37, A6—the second generator, B6—the third generator, C6—condenser, D6—evaporator or the first evaporator, E6—the fourth solution pump, F6—the first throttle, G6—the second throttle, H6—liquid refrigerant pump, I6—the second evaporator. J6—the third throttle, K6—the third solution heat exchanger, L6—the fourth solution heat exchanger.

What we need to clarify is as follows:

Firstly, in theory, the steam pressure in the second absorber 3 and the first absorber 2 is consistent. Meanwhile, the third solution pump 9 is used to overcome the resistance when the solution flows through the heat exchanger and the pipeline. But the solution pump will save when the altitude (gravity) difference exists and can be used. The third solution pump 9 can save too when the pressure of the second absorber 3 is higher than the pressure of the first absorber 2.

Secondly, the solution heat exchanger can act as the throttle which is used for throttling step-down.

Thirdly, the solution independent cycle in the solution independent cycle generation-absorption system refers to that the solution is divided into two ways with independent cycle in the process of generation-absorption system.

Fourthly, the solution tandem cycle in the solution tandem cycle generation-absorption system refers to that the solution flows orderly through all components of generation-absorption system in the process of generation-absorption system. And the parallel double-effect in the single stage parallel double-effect absorption heat pump refer to that the solution cycle is parallel when the absorption heat pump realize double-effect process. So do single stage parallel triple effect.

Fifthly, the tandem cycle double-effect in the single stage tandem cycle double-effect absorption heat pump refers to that the solution cycle is tandem when the absorption heat pump realizes the double-effect process. So do single stage tandem triple effect.

Sixthly, in the recuperative single stage double-effect absorption heat pump, the first generator 1 and the second generator A2 all can be used as the high-pressure generator or low-pressure generator. They can be called as the high-pressure generator or low-pressure generator when it is necessary. Similarly, in the recuperative single stage triple effect absorption heat pump, the first generator 1, the second generator A3 and the third generator B3 all can be used as the low-pressure generator, medium voltage generator or low-pressure generator. They can be called as the high-pressure generator, medium voltage generator or low-pressure generator when it is necessary too.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

Now combining the appended drawings and examples, we described the present invention in detail.

The solution tandem cycle recuperative generation-absorption system shown in FIG. 1 can be realized by the following way:

Firstly, structurally, it is mainly formed by the generator, the first absorber, the second absorber, the first solution heat exchanger, the second solution heat pump, the steam bleeding chamber, the first solution pump, the second solution pump and the third solution pump.

The generator 1 has the concentrated solution pipe which passes through the first solution pump 7, the first solution heat exchanger 4, the first absorber 2, and then connects the steam bleeding chamber 6. The steam bleeding chamber 6 has the concentrated solution pipe that passes through the second solution pump 8, the second solution heat exchanger 5 and then connects the second absorber 3. The second absorber 3 has the dilute solution pipe which passes through the second solution heat exchanger 5, the third solution pump 9 and then connects the first absorber 2. The first absorber 2 has the dilute solution pipe which passes through the first solution heat exchanger 4 and then connects the generator 1. The generator 1 has the residual heat medium pipe or thermal driving medium pipe which separately connects external. And the generator 1 also has the refrigerant vapor pipe which connects external. The first absorber 2 has the heated medium pipe and the refrigerant vapor pipe which separately connects external. The second absorber 3 has the refrigerant vapor channel and the heated medium pipe which separately connects external. The steam bleeding chamber has the refrigerant vapor pipe connected external.

Secondly, on the process, the residual heat medium or thermal driving medium heats up the dilute solution of the generator 1 and releases the refrigerant vapor. After that the concentrated solution of the generator 1 flows through the first solution pump 7, the first solution heat exchanger 4, the first absorber 2 and absorbs heat making parts of it vaporization, the concentrated solution enters the steam bleeding chamber and releases the refrigerant vapor. The concentrated solution of the steam bleeding chamber 6 flows through the second solution pump 8, the second solution heat exchanger 5 and then enters the second absorber 3 where it absorbs the refrigerant vapor coming from outside the system and releases heat to heated medium. The dilute solution of the second absorber 3 flows through the second solution heat exchanger 5, the third solution pump 9 and then enters the first absorber 2 where it absorbs the refrigerant vapor coming from outside the system and heats up the solution which flows through the first absorber 2 for meeting the heat demand of heated medium. The dilute solution pipe of the first absorber 2 flows through the first solution heat exchanger 4 and then reflows to generator 1 in which it is heated to release refrigerant vapor. Then we gain the solution tandem cycle recuperative generation-absorption system.

The solution tandem cycle recuperative generation-absorption system shown in FIG. 2 is similar to FIG. 1 in the structure and working principle. But there are two different aspects existing between the two. Firstly, the first absorber 2 has no heating medium pipe connected external. The solution of the first absorber 2 absorbs the refrigerant vapor and releases heat. And the heat is just used to heat the solution before vaporization. Secondly, there is no second solution pump 8 in FIG. 2.

The solution parallel cycle recuperative generation-absorption system shown in FIG. 3 can be realized by the following way:

Firstly, structurally, it is mainly formed by the generator, the first absorber, the second absorber, the first solution heat exchanger, the second solution heat pump, the steam bleeding chamber, the first solution pump and the second solution pump.

The generator 1 has the concentrated solution pipe which passes through the first solution pump 7, the first solution heat exchanger 4 and then connects the first absorber 2. The first absorber 2 has the dilute solution pipe which passes through the first solution heat exchanger 4 and then connects generator 1. The second absorber 3 has the dilute solution pipe which passes through the second solution heat exchanger 5, the first absorber 2 and then connects the steam bleeding chamber 6. The steam bleeding chamber 6 has the concentrated solution pipe that passes through the second solution pump 8, the second solution heat exchanger 5 and then connects the second absorber 3. The generator 1 has the residual heat medium pipe or thermal driving medium pipe which separately connects external. And the generator 1 also has the refrigerant vapor pipe which connects external. The first absorber 2 has the heated medium pipe and refrigerant vapor pipe which separately connects external. The second absorber 3 has refrigerant vapor channel and the heated medium pipe which separately connects external. The steam bleeding chamber has refrigerant vapor pipe connected external.

Secondly, on the process, the residual heat medium or thermal driving medium heats up the dilute solution of the generator 1 and releases the refrigerant vapor. The concentrated solution of the generator 1 flows through the first solution pump 7, the first solution heat exchanger 4, the first absorber 2 where it absorbs the refrigerant vapor coming from outside the system and heats up the solution which flows through the first absorber 2 for meeting the heat demand of heated medium. The dilute solution pipe of the first absorber 2 flows through the first solution heat exchanger 4 and then reflows to the generator 1. After that the solution which flows through the first absorber 2 absorbs heat making parts of it vaporization, the solution enters the steam bleeding chamber and releases refrigerant vapor. The concentrated solution of the steam bleeding chamber 6 flows through the second solution pump 8, the second solution heat exchanger 5 and then enters the second absorber 3 where it absorbs the refrigerant vapor coming from outside the system and releases heat to heated medium. The dilute solution of the second absorber 3 flows through the second solution heat exchanger 5, the first absorber 2 and absorbs heat making parts of it vaporization. Then the solution enters the steam bleeding chamber 6. Finally, we gain the solution parallel cycle recuperative generation-absorption system.

Compared with the solution tandem cycle recuperative generation-absorption system shown in FIG. 1, the solution parallel cycle recuperative generation-absorption system of FIG. 3 divides the solution into two parts with each independent circulating. The third solution pump 9 is removed in FIG. 3. However, they are both using the releasing heat to satisfy the absorption demand in another process. And the two both belong to the recuperative principle during the thermal cycle.

Seeing from the structure and working principle, the solution independent cycle recuperative generation-absorption system shown in FIG. 4 has no difference with FIG. 3 in essence. But the different between the two is as follows. The first absorber 2 has no heating medium pipe connected external. The solution of the first absorber 2 absorbs the refrigerant vapor and releases heat. And the heat is just used to heat the solution before vaporization.

The recuperative single-stage single-effect second-type absorption heat pump adopting the solution tandem cycle recuperative generation-absorption system shown in FIG. 5 can be realized by the following way:

Firstly, structurally, in the solution tandem cycle generation-absorption system shown in FIG. 1, we use the residual heat medium as the thermal driving medium of the generator 1 and add the condenser A1, evaporator B1, liquid refrigerant pump C1 in the system.

The generator 1 has the refrigerant vapor channel connected external can be considered as that generator 1 has refrigerant vapor channel connected condenser A1. That the steam bleeding chamber 6 has refrigerant vapor channel connected external can be considered as that the steam bleeding chamber 6 has refrigerant vapor channel connected condenser A1. That the first absorber 2 has refrigerant vapor channel connected external can be considered as that evaporator B1 has refrigerant vapor channel connected the first absorber 2. That the second absorber 3 has refrigerant vapor channel connected external can be considered as that evaporator B1 has refrigerant vapor channel connected the second absorber 3. Condenser A1 has liquid refrigerant pipe which passes through liquid refrigerant pump C1 and then connects evaporator B1. Condenser A1 has the cooling medium pipe connected external. Evaporator B1 has the residual heat medium pipe connected external.

Secondly, on the process, the residual heat medium heats up the dilute solution of generator 1 and releases refrigerant vapor provided to condenser A1. The refrigerant vapor released by the steam bleeding chamber is provided to condenser A1. The refrigerant vapor which enters condenser A1 releases heat to the cooling medium becoming liquid refrigerant. The liquid refrigerant of condenser A1 flows through liquid refrigerant pump C1 and then enters evaporator B1. The liquid refrigerant of evaporator B1 is heated by residual heat medium becoming refrigerant vapor. Evaporator B1 separately provides refrigerant vapor to the first absorber 2 and the second absorber 3. The heat release of the first absorber 2 is used to meet the heat demand of heated medium and satisfy the heating demand before the vaporization of solution. The heat release of the second absorber 3 is used to meet the (high temperature) heat demand of heated medium. Finally, we get recuperative single-stage single-effect second-type absorption heat pump.

The recuperative single-stage single-effect second-type absorption heat pump adopting the solution tandem cycle recuperative generation-absorption system shown in FIG. 6 can be realized by the following way:

Firstly, structurally, in the solution tandem cycle generation-absorption system shown in FIG. 2, we use the residual heat medium as the thermal driving medium of generator 1 and add condenser A1, the first evaporator B1, liquid refrigerant pump C1, the second evaporator D1, throttle E1 in the system.

That generator 1 has refrigerant vapor channel connected external can be considered as that generator 1 has refrigerant vapor channel connected condenser A1. That the steam bleeding chamber 6 has refrigerant vapor channel connected external can be considered as that the steam bleeding chamber 6 has refrigerant vapor channel connected condenser A1. That the first absorber 2 has refrigerant vapor channel connected external can be considered as that the first evaporator B1 has refrigerant vapor channel connected the first absorber 2. That the second absorber 3 has refrigerant vapor channel connected external can be considered as that the first evaporator B1 has refrigerant vapor channel connected the second absorber 3. Condenser A1 has liquid refrigerant pipe which passes through liquid refrigerant pump C1 and then connects the first evaporator B1. The first evaporator B1 has liquid refrigerant pipe which passes through throttle E1 and then connects the second evaporator D1. Condenser A1 has the cooling medium pipe connected external. The first evaporator B1 and the second evaporator D1 have the residual heat medium pipe which separately connects external.

Secondly, on the process, the residual heat medium heats up the dilute solution of generator 1 and releases refrigerant vapor provided to condenser A1. The refrigerant vapor released by the steam bleeding chamber 6 is provided to condenser A1. The refrigerant vapor which enters condenser A1 releases heat to the cooling medium becoming liquid refrigerant. The liquid refrigerant of condenser A1 flows through liquid refrigerant pump C1 and then enters the first evaporator B1. One part of liquid refrigerant in the first evaporator B1 absorbs residual heat medium becoming refrigerant vapor while another part of liquid refrigerant flows through throttle E1 and then enters the second evaporator D1. Residual heat medium heats up the liquid refrigerant of the second evaporator D1 becoming refrigerant vapor which is provided to the second absorber 3. The heat release of the first absorber 2 is used to meet the heat demand of heated medium and satisfy the heating demand before the vaporization of solution. The heat release of the second absorber 3 is used to meet the (high temperature) heat demand of heated medium. Finally, we get recuperative single-stage single-effect second-type absorption heat pump.

Compared with FIG. 7 and FIG. 6, the only difference between the two is adopting different recuperative generation-absorption systems.

Similarly, compared with FIG. 8 and FIG. 5, the only difference between the two is adopting different recuperative generation-absorption systems.

The recuperative single generator two-stage second-type absorption heat pump adopting the solution tandem cycle recuperative generation-absorption system shown in FIG. 9 can be realized by the following way:

Firstly, structurally, in the solution tandem cycle generation-absorption system shown in FIG. 1, we use the residual heat medium as the thermal driving medium of generator 1 and add the condenser A2, evaporator B2, absorption-evaporator C2, liquid refrigerant pump D2, throttle E2, the third solution heat exchanger F2 in the system.

We adjust that the dilute solution pipe of the first absorber 2 passes through the first solution heat exchanger 4 and then connects generator 1 to that the dilute solution pipe of absorption-evaporator C2 passes through the first solution heat exchanger 4 and then connects generator 1 after that the dilute solution pipe of the first absorber 2 passes through the third solution heat exchanger F2 and then connects absorption-evaporator C2. We adjust that the concentrated solution pipe of generator 1 passes through the first solution pump 7, the first solution heat exchanger 4, the first absorber 2 and then connects the steam bleeding chamber 6 to that the concentrated solution pipe of generator 1 passes through the first solution pump 7, the first solution heat exchanger 4, the third solution heat exchanger F2, the first absorber 2 and then connects the steam bleeding chamber 6.

That generator 1 has refrigerant vapor channel connected external can be considered as that generator 1 has refrigerant vapor channel connected condenser A2. That the steam bleeding chamber 6 has refrigerant vapor channel connected external can be considered as that the steam bleeding chamber 6 has refrigerant vapor channel connected condenser A2. That the first absorber 2 and the second absorber 3 has refrigerant vapor channel which separately connects external can be considered as that absorption-evaporator C2 has liquid refrigerant pipe which separately connects the first absorber 2 and the second absorber 3 after that condenser A2 has liquid refrigerant pipe which passes through liquid refrigerant pump D2 and then connects absorption-evaporator C2.

The liquid refrigerant pump D2 had liquid refrigerant pipe which passes through throttle E2 and then connects evaporator B2. Evaporator B2 has refrigerant vapor channel connected absorption-evaporator C2. Condenser A2 has the cooling medium pipe connected external. Evaporator B2 has the residual heat medium pipe connected external.

Secondly, on the process, the residual heat medium heats up the dilute solution of generator 1 and releases refrigerant vapor provided to condenser A2. The refrigerant vapor released by the steam bleeding chamber 6 is provided to condenser A2. The refrigerant vapor which enters condenser A2 releases heat to the cooling medium becoming liquid refrigerant. After that the pressure of liquid refrigerant from condenser A2 is promoted by liquid refrigerant pump D2, one part of the liquid refrigerant flows through throttle E2 and then enters evaporator B2 in which it absorbs residual heat vaporization. And another part flows directly through absorption-evaporator C2 vaporization. The refrigerant vapor produced by evaporator B2 is provided to absorption-evaporator C2. The refrigerant vapor produced by absorption-evaporator C2 is separately provided to the first absorber 2 and the second absorber 3.

The dilute solution of the first absorber 2 flows through the third solution heat exchanger F2 and then enters absorption-evaporator C2 in which it absorbs refrigerant vapor coming from evaporator B2 and heats up liquid refrigerant which flows through absorption-evaporator C2. The liquid refrigerant becomes refrigerant vapor. The dilute solution of absorption-evaporator C2 flows through the first solution heat exchanger 4 and then enters generator 1. The heat release of the first absorber 2 is used to meet the heat demand of heated medium and satisfy the heating demand before the vaporization of solution. The heat release of the second absorber 3 is used to meet the (high temperature) heat demand of heated medium. Finally, we get recuperative single generator two-stage second-type absorption heat pump.

The recuperative single generator two-stage second-type absorption heat pump adopting the solution tandem cycle recuperative generation-absorption system shown in FIG. 10 can be realized by the following way:

Firstly, structurally, in the solution tandem cycle generation-absorption system shown in FIG. 2, we use the residual heat medium as the thermal driving medium of generator 1 and add the condenser A2, evaporator B2, absorption-evaporator C2, liquid refrigerant pump D2, the second liquid refrigerant pump G2, the third solution heat exchanger F2 in the system.

We adjust that the dilute solution pipe of the first absorber 2 passes through the first solution heat exchanger 4 and then connects generator 1 to that the dilute solution pipe of the first absorber 2 passes through the third solution heat exchanger F2 and then connects absorption-evaporator C2. The dilute solution pipe of absorption-evaporator C2 passes through the first solution heat exchanger 4 and then connects generator 1. We adjust that the concentrated solution pipe of generator 1 passes through the first solution pump 7, the first solution heat exchanger 4, the first absorber 2 and then connects the steam bleeding chamber 6 to that the concentrated solution pipe of generator 1 passes through the first solution pump 7, the first solution heat exchanger 4, the third solution heat exchanger F2, the first absorber 2 and then connects the steam bleeding chamber 6.

That generator 1 has refrigerant vapor channel connected external can be considered as that generator 1 has refrigerant vapor channel connected condenser A2. That the steam bleeding chamber 6 has refrigerant vapor channel connected external can be considered as that the steam bleeding chamber 6 has refrigerant vapor channel connected condenser A2. That the first absorber 2 and the second absorber 3 has refrigerant vapor channel which separately connects external can be considered as that absorption-evaporator C2 has liquid refrigerant pipe which separately connects the first absorber 2 and the second absorber 3 after that evaporator B2 has liquid refrigerant pipe which passes through the second liquid refrigerant pump G2 and then connects absorption-evaporator C2.

Condenser A2 had liquid refrigerant pipe which passes through liquid refrigerant pump D2 and then connects evaporator B2. Evaporator B2 has refrigerant vapor channel connected absorption-evaporator C2. Condenser A2 has the cooling medium pipe connected external. Evaporator B2 has the residual heat medium pipe connected external.

Secondly, on the process, the residual heat medium heats up the dilute solution of generator 1 and releases refrigerant vapor provided to condenser A2. The refrigerant vapor released by the steam bleeding chamber 6 is provided to condenser A2. The refrigerant vapor which enters condenser A2 releases heat to the cooling medium becoming liquid refrigerant. After that the pressures of liquid refrigerant from condenser A2 is promoted by liquid refrigerant pump D2, the liquid refrigerant enters evaporator G2. In the evaporator, one part of the liquid refrigerant absorbs residual heat vaporization while another part flows directly through absorption-evaporator C2 vaporization. The refrigerant vapor produced by evaporator B2 is provided to absorption-evaporator C2. The refrigerant vapor produced by absorption-evaporator C2 is separately provided to the first absorber 2 and the second absorber 3.

The dilute solution of the first absorber 2 flows through the third solution heat exchanger F2 and then enters absorption—evaporator C2 in which it absorbs refrigerant vapor coming from evaporator B2 and heats up liquid refrigerant which flows through absorption-evaporator C2. The liquid refrigerant becomes refrigerant vapor. The dilute solution of absorption-evaporator C2 flows through the first solution heat exchanger 4 and then enters generator 1. The heat release of the first absorber 2 is used to satisfy the heating demand before the vaporization of solution. The heat release of the second absorber 3 is used to meet the (high temperature) heat demand of heated medium. Finally, we get recuperative single generator two-stage second-type absorption heat pump.

The recuperative single generator two-stage second-type absorption heat pump adopting the solution independent cycle recuperative generation-absorption system shown in FIG. 11 can be realized by the following way:

Firstly, Structurally, in the solution independent cycle generation-absorption system shown in FIG. 3, we use the residual heat medium as the thermal driving medium of generator 1 and add the condenser A2, evaporator B2, absorption-evaporator C2, liquid refrigerant pump D2, the second liquid refrigerant pump G2, the third solution heat exchanger F2 in the system.

We adjust that the dilute solution pipe of the first absorber 2 passes through the first solution heat exchanger 4 and then connects generator 1 to that the dilute solution pipe of absorption-evaporator C2 passes through the first solution heat exchanger 4 and then connects generator 1 after that the dilute solution pipe of the first absorber 2 passes through the third solution heat exchanger F2 and then connects absorption-evaporator C2. We adjust that the concentrated solution pipe of generator 1 passes through the first solution pump 7, the first solution heat exchanger 4 and then connects the first absorber 2 to that the concentrated solution pipe of generator 1 passes through the first solution pump 7, the first solution heat exchanger 4, the third solution heat exchanger F2 and then connects the first absorber 2.

That generator 1 has refrigerant vapor channel connected external can be considered as that generator 1 has refrigerant vapor channel connected condenser A2. That the steam bleeding chamber 6 has refrigerant vapor channel connected external can be considered as that the steam bleeding chamber 6 has refrigerant vapor channel connected condenser A2. That the first absorber 2 and the second absorber 3 has refrigerant vapor channel which separately connects external can be considered as that absorption-evaporator C2 has liquid refrigerant pipe which separately connects the first absorber 2 and the second absorber 3 after that evaporator B2 has liquid refrigerant pipe which passes through the second liquid refrigerant pump G2 and then connects absorption-evaporator C2.

Condenser A2 had liquid refrigerant pipe which passes through liquid refrigerant pump D2 and then connects evaporator B2. Evaporator B2 has refrigerant vapor channel connected absorption-evaporator C2. Condenser A2 has the cooling medium pipe connected external. Evaporator B2 has the residual heat medium pipe connected external.

Secondly, on the process, the residual heat medium heats up the dilute solution of generator 1 and releases refrigerant vapor provided to condenser A2. The refrigerant vapor released by the steam bleeding chamber 6 is provided to condenser A2. The refrigerant vapor which enters condenser A2 releases heat to the cooling medium becoming liquid refrigerant. After that the pressures of liquid refrigerant from condenser A2 is promoted by liquid refrigerant pump D2, the liquid refrigerant enters evaporator G2. In the evaporator, one part of the liquid refrigerant absorbs residual heat vaporization while another part flows directly through absorption-evaporator C2 vaporization. The refrigerant vapor produced by evaporator B2 is provided to absorption-evaporator C2. The refrigerant vapor produced by absorption-evaporator C2 is separately provided to the first absorber 2 and the second absorber 3.

The dilute solution of the first absorber 2 flows through the third solution heat exchanger F2 and then enters absorption-evaporator C2 in which it absorbs refrigerant vapor coming from evaporator B2 and heats up liquid refrigerant which flows through absorption-evaporator C2. The liquid refrigerant becomes refrigerant vapor. The dilute solution of absorption-evaporator C2 flows through the first solution heat exchanger 4 and then enters generator 1. The heat release of the first absorber 2 is used to meet the heat demand of heated medium and satisfy the heating demand before the vaporization of solution. The heat release of the second absorber 3 is used to meet the (high temperature) heat demand of heated medium. Finally, we get recuperative single generator two-stage second-type absorption heat pump.

The recuperative single generator two-stage second-type absorption heat pump adopting the solution independent cycle recuperative generation-absorption system shown in FIG. 12 can be realized by the following way:

Firstly, structurally, in the solution independent cycle generation-absorption system shown in FIG. 4, we use the residual heat medium as the thermal driving medium of generator 1 and add condenser A2, evaporator B2, absorption-evaporator C2, liquid refrigerant pump D2, throttle E2, the third solution heat exchanger F2 in the system.

We adjust that the dilute solution pipe of the first absorber 2 passes through the first solution heat exchanger 4 and then connects generator 1 to that the dilute solution pipe of absorption-evaporator C2 passes through the first solution heat exchanger 4 and then connects generator 1 after that the dilute solution pipe of the first absorber 2 passes through the third solution heat exchanger F2 and then connects absorption-evaporator C2. We adjust that the concentrated solution pipe of generator 1 passes through the first solution pump 7, the first solution heat exchanger 4 and then connects the first absorber 2 to that the concentrated solution pipe of generator 1 passes through the first solution pump 7, the first solution heat exchanger 4, the third solution heat exchanger F2 and then connects the first absorber 2.

That generator 1 has refrigerant vapor channel connected external can be considered as that generator 1 has refrigerant vapor channel connected condenser A2. That the steam bleeding chamber 6 has refrigerant vapor channel connected external can be considered as that the steam bleeding chamber 6 has refrigerant vapor channel connected condenser A2. That the first absorber 2 and the second absorber 3 has refrigerant vapor channel which separately connects external can be considered as that absorption—evaporator C2 has liquid refrigerant pipe which separately connects the first absorber 2 and the second absorber 3 after that condenser A2 has liquid refrigerant pipe which passes through liquid refrigerant pump D2 and then connects absorption-evaporator C2.

Liquid refrigerant pump D2 had liquid refrigerant pipe which passes through throttle E2 and then connects evaporator B2. Evaporator B2 has refrigerant vapor channel connected absorption—evaporator C2. Condenser A2 has the cooling medium pipe connected external. Evaporator B2 has the residual heat medium pipe connected external.

Secondly, on the process, the residual heat medium heats up the dilute solution of generator 1 and releases refrigerant vapor provided to condenser A2. The refrigerant vapor released by the steam bleeding chamber 6 is provided to condenser A2. The refrigerant vapor which enters condenser A2 releases heat to the cooling medium becoming liquid refrigerant. After that the pressure of liquid refrigerant from condenser A2 is promoted by liquid refrigerant pump D2, one part of the liquid refrigerant flows through throttle E2 and then enters evaporator B2 in which it absorbs residual heat vaporization. And another part flows directly through absorption—evaporator C2 vaporization. The refrigerant vapor produced by evaporator B2 is provided to absorption-evaporator C2. The refrigerant vapor produced by absorption—evaporator C2 is separately provided to the first absorber 2 and the second absorber 3.

The dilute solution of the first absorber 2 flows through the third solution heat exchanger F2 and then enters absorption-evaporator C2 in which it absorbs refrigerant vapor coming from evaporator B2 and heats up liquid refrigerant which flows through absorption—evaporator C2. The liquid refrigerant becomes refrigerant vapor. The dilute solution of absorption-evaporator C2 flows through the first solution heat exchanger 4 and then enters generator 1. The heat release of the first absorber 2 is used to satisfy the heating demand before the vaporization of solution. The heat release of the second absorber 3 is used to meet the (high temperature) heat demand of heated medium. Finally, we get recuperative single generator two-stage second-type absorption heat pump.

The recuperative single generator three-stage second-type absorption heat pump adopting the solution tandem cycle recuperative generation-absorption system shown in FIG. 13 can be realized by the following way:

Firstly, Structurally, in the solution tandem cycle generation-absorption system shown in FIG. 1, we use the residual heat medium as the thermal driving medium of generator 1 and add condenser A3, evaporator B3, one-stage absorption-evaporator C3, two-stage absorption-evaporator D3, liquid refrigerant pump E3, the first throttle F3, the second throttle G3, the third solution heat exchanger H3, the fourth solution heat exchanger I3 in the system.

We adjust that the dilute solution pipe of the first absorber 2 passes through the first solution heat exchanger 4 and then connects generator 1 to that the dilute solution pipe of the first absorber 2 passes through the third solution heat exchanger H3 and then connects two-stage absorption-evaporator D3. Two-stage absorption-evaporator D3 has the dilute solution pipe which passes through the fourth solution heat exchanger I3 and then connects one-stage absorption-evaporator C3. One-stage absorption-evaporator C3 has the dilute solution pipe which passes through the first solution heat exchanger 4 and connects generator 1. We adjust that the concentrated solution pipe of generator 1 passes through the first solution pump 7, the first solution heat exchanger 4, the first absorber 2 and then connects the steam bleeding chamber 6 to that the concentrated solution pipe of generator 1 passes through the first solution pump 7, the first solution heat exchanger 4, the fourth solution heat exchanger I3, the third solution heat exchanger H3, the first absorber 2 and then connects the steam bleeding chamber 6.

That generator 1 has refrigerant vapor channel connected external can be considered as that generator 1 has refrigerant vapor channel connected condenser A3. That the steam bleeding chamber 6 has refrigerant vapor channel connected external can be considered as that the steam bleeding chamber 6 has refrigerant vapor channel connected condenser A3. That the first absorber 2 and the second absorber 3 has refrigerant vapor channel which separately connects external can be considered as that two-stage absorption-evaporator D3 has refrigerant vapor channel which separately connects the first absorber 2 and the second absorber 3 after that condenser A3 has liquid refrigerant pipe which passes through liquid refrigerant pump E3 and then connects two-stage absorption-evaporator D3.

Liquid refrigerant pump E3 had liquid refrigerant pipe which passes through the first throttle F3 and then connects evaporator B3. Evaporator B3 has refrigerant vapor channel connected one-stage absorption-evaporator C3. After that liquid refrigerant pump E3 has liquid refrigerant pipe which passes through the second throttle G3 and connects one-stage absorption-evaporator C3, one-stage absorption-evaporator C3 has refrigerant vapor channel connected two-stage absorption-evaporator D3. Condenser A3 has the cooling medium pipe connected external. Evaporator B3 has the residual heat medium pipe connected external.

Secondly, on the process, the residual heat medium heats up the dilute solution of generator 1 and releases refrigerant vapor provided to condenser A3. The refrigerant vapor released by the steam bleeding chamber 6 is provided to condenser A3. The refrigerant vapor which enters condenser A3 releases heat to the cooling medium becoming liquid refrigerant.

After that the pressures of liquid refrigerant from condenser A3 is promoted by liquid refrigerant pump D2, the liquid refrigerant can be divided into three parts. The first part of the liquid refrigerant flows through the first throttle F3 and then enters evaporator B3 in which it absorbs residual heat becoming refrigerant vapor provided to one-stage absorption-evaporator C3. The second part flows through the second throttle G3, one-stage absorption-evaporator C3 and absorbs heat becoming refrigerant vapor provided to two-stage absorption-evaporator D3. The third part flows directly through two-stage absorption-evaporator D3 and absorbs heat becoming refrigerant vapor which is separately provided to the first absorber 2 and the second absorber 3.

The dilute solution of the first absorber 2 flows through the third solution heat exchanger H3 and then enters two-stage absorption-evaporator D3 in which it absorbs refrigerant vapor coming from one-stage absorption-evaporator C3 and releases heat to the liquid refrigerant which flows through two-stage absorption-evaporator D3. And the liquid refrigerant becomes refrigerant vapor.

The dilute solution of two-stage absorption-evaporator D3 flows through the fourth solution heat exchanger I3 and then enters one-stage absorption-evaporator C3 where it absorbs refrigerant vapor coming from evaporator B3 and releases heat to the liquid refrigerant which flows through one-stage absorption-evaporator C3. The liquid refrigerant becomes refrigerant vapor. The dilute solution of one-stage absorption-evaporator C3 flows through the first solution heat exchanger 4 and then enters generator 1. The heat release of the first absorber 2 is used to meet the heat demand of heated medium and satisfy the heating demand before the solution vaporization. The heat release of the second absorber 3 is used to meet the (high temperature) heat demand of heated medium. Finally, we get recuperative single generator three-stage second-type absorption heat pump.

The recuperative single generator three-stage second-type absorption heat pump adopting the solution independent cycle recuperative generation-absorption system shown in FIG. 14 can be realized by the following way:

Firstly, Structurally, in the solution independent cycle generation-absorption system shown in FIG. 3, we use the residual heat medium as the thermal driving medium of generator 1 and add condenser A3, evaporator B3, one-stage absorption-evaporator C3, two-stage absorption-evaporator D3, the first liquid refrigerant pump E3, the third solution heat exchanger H3, the fourth solution heat exchanger I3, the second liquid refrigerant pump J3, the third liquid refrigerant pump K3 in the system.

We adjust that the dilute solution pipe of the first absorber 2 passes through the first solution heat exchanger 4 and then connects generator 1 to that the dilute solution pipe of the first absorber 2 passes through the third solution heat exchanger H3 and then connects two-stage absorption-evaporator D3. Two-stage absorption-evaporator D3 has the dilute solution pipe which passes through the fourth solution heat exchanger I3 and then connects one-stage absorption-evaporator C3. One-stage absorption-evaporator C3 has the dilute solution pipe which passes through the first solution heat exchanger 4 and connects generator 1. We adjust that the concentrated solution pipe of generator 1 passes through the first solution pump 7, the first solution heat exchanger 4 and then connects the first absorber 2 to that the concentrated solution pipe of generator 1 passes through the first solution pump 7, the first solution heat exchanger 4, the fourth solution heat exchanger I3, the third solution heat exchanger H3 and then connects the first absorber 2.

That generator 1 has refrigerant vapor channel connected external can be considered as that generator 1 has refrigerant vapor channel connected condenser A3. That the steam bleeding chamber 6 has refrigerant vapor channel connected external can be considered as that the steam bleeding chamber 6 has refrigerant vapor channel connected condenser A3. That the first absorber 2 and the second absorber 3 has refrigerant vapor channel which separately connects external can be considered as that two-stage absorption-evaporator D3 has refrigerant vapor channel which separately connects the first absorber 2 and the second absorber 3 after that evaporator B3 has liquid refrigerant pipe which passes through the second liquid refrigerant pump J3, the third liquid refrigerant pump K3 and then connects two-stage absorption-evaporator D3.

After that the second liquid refrigerant pump J3 has liquid refrigerant pipe connected one-stage absorption-evaporator C3, one-stage absorption-evaporator C3 has refrigerant vapor channel connected two-stage absorption-evaporator D3. Condenser A3 had liquid refrigerant pipe which passes through the first liquid refrigerant pump E3 and then connects evaporator B3. Evaporator B3 has refrigerant vapor channel connected one-stage absorption-evaporator C3. Condenser A3 has the cooling medium pipe connected external. Evaporator B3 has the residual heat medium pipe connected external.

Secondly, on the process, the residual heat medium heats up the dilute solution of generator 1 and releases refrigerant vapor provided to condenser A3. The refrigerant vapor released by the steam bleeding chamber 6 is provided to condenser A3. The refrigerant vapor which enters condenser A3 releases heat to the cooling medium becoming liquid refrigerant.

After that the pressure of liquid refrigerant from condenser A3 is promoted by liquid refrigerant pump D2. Then the liquid refrigerant enters evaporator B3 and is divided into two parts. One part of the liquid refrigerant absorbs residual heat becoming refrigerant vapor provided to one-stage absorption-evaporator C3. After that the pressure of another part is promoted by the second liquid refrigerant pump J3, this part is decided into two parts too. One of the parts flows through one-stage absorption—evaporator C3 and absorbs heat becoming refrigerant vapor provided to two-stage absorption-evaporator D3. After that the other part's pressure is increased by the third liquid refrigerant pump K3 again, it flows through two-stage absorption-evaporator D3 and absorbs heat becoming refrigerant vapor which is separately provided to the first absorber 2 and the second absorber 3.

The dilute solution of the first absorber 2 flows through the third solution heat exchanger H3 and then enters two-stage absorption-evaporator D3 in which it absorbs refrigerant vapor coming from one-stage absorption-evaporator C3 and releases heat to the liquid refrigerant which flows through two-stage absorption-evaporator D3. And the liquid refrigerant becomes refrigerant vapor.

The dilute solution of two-stage absorption-evaporator D3 flows through the fourth solution heat exchanger I3 and then enters one-stage absorption-evaporator C3 where it absorbs refrigerant vapor coming from evaporator B3 and releases heat to the liquid refrigerant which flows through one-stage absorption-evaporator C3. The liquid refrigerant becomes refrigerant vapor. The dilute solution of one-stage absorption-evaporator C3 flows through the first solution heat exchanger 4 and then enters generator 1. The heat release of the first absorber 2 is used to meet the heat demand of heated medium and satisfy the heating demand before the solution vaporization. The heat release of the second absorber 3 is used to meet the (high temperature) heat demand of heated medium. Finally, we get recuperative single generator three-stage second-type absorption heat pump.

The recuperative two-generator two-stage second-type absorption heat pump adopting the solution tandem cycle recuperative generation-absorption system shown in FIG. 15 can be realized by the following way:

Firstly, structurally, in the solution tandem cycle generation-absorption system shown in FIG. 1, we add condenser A4, evaporator B4, absorption-evaporator C4, liquid refrigerant pump D4, the first throttle E4, low-temperature generator F4, the fourth solution pump G4, the second throttle H4, the third solution heat exchanger I4 in the system.

We adjust that the dilute solution pipe of the first absorber 2 passes through the first solution heat exchanger 4 and then connects generator 1 to that the dilute solution pipe of the first absorber 2 passes through the first solution heat exchanger 4 and then connects absorption-evaporator C4. Absorption-evaporator C4 has the dilute solution pipe which passes through the third solution heat exchanger I4 and then connects low-temperature generator F4.

Low-temperature generator F4 has the concentrated solution pipe which passes through the fourth solution pump G4, the third solution heat exchanger I4 and connects generator 1. That the first absorber 2 and the second absorber 3 has refrigerant vapor channel which separately connects external can be considered as that absorption-evaporator C4 has refrigerant vapor channel which separately connects the first absorber 2 and the second absorber 3 after that condenser A4 has liquid refrigerant pipe which passes through liquid refrigerant pump D4 and then connects absorption-evaporator C4.

That generator 1 has thermal driving medium pipe connected external can be considered as that the liquid refrigerant pump D4 has liquid refrigerant pipe connected absorption-evaporator C4, absorption-evaporator C4 has refrigerant vapor channel connected generator 1, generator 1 has liquid refrigerant pipe which passes through the first throttle E4 and then connects condenser A4. A part of the refrigerant vapor produced by absorption-evaporator C4 is used as the thermal driving medium of generator 1. The liquid refrigerant pump D4 has liquid refrigerant pipe which passes through the second throttle F4 and then connects evaporator B4. That generator 1 has refrigerant vapor channel connected external can be considered as that generator 1 has refrigerant vapor channel connected condenser A4. That the steam bleeding chamber 6 has refrigerant vapor channel connected external can be considered as that the steam bleeding chamber 6 has refrigerant vapor channel connected condenser A4. Evaporator B4 has the residual heat medium pipe connected external and the refrigerant vapor channel connected absorption-evaporator C4. Low-temperature generator F4 has the residual heat medium pipe connected external and the refrigerant vapor channel connected condenser A4.

Secondly, on the process, the residual heat medium heats up the dilute solution of low-temperature generator F4 which flows through the third solution heat exchanger I4 and enters low-temperature generator F4 from absorption-evaporator C4 and the dilute solution releases refrigerant vapor which provided to condenser A4. The concentrated solution of low-temperature generator F4 flows through the fourth solution pump G4, the third solution heat exchanger I4 and then enters the first absorber 1 in which it is heated and releases refrigerant vapor provided to condenser A4. The steam bleeding chamber 6 releases refrigerant vapor provided to condenser A4. The refrigerant vapor is used as the thermal driving medium and releases heat becoming liquid refrigerant. After that, the liquid refrigerant flows through the first throttle E4 and then enters condenser A4. The refrigerant vapor which enters condenser A4 releases heat to cooling medium and becomes liquid refrigerant.

The liquid refrigerant of condenser A4 flows through the liquid refrigerant pump D4 and its pressure is promoted. After that, a part of the liquid refrigerant flows through the second throttle H4 and then enters evaporator B4 in which it absorbs residual heat becoming refrigerant vapor. Another part flows through absorption-evaporator C4 and absorbs heat becoming refrigerant vapor. The refrigerant vapor produced by evaporator B4 is provided to absorption-evaporator C4. The refrigerant vapor produced by absorption-evaporator C4 is separately provided to the first absorber 2 and the second absorber 3. And the refrigerant vapor is also provided to the first generator 1 in which it is used as thermal driving medium. The dilute solution of the first absorber 2 flows through the first solution heat exchanger 4 and then enters absorption-evaporator C4 in which it absorbs the refrigerant vapor coming from evaporator B4 and heats up the liquid refrigerant which flows through absorption-evaporator C4 and becomes refrigerant vapor. The dilute solution of absorption-evaporator C4 flows through the third solution heat exchanger I4 and then enters low-temperature generator F4. The heat release of the first to absorber 2 is used to meet the heat demand of heated medium and satisfy the heating demand before the solution vaporization. The heat release of the second absorber 3 is used to meet the (high temperature) heat demand of heated medium. Finally, we get recuperative two generator two-stage second-type absorption heat pump.

The recuperative two-generator two-stage second-type absorption heat pump adopting the solution independent cycle recuperative generation-absorption system shown in FIG. 16 can be realized by the following way:

Firstly, Structurally, in the solution independent cycle generation-absorption system shown in FIG. 3, we add condenser A4, evaporator B4, absorption-evaporator C4, the first liquid refrigerant pump D4, throttle E4, low-temperature generator F4, the fourth solution pump G4 the third solution heat exchanger I4, the second liquid refrigerant pump J4 in the system.

We adjust that the dilute solution pipe of the first absorber 2 passes through the first solution heat exchanger 4 and then connects generator 1 to that the dilute solution pipe of the first absorber 2 passes through the first solution heat exchanger 4 and then connects absorption-evaporator C4. Absorption-evaporator C4 has the dilute solution pipe which passes through the third solution heat exchanger I4 and then connects low-temperature generator F4.

Low-temperature generator F4 has the concentrated solution pipe which passes through the fourth solution pump G4, the third solution heat exchanger I4 and connects generator 1. That the first absorber 2 and the second absorber 3 has refrigerant vapor channel which separately connects external can be considered as that absorption-evaporator C4 has refrigerant vapor channel which separately connects the first absorber 2 and the second absorber 3 after that evaporator B4 has liquid refrigerant pipe which passes through the second liquid refrigerant pump J4 and then connects absorption-evaporator C4.

That generator 1 has thermal driving medium pipe connected external can be considered as that the second liquid refrigerant pump J4 has liquid refrigerant pipe connected absorption-evaporator C4, absorption-evaporator C4 has refrigerant vapor channel connected generator 1, generator 1 has liquid refrigerant pipe which passes through the first throttle E4 and then connects condenser A4. A part of the refrigerant vapor produced by absorption-evaporator C4 is used as the thermal driving medium of generator 1. That generator 1 has refrigerant vapor channel connected external can be considered as that generator 1 has refrigerant vapor channel connected condenser A4. That the steam bleeding chamber 6 has refrigerant vapor channel connected external can be considered as that the steam bleeding chamber 6 has refrigerant vapor channel connected condenser A4. Condenser A4 has the liquid refrigerant pipe which flows through the first liquid refrigerant pump D4 and then enters evaporator B4. Evaporator B4 has the residual heat medium pipe connected external and the refrigerant vapor channel connected absorption-evaporator C4. Low-temperature generator F4 has the residual heat medium pipe connected external and the refrigerant vapor channel connected condenser A4.

Secondly, on the process, the residual heat medium heats up the dilute solution of low-temperature generator F4 which flows through the third solution heat exchanger I4 and enters low-temperature generator F4 from absorption-evaporator C4 and the dilute solution releases refrigerant vapor which is provided to condenser A4. The concentrated solution of low-temperature generator F4 flows through the fourth solution pump G4, the third solution heat exchanger I4 and then enters the first absorber 1 in which it is heated and releases refrigerant vapor provided to condenser A4. The steam bleeding chamber 6 releases refrigerant vapor provided to condenser A4. The refrigerant vapor is used as the thermal driving medium and releases heat becoming liquid refrigerant. After that, the liquid refrigerant flows through the first throttle E4 and then enters condenser A4. The refrigerant vapor which enters condenser A4 releases heat to cooling medium and becomes liquid refrigerant.

The liquid refrigerant of condenser A4 flows through the liquid refrigerant pump D4 and its pressure is promoted. After that, the liquid refrigerant enters evaporator B4 in which a part of the liquid refrigerant absorbs residual heat becoming refrigerant vapor. Another part flows through the second liquid refrigerant pump J4 and its pressure is increased again. This part of liquid refrigerant flows through absorption-evaporator C4. and absorbs heat becoming refrigerant vapor too. The refrigerant vapor produced by evaporator B4 is provided to absorption-evaporator C4. The refrigerant vapor produced by absorption-evaporator C4 is separately provided to the first absorber 2 and the second absorber 3. And the refrigerant vapor is also provided to the first generator 1 in which it is used as thermal driving medium.

The dilute solution of the first absorber 2 flows through the first solution heat exchanger 4 and then enters absorption-evaporator C4 in which it absorbs the refrigerant vapor coming from evaporator B4 and heats up the liquid refrigerant which flows through absorption-evaporator C4 and becomes refrigerant vapor. The dilute solution of absorption-evaporator C4 flows through the third solution heat exchanger I4 and then enters low-temperature generator F4. The heat release of the first absorber 2 is used to meet the heat demand of heated medium and satisfy the heating demand before the solution vaporization. The heat release of the second absorber 3 is used to meet the (high temperature) heat demand of heated medium. Finally, we get recuperative two generator two-stage second-type absorption heat pump.

The recuperative single stage tandem double-effect second-type absorption heat pump adopting the solution tandem cycle recuperative generation-absorption system shown in FIG. 17 can be realized by the following way:

Firstly, structurally, in the solution tandem cycle generation-absorption system shown in FIG. 1, we add the second generator A5, condenser B5, evaporator C5, throttle D5, liquid refrigerant pump E5.

Taking the second generator A5 as high pressure generator, we adjust that the concentrated solution pipe of generator 1 passes through the first solution pump 7, the first solution heat exchanger 4, the first absorber 2 and then connects the steam bleeding chamber 6 to that t the concentrated solution pipe of generator 1 passes through the first solution pump 7 and then connects the second generator A5, then the second generator A5 has the concentrated solution pipe which passes through the first solution heat exchanger 4, the first absorber 2 and then connects the steam bleeding chamber 6. We adjust that the first generator 1 has thermal driving medium connected external to that the first generator 1 has cooling medium pipe which flows through the first throttle D5 and then connects condenser B5 after that the second generator A5 has refrigerant vapor channel connected the first generator 1.

The refrigerant vapor produced by the second generator A5 is used as the thermal driving medium of the first generator 1. That the first generator 1 has refrigerant vapor channel connected external can be considered as the first generator 1 has refrigerant vapor channel connected condenser B5. That the steam bleeding chamber 6 has refrigerant vapor channel connected external can be considered as that the steam bleeding chamber 6 has refrigerant vapor channel connected condenser B5. That the first absorber 2 has refrigerant vapor channel connected external can be considered as that evaporator C5 has refrigerant vapor channel connected the first absorber 2. That the second absorber 3 has refrigerant vapor channel connected external can be considered as that evaporator C5 has refrigerant vapor channel connected the second absorber 3. Condenser B5 has the liquid refrigerant pipe which flows through liquid refrigerant pump E5 and then connects evaporator C5. Condenser B5 has the cooling medium pipe connected external. The second generator A5 and evaporator C5 has residual medium pipe connected external too.

Secondly, on the process, the residual heat medium heat up the solution which flows through the first solution pump 7 and enters the second generator A5 from the first generator 1. And the solution releases refrigerant vapor which is provided to the first generator 1 and is used as thermal driving medium.

The concentrated solution of the second generator A5 flows through the first solution heat exchanger 4, the first absorber 2 and then enters the steam bleeding chamber 6. The refrigerant vapor which is used as thermal driving medium releases heat and become liquid refrigerant. And the liquid refrigerant flows through throttle D5 and then enters condenser B5. The refrigerant vapor produced by the first generator enters condenser B5. The refrigerant vapor produced by the steam bleeding chamber 6 enters liquid refrigerant. The refrigerant vapor entered the condenser B5 releases heat to the cooling medium and becomes liquid refrigerant. The liquid refrigerant of condenser B5 flows through liquid refrigerant pump E5 and its pressure is promoted. Then it enters evaporator C5 and absorbs residual medium becoming refrigerant vapor which is separately provided to the first absorber 2 and the second absorber 3. The heat release of the first absorber 2 is used to meet the heat demand of heated medium and satisfy the heating demand before the solution vaporization. The heat release of the second absorber 3 is used to meet the (high temperature) heat demand of heated medium. Finally, we get recuperative single stage tandem double-effect second-type absorption heat pump.

The recuperative single stage tandem double-effect second-type absorption heat pump adopting the solution tandem cycle recuperative generation-absorption system shown in FIG. 18 can be realized by the following way:

Firstly, Structurally, in the solution tandem cycle generation-absorption system shown in FIG. 2, we add the second generator A5, condenser B5, the first evaporator C5, the first throttle D5, liquid refrigerant pump E5, the second evaporator F5, the second throttle G5.

Taking the second generator A5 as high pressure generator, we adjust that the concentrated solution pipe of generator 1 passes through the first solution pump 7, the first solution heat exchanger 4, the first absorber 2 and then connects the steam bleeding chamber 6 to that the concentrated solution pipe of generator 1 passes through the first solution pump 7 and then connects the second generator A5, then the second generator A5 has the concentrated solution pipe which passes through the first solution heat exchanger 4, the first absorber 2 and then connects the steam bleeding chamber 6. We adjust that the first generator 1 has thermal driving medium connected external to that the first generator 1 has cooling medium pipe which flows through the first throttle D5 and then connects condenser B5 after that the second generator A5 has refrigerant vapor channel connected the first generator 1.

The refrigerant vapor produced by the second generator A5 is used as the thermal driving medium of the first generator 1. That the first generator 1 has refrigerant vapor channel connected external can be considered as the first generator 1 has refrigerant vapor channel connected condenser B5. That the steam bleeding chamber 6 has refrigerant vapor channel connected external can be considered as that the steam bleeding chamber 6 has refrigerant vapor channel connected condenser B5. That the first absorber 2 has refrigerant vapor channel connected external can be considered as that the second evaporator F5 has refrigerant vapor channel connected the first absorber 2. That the second absorber 3 has refrigerant vapor channel connected external can be considered as that the first evaporator C5 has refrigerant vapor channel connected the second absorber 3. Condenser B5 has the liquid refrigerant pipe which flows through liquid refrigerant pump E5 and then connects the first evaporator C5. The first evaporator C5 has the liquid refrigerant pipe which passes through the second throttle G5 and then connects the second evaporator F5. Condenser B5 has the cooling medium pipe connected external. The second generator A5, the first evaporator C5 and the second evaporator F5 has residual medium pipe connected external too.

Secondly, on the process, the residual heat medium heat up the solution which flows through the first solution pump 7 and enters the second generator A5 from the first generator 1. And the solution releases refrigerant vapor which is provided to the first generator 1 and is used as thermal driving medium.

The concentrated solution of the second generator A5 flows through the first solution heat exchanger 4, the first absorber 2 and then enters the steam bleeding chamber 6. The refrigerant vapor which is used as thermal driving medium releases heat and become liquid refrigerant. And the liquid refrigerant flows through throttle D5 and then enters condenser B5. The refrigerant vapor produced by the first generator enters condenser B5. The refrigerant vapor produced by the steam bleeding chamber 6 enters liquid refrigerant. The refrigerant vapor entered the condenser B5 releases heat to the cooling medium and becomes liquid refrigerant.

The liquid refrigerant of condenser B5 flows through liquid refrigerant pump E5 and its pressure is promoted. Then it enters the first evaporator C5. The liquid refrigerant which enters the first evaporator C5 is divided into two parts. A part of the liquid refrigerant absorbs residual medium becoming refrigerant vapor which is provided to the second absorber 3. The other part flows through the second throttle G5 and then enters the second evaporator F5 in which it absorbs residual heat medium becoming refrigerant vapor which is provided to the first absorber 2. The heat release of the first absorber 2 is used to meet the heat demand of heated medium and satisfy the heating demand before the solution vaporization. The heat release of the second absorber 3 is used to meet the (high temperature) heat demand of heated medium. Finally, we get recuperative single stage tandem double-effect second-type absorption heat pump.

The recuperative single stage tandem double-effect second-type absorption heat pump adopting the solution independent cycle recuperative generation-absorption system shown in FIG. 19 can be realized by the following way:

Firstly, Structurally, in the solution independent cycle generation-absorption system shown in FIG. 3, we add the third solution pump 9, the second generator A5, condenser B5, the first evaporator C5, the first throttle D5, liquid refrigerant pump E5.

Taking the second generator A5 as high pressure generator, we adjust that the concentrated solution pipe of generator 1 passes through the first solution pump 7, the first solution heat exchanger 4 and then connects the first absorber 2 to that t the concentrated solution pipe of generator 1 passes through the first solution pump 7 and then connects the second generator A5, then the second generator A5 has the concentrated solution pipe which passes through the third solution pump 9, the first solution heat exchanger 4 and then connects the first absorber 2. We adjust that the first generator 1 has thermal driving medium connected external to that the first generator 1 has cooling medium pipe which flows through the first throttle D5 and then connects condenser B5 after that the second generator A5 has refrigerant vapor channel connected the first generator 1.

The refrigerant vapor produced by the second generator A5 is used as the thermal driving medium of the first generator 1. That the first generator 1 has refrigerant vapor channel connected external can be considered as the first generator 1 has refrigerant vapor channel connected condenser B5. That the steam bleeding chamber 6 has refrigerant vapor channel connected external can be considered as that the steam bleeding chamber 6 has refrigerant vapor channel connected condenser B5. That the first absorber 2 has refrigerant vapor channel connected external can be considered as that evaporator D5 has refrigerant vapor channel connected the first absorber 2. That the second absorber 3 has refrigerant vapor channel connected external can be considered as that evaporator C5 has refrigerant vapor channel connected the second absorber 3. Condenser B5 has the liquid refrigerant pipe which flows through liquid refrigerant pump E5 and then connects evaporator C5. Condenser B5 has the cooling medium pipe connected external. The second generator A5 and evaporator C5 has residual medium pipe connected external too.

Secondly, on the process, the residual heat medium heat up the solution which flows through the first solution pump 7 and enters the second generator A5 from the first generator 1. And the solution releases refrigerant vapor which is provided to the first generator 1 and is used as thermal driving medium.

The concentrated solution of the second generator A5 flows through the third solution pump 9, the first solution heat exchanger 4 and then enters the first absorber 2. The refrigerant vapor which is used as thermal driving medium releases heat and become liquid refrigerant. And the liquid refrigerant flows through throttle D5 and then enters condenser B5. The refrigerant vapor produced by the first generator 1 enters condenser B5. The refrigerant vapor produced by the steam bleeding chamber 6 enters liquid refrigerant. The refrigerant vapor entered the condenser B5 releases heat to the cooling medium and becomes liquid refrigerant. The liquid refrigerant of condenser B5 flows through liquid refrigerant pump E5 and its pressure is promoted. Then it enters evaporator C5. The liquid refrigerant which enters the first evaporator C5 absorbs residual heat medium becoming refrigerant vapor which is separately provided to the first absorber 2 and the second absorber 3. The heat release of the first absorber 2 is used to meet the heat demand of heated medium and satisfy the heating demand before the solution vaporization. The heat release of the second absorber 3 is used to meet the (high temperature) heat demand of heated medium. Finally, we get recuperative single stage tandem double-effect second-type absorption heat pump.

The recuperative single stage tandem double-effect second-type absorption heat pump adopting the solution independent cycle recuperative generation-absorption system shown in FIG. 20 can be realized by the following way:

Firstly, Structurally, in the solution independent cycle generation-absorption system shown in FIG. 4, we add the third solution pump 9, the second generator A5, condenser B5, the first evaporator C5, the first throttle D5, liquid refrigerant pump E5, the second evaporator F5, the second throttle G5.

Taking the second generator A5 as high pressure generator, we adjust that the concentrated solution pipe of generator 1 passes through the first solution pump 7, the first solution heat exchanger 4 and then connects the first absorber 2 to that t the concentrated solution pipe of generator 1 passes through the first solution pump 7 and then connects the second generator A5, then the second generator A5 has the concentrated solution pipe which passes through the third solution pump 9, the first solution heat exchanger 4 and then connects the first absorber 2. We adjust that the first generator 1 has thermal driving medium connected external to that the first generator 1 has cooling medium pipe which flows through the first throttle D5 and then connects condenser B5 after that the second generator A5 has refrigerant vapor channel connected the first generator 1.

The refrigerant vapor produced by the second generator A5 is used as the thermal driving medium of the first generator 1. That the first generator 1 has refrigerant vapor channel connected external can be considered as the first generator 1 has refrigerant vapor channel connected condenser B5. That the steam bleeding chamber 6 has refrigerant vapor channel connected external can be considered as that the steam bleeding chamber 6 has refrigerant vapor channel connected condenser B5. That the first absorber 2 has refrigerant vapor channel connected external can be considered as that the second evaporator F5 has refrigerant vapor channel connected the first absorber 2. That the second absorber 3 has refrigerant vapor channel connected external can be considered as that the first evaporator C5 has refrigerant vapor channel connected the second absorber 3. Condenser B5 has the liquid refrigerant pipe which flows through liquid refrigerant pump E5 and then connects the first evaporator C5. The first evaporator C5 has the liquid refrigerant pipe which passes through the second throttle G5 and then connects the second evaporator F5. Condenser B5 has the cooling medium pipe connected external. The second generator A5 and the first evaporator C5 has residual medium pipe connected external too.

Secondly, on the process, the residual heat medium heat up the solution which flows through the first solution pump 7 and enters the second generator A5 from the first generator 1. And the solution releases refrigerant vapor which is provided to the first generator 1 and is used as thermal driving medium.

The concentrated solution of the second generator A5 flows through the third solution pump 9, the first solution heat exchanger 4 and then enters the first absorber 2. The refrigerant vapor which is used as thermal driving medium releases heat and become liquid refrigerant. And the liquid refrigerant flows through throttle D5 and then enters condenser B5. The refrigerant vapor produced by the first generator 1 enters condenser B5. The refrigerant vapor produced by the steam bleeding chamber 6 enters liquid refrigerant. The refrigerant vapor entered the condenser B5 releases heat to the cooling medium and becomes liquid refrigerant. The liquid refrigerant of condenser B5 flows through liquid refrigerant pump E5 and its pressure is promoted. Then it enters evaporator C5. The liquid refrigerant which enters the first evaporator C5 is divided into two parts. A part of the liquid refrigerant absorbs residual medium becoming refrigerant vapor which is provided to the second absorber 3. The other part flows through the second throttle G5 and then enters the second evaporator F5 in which it absorbs residual heat medium becoming refrigerant vapor which is provided to the first absorber 2. The heat release of the first absorber 2 is used to satisfy the heating demand before the solution vaporization. The heat release of the second absorber 3 is used to meet the (high temperature) heat demand of heated medium. Finally, we get recuperative single stage tandem double-effect second-type absorption heat pump.

The recuperative single stage tandem double-effect second-type absorption heat pump adopting the solution tandem cycle recuperative generation-absorption system shown in FIG. 21 can be realized by the following way:

Firstly, structurally, in the solution tandem cycle generation-absorption system shown in FIG. 1, we add the second generator A5, condenser B5, evaporator C5, throttle D5, liquid refrigerant pump E5, the third solution heat exchanger H5.

Taking the second generator A5 as low pressure generator, we adjust that the concentrated solution pipe of generator 1 passes through the first solution pump 7, the first solution heat exchanger 4, the first absorber 2 and then connects the steam bleeding chamber 6 to that the concentrated solution pipe of the first generator 1 passes through the third solution heat exchanger H5, the first solution heat exchanger 4, the first absorber 2 and then connects the second generator A5, then the second generator A5 has the concentrated solution pipe which passes through the first solution pump 7, the third solution heat exchanger H5 and then connects the steam bleeding chamber 6. We adjust that the first generator 1 has the refrigerant vapor connected external to that the second generator A5 has liquid refrigerant pipe which passes through throttle D5 and then connects condenser B5 after that the first generator 1 has refrigerant vapor channel connected the second generator A5.

The refrigerant vapor produced by the first generator 1 is used as the thermal driving medium of the second generator A5. The second generator A5 has refrigerant vapor channel connected condenser B5. That the steam bleeding chamber 6 has refrigerant vapor channel connected external can be considered as that the steam bleeding chamber 6 has refrigerant vapor channel connected condenser B5. That the first absorber 2 has refrigerant vapor channel connected external can be considered as that evaporator C5 has refrigerant vapor channel connected the first absorber 2. That the second absorber 3 has refrigerant vapor channel connected external can be considered as that evaporator C5 has refrigerant vapor channel connected the second absorber 3. Condenser B5 has the liquid refrigerant pipe which flows through liquid refrigerant pump E5 and then connects evaporator C5. Condenser B5 has the cooling medium pipe connected external. The second generator A5 and evaporator C5 has residual medium pipe connected external too.

Secondly, on the process, the residual heat medium heats up the solution which enters the first generator 1. And the solution releases refrigerant vapor which is provided to the second generator A5. The concentrated solution of the first generator 1 flows through the third solution heat exchanger H5 and then enters the second generator A5. The solution which enters the second generator A5 absorbs heat and releases refrigerant vapor which is provided to condenser B5. The concentrated solution of the second generator A5 flows through the first solution pump 7, the third solution heat exchanger H5, the first solution heat exchanger 4, the first absorber 2 and then enters the steam bleeding chamber 6.

The refrigerant vapor which is used as the thermal driving medium of the second generator A5 releases heat becoming liquid refrigerant which flows through throttle D5 and then enters condenser B5. The refrigerant vapor produced by the steam bleeding chamber enters condenser B5. The refrigerant vapor which enters condenser B5 releases heat to the cooling medium becoming liquid refrigerant. The liquid refrigerant of condenser B5 flows through liquid refrigerant pump E5 and its pressure is promoted. Then the liquid refrigerant enters evaporator C5. The liquid refrigerant which enters evaporator C5 absorbs residual heat medium becoming refrigerant vapor which is separately provided to the first absorber 2 and the second absorber 3. The heat release of the first absorber 2 is used to meet the heat demand of heated medium and satisfy the heating demand before the solution vaporization. The heat release of the second absorber 3 is used to meet the (high temperature) heat demand of heated medium. Finally, we get recuperative single stage tandem double-effect second-type absorption heat pump.

The recuperative single stage tandem double-effect second-type absorption heat pump adopting the solution tandem cycle recuperative generation-absorption system shown in FIG. 22 can be realized by the following way:

Firstly, Structurally, in the solution tandem cycle generation-absorption system shown in FIG. 2, we add the second generator A5, condenser B5, the first evaporator C5, the first throttle D5, liquid refrigerant pump E5, the second evaporator F5, the second throttle G5, the third solution heat exchanger H5.

Taking the second generator A5 as low pressure generator, we adjust that the concentrated solution pipe of generator 1 passes through the first solution pump 7, the first solution heat exchanger 4, the first absorber 2 and then connects the steam bleeding chamber 6 to that the concentrated solution pipe of the first generator 1 passes through the third solution heat exchanger H5, the first solution heat exchanger 4, the first absorber 2 and then connects the second generator A5, then the second generator A5 has the concentrated solution pipe which passes through the first solution pump 7, the third solution heat exchanger H5 and then connects the steam bleeding chamber 6. We adjust that the first generator 1 has the refrigerant vapor connected external to that the second generator A5 has liquid refrigerant pipe which passes through throttle D5 and then connects condenser B5 after that the first generator 1 has refrigerant vapor channel connected the second generator A5.

The refrigerant vapor produced by the first generator 1 is used as the thermal driving medium of the second generator A5. The second generator A5 has refrigerant vapor channel connected condenser B5. That the steam bleeding chamber 6 has refrigerant vapor channel connected external can be considered as that the steam bleeding chamber 6 has refrigerant vapor channel connected condenser B5. That the first absorber 2 has refrigerant vapor channel connected external can be considered as that the first evaporator C5 has refrigerant vapor channel connected the first absorber 2. That the second absorber 3 has refrigerant vapor channel connected external can be considered as that the first evaporator C5 has refrigerant vapor channel connected the second absorber 3. Condenser B5 has the liquid refrigerant pipe which flows through liquid refrigerant pump E5 and then connects the first evaporator C5. The first evaporator C5 has the liquid refrigerant pipe which passes through the second throttle G5 and then connects the second evaporator F5. Condenser B5 has the cooling medium pipe connected external. The second generator A5 and the first evaporator C5 has residual medium pipe connected external too.

Secondly, on the process, the residual heat medium heat up the solution which enters the first generator 1. And the solution releases refrigerant vapor which is provided to the second generator A5. The concentrated solution of the first generator 1 flows through the third solution heat exchanger H5 and then enters the second generator A5. The solution which enters the second generator A5 absorbs heat and releases refrigerant vapor which is provided to condenser B5. The concentrated solution of the second generator A5 flows through the first solution pump 7, the third solution heat exchanger H5, the first solution heat exchanger 4, the first absorber 2 and then enters the steam bleeding chamber 6.

The refrigerant vapor which is used as the thermal driving medium of the second generator A5 releases heat becoming liquid refrigerant which flows through the first throttle D5 and then enters condenser B5. The refrigerant vapor produced by the steam bleeding chamber enters condenser B5. The refrigerant vapor which enters condenser B5 releases heat to the cooling medium becoming liquid refrigerant. The liquid refrigerant of condenser B5 flows through liquid refrigerant pump E5 and its pressure is promoted. Then the liquid refrigerant enters the first evaporator C5. The liquid refrigerant which enters the first evaporator C5 is divided into two parts. A part of the liquid refrigerant absorbs residual medium becoming refrigerant vapor which is provided to the second absorber 3. The other part flows through the second throttle G5 and then enters the second evaporator F5 in which it absorbs residual heat medium becoming refrigerant vapor which is provided to the first absorber 2. The heat release of the first absorber 2 is used to satisfy the heating demand before the solution vaporization. The heat release of the second absorber 3 is used to meet the (high temperature) heat demand of heated medium. Finally, we get recuperative single stage tandem double-effect second-type absorption heat pump.

The recuperative single stage tandem double-effect second-type absorption heat pump adopting the solution independent cycle recuperative generation-absorption system shown in FIG. 23 can be realized by the following way:

Firstly, Structurally, in the solution independent cycle generation-absorption system shown in FIG. 3, we add the second generator A5, condenser B5, the first evaporator C5, the first throttle D5, liquid refrigerant pump E5, the second evaporator F5, the second throttle G5, the third solution heat exchanger H5.

Taking the second generator A5 as low pressure generator, we adjust that the concentrated solution pipe of generator 1 passes through the first solution pump 7, the first solution heat exchanger 4 and then connects the first absorber 2 to that t the concentrated solution pipe of generator 1 passes through the third solution heat exchanger H5 and then connects the second generator A5, then the second generator A5 has the concentrated solution pipe which passes through the third solution heat exchanger H5, the first solution heat exchanger 4 and then connects the first absorber 2. We adjust that the first generator 1 has the refrigerant vapor connected external to that the second generator A5 has liquid refrigerant pipe which passes through throttle D5 and then connects condenser B5 after that the first generator 1 has refrigerant vapor channel connected the second generator A5.

The refrigerant vapor produced by the first generator 1 is used as the thermal driving medium of the second generator A5. The second generator A5 has refrigerant vapor channel connected condenser B5. That the steam bleeding chamber 6 has refrigerant vapor channel connected external can be considered as that the steam bleeding chamber 6 has refrigerant vapor channel connected condenser B5. That the first absorber 2 has refrigerant vapor channel connected external can be considered as that the first evaporator C5 has refrigerant vapor channel connected the first absorber 2. That the second absorber 3 has refrigerant vapor channel connected external can be considered as that the first evaporator C5 has refrigerant vapor channel connected the second absorber 3. Condenser B5 has the liquid refrigerant pipe which flows through liquid refrigerant pump E5 and then connects the first evaporator C5. The first evaporator C5 has the liquid refrigerant pipe which passes through the second throttle G5 and then connects the second evaporator F5. Condenser B5 has the cooling medium pipe connected external. The second generator A5 and the first evaporator C5 has residual medium pipe connected external too.

Secondly, on the process, the residual heat medium heats up the solution which enters the first generator 1. And the solution releases refrigerant vapor which is provided to the second generator A5. The concentrated solution of the first generator 1 flows through the third solution heat exchanger H5 and then enters the second generator A5. The solution which enters the second generator A5 absorbs heat and releases refrigerant vapor which is provided to condenser B5. The concentrated solution of the second generator A5 flows through the first solution pump 7, the third solution heat exchanger H5, the first solution heat exchanger 4, the first absorber 2 and then enters the steam bleeding chamber 6.

The refrigerant vapor which is used as the thermal driving medium of the second generator A5 releases heat becoming liquid refrigerant which flows through the first throttle D5 and then enters condenser B5. The refrigerant vapor produced by the steam bleeding chamber enters condenser B5. The refrigerant vapor which enters condenser B5 releases heat to the cooling medium becoming liquid refrigerant. The liquid refrigerant of condenser B5 flows through liquid refrigerant pump E5 and its pressure is promoted. Then the liquid refrigerant enters the first evaporator C5. The liquid refrigerant which enters the first evaporator C5 is divided into two parts. A part of the liquid refrigerant absorbs residual medium becoming refrigerant vapor which is provided to the second absorber 3. The other part flows through the second throttle G5 and then enters the second evaporator F5 in which it absorbs residual heat medium becoming refrigerant vapor which is provided to the first absorber 2. The heat release of the first absorber 2 is used to meet the heat demand of heated medium and satisfy the heating demand before the solution vaporization. The heat release of the second absorber 3 is used to meet the (high temperature) heat demand of heated medium. Finally, we get recuperative single stage tandem double-effect second-type absorption heat pump.

Compared with FIG. 24 and FIG. 23, the differences between the two is that there are no the second evaporator F5 and the second throttle G5 in FIG. 24. What's more, evaporator 5 has the liquid refrigerant channel which separately connects the first absorber 2 and the second absorber 3.

The recuperative single stage parallel double-effect second-type absorption heat pump adopting the solution tandem cycle recuperative generation-absorption system shown in FIG. 25 can be realized by the following way:

Firstly, structurally, in the solution tandem cycle generation-absorption system shown in FIG. 1, we add the second generator A5, condenser B5, evaporator C5, throttle D5, liquid refrigerant pump E5, the third solution heat exchanger H5.

Taking the second generator A5 as high pressure generator, the concentrated solution pipe of the second generator A5 passes through the third solution heat exchanger H5. After that, the pipe joins with the concentrated solution pipe which passes through the first solution pump 7, the first solution heat exchanger 4 from the first generator 1. The first absorber 2 has the dilute solution pipe which passes through the third solution heat exchanger H5 and then connects the second generator A5. We adjust that the first generator 1 has the refrigerant vapor connected external to that the first generator 1 has liquid refrigerant pipe which passes through throttle D5 and then connects condenser B5 after that the second generator A5 has refrigerant vapor channel connected the first generator 1.

The refrigerant vapor produced by the second generator A5 is used as the thermal driving medium of the first generator 1. That the first generator 1 has refrigerant vapor channel connected external can be considered that the first generator 1 has refrigerant vapor channel connected condenser B5. That the steam bleeding chamber 6 has refrigerant vapor channel connected external can be considered as that the steam bleeding chamber 6 has refrigerant vapor channel connected condenser B5. That the first absorber 2 has refrigerant vapor channel connected external can be considered as that evaporator C5 has refrigerant vapor channel connected the first absorber 2. That the second absorber 3 has refrigerant vapor channel connected external can be considered as that evaporator C5 has refrigerant vapor channel connected the second absorber 3. Condenser B5 has the liquid refrigerant pipe which flows through liquid refrigerant pump E5 and then connects evaporator C5. Condenser B5 has the cooling medium pipe connected external. The second generator A5, the first evaporator C5 and the second evaporator F5 has residual medium pipe connected external too.

Secondly, on the process, the residual heat medium heats up the solution which flows through the third solution heat exchanger 5 and then enters the second generator A5 from the first absorber 2. And the solution releases refrigerant vapor which is provided to the first generator 1. The refrigerant vapor is used as thermal driving medium. The concentrated solution of the second generator A5 flows through the third solution heat exchanger H5 and then it joins with the concentrated solution which flows through the first solution pump 7, the first solution heat exchanger 4 from the first generator 1. Then the solution flows through the first absorber 2 and then enters the steam bleeding chamber 6. The first generator 1 releases refrigerant vapor which enters condenser B5.

The refrigerant vapor which is used as the thermal driving medium of the first generator 1 releases heat becoming liquid refrigerant which flows through throttle D5 and then enters condenser B5. The refrigerant vapor produced by the steam bleeding chamber 6 enters condenser B5. The refrigerant vapor which enters condenser B5 releases heat to the cooling medium becoming liquid refrigerant. The liquid refrigerant of condenser B5 flows through liquid refrigerant pump E5 and its pressure is promoted. Then the liquid refrigerant enters evaporator C5. The liquid refrigerant which enters evaporator C5 absorbs residual heat medium becoming refrigerant vapor which is separately provided to the first absorber 2 and the second absorber 3. The heat release of the first absorber 2 is used to meet the heat demand of heated medium and satisfy the heating demand before the solution vaporization. The heat release of the second absorber 3 is used to meet the (high temperature) heat demand of heated medium. Finally, we get recuperative single stage parallel double-effect second-type absorption heat pump.

The recuperative single stage parallel double-effect second-type absorption heat pump adopting the solution independent cycle recuperative generation-absorption system shown in FIG. 26 can be realized by the following way:

Firstly, Structurally, in the solution independent cycle generation-absorption system shown in FIG. 3, we add the third solution pump 9, the second generator A5, condenser B5, the first evaporator C5, the first throttle D5, liquid refrigerant pump E5, the second evaporator F5, the second throttle G5, the third solution heat exchanger H5.

Taking the second generator A5 as low pressure generator, the second generator A5 has the concentrated solution pipe which passes through the third solution pump 9, the third solution heat exchanger H5 and then connects the first absorber 2. The first absorber 2 the dilute solution pipe which passes through the third solution heat exchanger H5 and then connects the second generator A5. That the first generator 1 has the refrigerant vapor channel connected external can be considered as that the second generator A5 has the liquid refrigerant pipe which passes through the first throttle D5 and then connects condenser B5 after that the first generator 1 has the refrigerant vapor channel connected the second generator A5.

The refrigerant vapor produced by the first generator 1 is used as the thermal driving medium of the second generator A5. The second generator A5 has refrigerant vapor channel connected condenser B5. That the steam bleeding chamber 6 has refrigerant vapor channel connected external can be considered as that the steam bleeding chamber 6 has refrigerant vapor channel connected condenser B5. That the first absorber 2 has refrigerant vapor channel connected external can be considered as that the second evaporator F5 has refrigerant vapor channel connected the first absorber 2. That the second absorber 3 has refrigerant vapor channel connected external can be considered as that the first evaporator C5 has refrigerant vapor channel connected the second absorber 3. Condenser B5 has the liquid refrigerant pipe which flows through liquid refrigerant pump E5 and then connects the first evaporator C5. The first evaporator C5 has the liquid refrigerant pipe which flows through the second throttle G5 and then connects the second evaporator F5. Condenser B5 has the cooling medium pipe connected external. The first evaporator C5 and the second evaporator F5 has residual medium pipe connected external too.

Secondly, on the process, the residual heat medium heats up the solution which enters the first generator 1. And the solution releases refrigerant vapor which is provided to the second generator A5. The refrigerant vapor is used as thermal driving medium. The solution, which flows through the third solution heat exchanger H5 and then enters the second generator A5 from the first absorber 2, absorbs heat becoming refrigerant vapor which is provided to condenser B5. The concentrated solution of the second generator A5 flows through the third solution pump 9, the third solution heat exchanger H5 and then enters the first absorber 2. The refrigerant vapor, which is used as the thermal driving medium of the second generator A5, releases heat and becomes liquid refrigerant. And the solution flows through the first throttle D5 and then enters condenser B5. The refrigerant vapor produced by the steam bleeding chamber 6 enters condenser B5.

The refrigerant vapor which enters condenser B5 releases heat to the cooling medium becoming liquid refrigerant. The liquid refrigerant of condenser B5 flows through the liquid refrigerant pump E5 and its pressure is promoted by it. Then it enters the first evaporator C5. The liquid refrigerant is divided into two parts. One part of it absorbs residual heat becoming refrigerant vapor which is provided to the second absorber 3. And the other part flows through the second throttle G5 and then enters the second evaporator F5 in which it absorbs residual heat becoming refrigerant vapor which is provided to the first absorber 2. The heat release of the first absorber 2 is used to meet the heat demand of heated medium and satisfy the heating demand before the solution vaporization. The heat release of the second absorber 3 is used to meet the (high temperature) heat demand of heated medium. Finally, we get recuperative single stage parallel double-effect second-type absorption heat pump.

The recuperative single stage parallel double-effect second-type absorption heat pump adopting the solution tandem cycle recuperative generation-absorption system shown in FIG. 27 can be realized by the following way:

Firstly, Structurally, in the solution tandem cycle generation-absorption system shown in FIG. 1, we add the second generator A5, condenser B5, evaporator C5, throttle D5, liquid refrigerant pump E5, the third solution heat exchanger H5, the fourth solution pump I5.

Taking the second generator A5 as low pressure generator, the second generator A5 has the concentrated solution pipe which passes through the fourth solution pump I5, the third solution heat exchanger H5 and then connects the first absorber 2. The first absorber 2 the dilute solution pipe which passes through the third solution heat exchanger H5 and then connects the second generator A5. That the first generator 1 has the refrigerant vapor channel connected external can be considered as that the second generator A5 has the liquid refrigerant pipe which passes through the first throttle D5 and then connects condenser B5 after that the first generator 1 has the refrigerant vapor channel connected the second generator A5.

The refrigerant vapor produced by the first generator 1 is used as the thermal driving medium of the second generator A5. The second generator A5 has refrigerant vapor channel connected condenser B5. That the steam bleeding chamber 6 has refrigerant vapor channel connected external can be considered as that the steam bleeding chamber 6 has refrigerant vapor channel connected condenser B5. That the first absorber 2 has refrigerant vapor channel connected external can be considered as that evaporator C5 has refrigerant vapor channel connected the first absorber 2. That the second absorber 3 has refrigerant vapor channel connected external can be considered as that evaporator C5 has refrigerant vapor channel connected the second absorber 3. Condenser B5 has the liquid refrigerant pipe which flows through liquid refrigerant pump E5 and then connects evaporator C5. Condenser B5 has the cooling medium pipe connected external. Evaporator C5 has residual medium pipe connected external too.

Secondly, on the process, the residual heat medium heats up the solution which enters the first generator 1. And the solution releases refrigerant vapor which is provided to the second generator A5. The refrigerant vapor is used as thermal driving medium. The solution, which flows through the third solution heat exchanger H5 and then enters the second generator A5 from the first absorber 2, absorbs heat becoming refrigerant vapor which is provided to condenser B5. The concentrated solution of the second generator A5 flows through the fourth solution pump I5, the third solution heat exchanger H5 and then enters the first absorber 2. The refrigerant vapor, which is used as the thermal driving medium of the second generator A5, releases heat and becomes liquid refrigerant. And the solution flows through the first throttle D5 and then enters condenser B5. The refrigerant vapor produced by the steam bleeding chamber 6 enters condenser B5.

The refrigerant vapor which enters condenser B5 releases heat to the cooling medium becoming liquid refrigerant. The liquid refrigerant of condenser B5 flows through the liquid refrigerant pump E5 and its pressure is promoted by it. Then it enters the first evaporator C5. The liquid refrigerant absorbs residual heat becoming refrigerant vapor which is separately provided to the first absorber 2 and the second absorber 3. The heat release of the first absorber 2 is used to meet the heat demand of heated medium and satisfy the heating demand before the solution vaporization. The heat release of the second absorber 3 is used to meet the (high temperature) heat demand of heated medium. Finally, we get recuperative single stage parallel double-effect second-type absorption heat pump.

The recuperative single stage parallel double-effect second-type absorption heat pump adopting the solution tandem cycle recuperative generation-absorption system shown in FIG. 28 can be realized by the following way:

Firstly, Structurally, in the solution tandem cycle generation-absorption system shown in FIG. 1, we add the second generator A5, condenser B5, the first evaporator C5, the first throttle D5, liquid refrigerant pump E5, the second evaporator F5, the second throttle G5, the third solution heat exchanger H5, the fourth solution pump I5.

Taking the second generator A5 as high pressure generator, the second generator A5 has the concentrated solution pipe which passes through the fourth solution pump I5, the third solution heat exchanger H5 and then connects the first absorber 2. The first absorber 2 the dilute solution pipe which passes through the third solution heat exchanger H5 and then connects the second generator A5. That the first generator 1 has the refrigerant vapor channel connected external can be considered as that the first generator 1 has the liquid refrigerant pipe which passes through the first throttle D5 and then connects condenser B5 after that the second generator A5 has the refrigerant vapor channel connected the first generator 1.

The refrigerant vapor produced by the second generator A5 is used as the thermal driving medium of the first generator 1. That the first generator 1 has refrigerant vapor channel connected condenser B5 can be considered as that the first generator 1 has the liquid refrigerant pipe connected condenser B5. That the steam bleeding chamber 6 has refrigerant vapor channel connected external can be considered as that the steam bleeding chamber 6 has refrigerant vapor channel connected condenser B5. That the first absorber 2 has refrigerant vapor channel connected external can be considered as that the second evaporator F5 has refrigerant vapor channel connected the first absorber 2. That the second absorber 3 has refrigerant vapor channel connected external can be considered as that the first evaporator C5 has refrigerant vapor channel connected the second absorber 3. Condenser B5 has the liquid refrigerant pipe which flows through liquid refrigerant pump E5 and then connects the first evaporator C5. Condenser B5 has the cooling medium pipe connected external. The second generator A5, the first evaporator C5 and the second evaporator F5 has residual medium pipe connected external too.

Secondly, on the process, the residual heat medium heats up the solution which enters the first absorber 2. And the solution releases refrigerant vapor which is provided to the first generator 1. The refrigerant vapor is used as thermal driving medium. The concentrated solution of the second generator A5 flows through the fourth solution pump I5, the third solution heat exchanger H5 and then enters the first absorber 2. The refrigerant vapor, which is used as thermal driving medium of the second generator A5, releases heat becoming liquid refrigerant which flows through the first throttle D5 and to then enters condenser B5. The refrigerant vapor produced by the first generator 1 enters condenser B5. The refrigerant vapor produced by the steam bleeding chamber 6 enters condenser B5.

The refrigerant vapor which enters condenser B5 releases heat to the cooling medium becoming liquid refrigerant. The liquid refrigerant of condenser B5 flows through the liquid refrigerant pump E5 and its pressure is promoted by it. Then it enters the first evaporator C5. The liquid refrigerant is divided into two parts. One part of it absorbs residual heat becoming refrigerant vapor which is provided to the second absorber 3. And the other part flows through the second throttle G5 and then enters the second evaporator F5 in which it absorbs residual heat becoming refrigerant vapor which is provided to the first absorber 2. The heat release of the first absorber 2 is used to meet the heat demand of heated medium and satisfy the heating demand before the solution vaporization. The heat release of the second absorber 3 is used to meet the (high temperature) heat demand of heated medium. Finally, we get recuperative single stage parallel double-effect second-type absorption heat pump.

The recuperative single stage tandem triple effect second-type absorption heat pump adopting the solution tandem cycle recuperative generation-absorption system shown in FIG. 29 can be realized by the following way:

Firstly, Structurally, in the solution tandem cycle generation-absorption system shown in FIG. 1, we add the second generator A6, the third generator B6, condenser C6, evaporator D6, the fourth solution pump E6, the first throttle F6, the second throttle G6, liquid refrigerant pump H6.

We adjust that the concentrated solution pipe of generator 1 passes through the first solution pump 7, the first solution heat exchanger 4, the first absorber 2 and then connects the steam bleeding chamber 6 to that the concentrated solution pipe of the first generator 1 passes through the first solution pump 7 and then connects the third generator B6. The third generator B6 has the concentrated solution pipe which passes through the fourth solution pump E6 and then connects the second generator A6. The second generator A6 has the concentrated solution pipe which passes through the first solution heat exchanger 4, the first absorber 2 and then connects the steam bleeding chamber 6. We adjust that the first generator 1 has the refrigerant vapor connected external to that the first generator 1 has liquid refrigerant pipe which passes through the second throttle G6 and then connects condenser C6 after that the third generator B6 has refrigerant vapor channel connected the first generator 1.

The refrigerant vapor produced by the third generator B6 is used as the thermal driving medium of the first generator 1. After that the second generator A6 has refrigerant vapor channel connected the third generator B6, the third generator B6 has liquid refrigerant pipe which flows through the first throttle F6 and then connects condenser C6. The refrigerant vapor produced by the second generator A6 is used as the thermal driving medium of the third generator B6. That the first generator 1 has refrigerant vapor channel connected external can be considered as that the first generator 1 has the liquid refrigerant pipe connected condenser C6.

That the first absorber 2 has refrigerant vapor channel connected external can be considered as that evaporator D6 has refrigerant vapor channel connected the first absorber 2. That the second absorber 3 has refrigerant vapor channel connected external can be considered as that the evaporator D6 has refrigerant vapor channel connected the second absorber 3. Condenser C6 has the liquid refrigerant pipe which flows through liquid refrigerant pump H6 and then connects evaporator D6. Condenser C6 has the cooling medium pipe connected external. The second generator A6 and evaporator D6 has residual medium pipe connected external too.

Secondly, on the process, the refrigerant vapor, released by the third generator B6, is used as thermal driving medium of the first generator 1. After that the refrigerant vapor releases heat becoming liquid refrigerant, then the solution flows through the second throttle G6 and then enters condenser C6. The concentrated solution of the first generator 1 flows through the first solution pump 7 and then enters the third generator B6. The refrigerant vapor, produced by the second generator A6, used as thermal driving medium of the third generator B6, releases heat becoming liquid refrigerant, then the solution flows through the first throttle F6 and then enters condenser C6. The concentrated solution of the third generator B6 flows through the fourth solution pump E6 and then enters the second generator A6. The residual heat medium heats up the solution which enters the second generator A6. The solution releases refrigerant vapor. The concentrated solution of the second generator A6 flows through the first solution heat exchanger 4, the first absorber 2 and then enters the steam bleeding chamber 6.

The refrigerant vapor produced by the first generator enters condenser C6. The steam bleeding chamber 6 releases refrigerant vapor which enters condenser C6 and releases heat to the cooling medium becoming liquid refrigerant. The liquid refrigerant of condenser C6 flows through liquid refrigerant pump H6 and its pressure is promoted by it. Then the liquid refrigerant enters evaporator D6 where it absorbs residual heat becoming refrigerant vapor which is separately provided to the first absorber 2 and the second absorber 3. The heat release of the first absorber 2 is used to meet the heat demand of heated medium and satisfy the heating demand before the solution vaporization. The heat release of the second absorber 3 is used to meet the (high temperature) heat demand of heated medium. Finally, we get recuperative single stage tandem triple effect second-type absorption heat pump.

The recuperative single stage tandem triple effect second-type absorption heat pump adopting the solution tandem cycle recuperative generation-absorption system shown in FIG. 30 can be realized by the following way:

Firstly, structurally, in the solution tandem cycle generation-absorption system shown in FIG. 1, we add the second generator A6, the third generator B6, condenser C6, the first evaporator D6, the fourth solution pump E6, the first throttle F6, the second throttle G6, liquid refrigerant pump H6, the second evaporator I6, the third throttle J6.

We adjust that the concentrated solution pipe of generator 1 passes through the first solution pump 7, the first solution heat exchanger 4, the first absorber 2 and then connects the steam bleeding chamber 6 to that the concentrated solution pipe of the first generator 1 passes through the first solution pump 7 and then connects the third generator B6. The third generator B6 has the concentrated solution pipe which passes through the fourth solution pump E6 and then connects the second generator A6. The second generator A6 has the concentrated solution pipe which passes through the first solution heat exchanger 4, the first absorber 2 and then connects the steam bleeding chamber 6. We adjust that the first generator 1 has the refrigerant vapor connected external to that the first generator 1 has liquid refrigerant pipe which passes through the second throttle G6 and then connects condenser C6 after that the third generator B6 has refrigerant vapor channel connected the first generator 1.

The refrigerant vapor produced by the third generator B6 is used as the thermal driving medium of the first generator 1. After that the second generator A6 has refrigerant vapor channel connected the third generator B6, the third generator B6 has liquid refrigerant pipe which flows through the first throttle F6 and then connects condenser C6. The refrigerant vapor produced by the second generator A6 is used as the thermal driving medium of the third generator B6. That the first generator 1 has refrigerant vapor channel connected external can be considered as that the first generator 1 has the liquid refrigerant pipe connected condenser C6.

That the first absorber 2 has refrigerant vapor channel connected external can be considered as that the second evaporator I6 has refrigerant vapor channel connected the first absorber 2. That the second absorber 3 has refrigerant vapor channel connected external can be considered as that the first evaporator D6 has refrigerant vapor channel connected the second absorber 3. Condenser C6 has the liquid refrigerant pipe which flows through liquid refrigerant pump H6 and then connects the first evaporator D6. The first evaporator D6 has liquid refrigerant pipe which flows through the third throttle J6 and then connects the second evaporator I6. Condenser C6 has the cooling medium pipe connected external. The second generator A6, the first evaporator D6 and the second evaporator I6 has residual medium pipe connected external too.

Secondly, on the process, the refrigerant vapor, released by the third generator B6, is used as thermal driving medium of the first generator 1. After that the refrigerant vapor releases heat becoming liquid refrigerant, then the solution flows through the second throttle G6 and then enters condenser C6. The concentrated solution of the first generator 1 flows through the first solution pump 7 and then enters the third generator B6. The refrigerant vapor, produced by the second generator A6, used as thermal driving medium of the third generator B6, releases heat becoming liquid refrigerant, then the solution flows through the first throttle F6 and then enters condenser C6. The concentrated solution of the third generator B6 flows through the fourth solution pump E6 and then enters the second generator A6. The residual heat medium heats up the solution which enters the second generator A6. The solution releases refrigerant vapor. The concentrated solution of the second generator A6 flows through the first solution heat exchanger 4, the first absorber 2 and then enters the steam bleeding chamber 6.

The refrigerant vapor produced by the first generator 1 enters condenser C6. The steam bleeding chamber 6 releases refrigerant vapor which enters condenser C6 and releases heat to the cooling medium becoming liquid refrigerant. The liquid refrigerant of condenser C6 flows through liquid refrigerant pump H6 and its pressure is promoted by it. Then the liquid refrigerant enters evaporator D6. It is divided into two parts. One part of it absorbs residual heat becoming refrigerant vapor which is provided to the second absorber 3. The other part flows through the third throttle J6 and then enters the second evaporator I6 where it absorbs heat absorbs residual heat becoming refrigerant vapor provided to the first absorber 2. The heat release of the first absorber 2 is used to meet the heat demand of heated medium and satisfy the heating demand before the solution vaporization. The heat release of the second absorber 3 is used to meet the (high temperature) heat demand of heated medium. Finally, we get recuperative single stage tandem triple effect second-type absorption heat pump.

The recuperative single stage tandem triple effect second-type absorption heat pump adopting the solution independent cycle recuperative generation-absorption system shown in FIG. 31 can be realized by the following way:

Firstly, structurally, in the solution independent cycle generation-absorption system shown in FIG. 3, we add the third solution pump 9, the second generator A6, the third generator B6, condenser C6, the first evaporator D6, the fourth solution pump E6, the first throttle F6, the second throttle G6, liquid refrigerant pump H6, the second evaporator I6, the third throttle J6.

We adjust that the concentrated solution pipe of generator 1 passes through the first solution pump 7, the first solution heat exchanger 4 and then connects the first absorber 2 to that the concentrated solution pipe of the first generator 1 passes through the first solution pump 7 and then connects the third generator B6. The third generator B6 has the concentrated solution pipe which passes through the fourth solution pump E6 and then connects the second generator A6. The second generator A6 has the concentrated solution pipe which passes through the third solution pump 9, the first solution heat exchanger 4, the first absorber 2 and then connects the steam bleeding chamber 6. We adjust that the first generator 1 has the refrigerant vapor connected external to that the first generator 1 has liquid refrigerant pipe which passes through the second throttle G6 and then connects condenser C6 after that the third generator B6 has refrigerant vapor channel connected the first generator 1.

The refrigerant vapor produced by the third generator B6 is used as the thermal driving medium of the first generator 1. After that the second generator A6 has refrigerant vapor channel connected the third generator B6, the third generator B6 has liquid refrigerant pipe which flows through the first throttle F6 and then connects condenser C6. The refrigerant vapor produced by the second generator A6 is used as the thermal driving medium of the third generator B6. That the first generator 1 has refrigerant vapor channel connected external can be considered as that the first generator 1 has the liquid refrigerant pipe connected condenser C6.

That the first absorber 2 has refrigerant vapor channel connected external can be considered as that the second evaporator I6 has refrigerant vapor channel connected the first absorber 2. That the second absorber 3 has refrigerant vapor channel connected external can be considered as that the first evaporator D6 has refrigerant vapor channel connected the second absorber 3. That the steam bleeding chamber 6 has refrigerant vapor channel connected external can be considered as that the steam bleeding chamber 6 has refrigerant vapor channel connected condenser C6. Condenser C6 has the liquid refrigerant pipe which flows through liquid refrigerant pump H6 and then connects the first evaporator D6. The first evaporator D6 has liquid refrigerant pipe which flows through the third throttle J6 and then connects the second evaporator I6. Condenser C6 has the cooling medium pipe connected external. The second generator A6, the first evaporator D6 and the second evaporator I6 have residual medium pipe connected external too.

Secondly, on the process, the refrigerant vapor, released by the third generator B6, is used as thermal driving medium of the first generator 1. After that the refrigerant vapor releases heat becoming liquid refrigerant, then the solution flows through the second throttle G6 and then enters condenser C6. The concentrated solution of the first generator 1 flows through the first solution pump 7 and then enters the third generator B6. The refrigerant vapor, produced by the second generator A6, used as thermal driving medium of the third generator B6, releases heat becoming liquid refrigerant, then the solution flows through the first throttle F6 and then enters condenser C6. The concentrated solution of the third generator B6 flows through the fourth solution pump E6 and then enters the second generator A6. The residual heat medium heats up the solution which enters the second generator A6. The solution releases refrigerant vapor. The concentrated solution of the second generator A6 flows through the third solution pump 9, the first solution heat exchanger 4 and then enters the first absorber 2.

The refrigerant vapor produced by the first generator 1 enters condenser C6. The steam bleeding chamber 6 releases refrigerant vapor which enters condenser C6 and releases heat to the cooling medium becoming liquid refrigerant. The liquid refrigerant of condenser C6 flows through liquid refrigerant pump H6 and its pressure is promoted by it. Then the liquid refrigerant enters evaporator D6. It is divided into two parts. One part of it absorbs residual heat becoming refrigerant vapor which is provided to the second absorber 3. The other part flows through the third throttle J6 and then enters the second evaporator I6 where it absorbs heat absorbs residual heat becoming refrigerant vapor provided to the first absorber 2. The heat release of the first absorber 2 is used to meet the heat demand of heated medium and satisfy the heating demand before the solution vaporization. The heat release of the second absorber 3 is used to meet the (high temperature) heat demand of heated medium. Finally, we get recuperative single stage tandem triple effect second-type absorption heat pump.

The recuperative single stage tandem triple effect second-type absorption heat pump adopting the solution independent cycle recuperative generation-absorption system shown in FIG. 32 can be realized by the following way:

Firstly, structurally, in the solution independent cycle generation-absorption system shown in FIG. 3, we add the second generator A6, the third generator B6, condenser C6, evaporator D6, the first throttle F6, the second throttle G6, liquid refrigerant pump H6, the third solution heat exchanger K6, the fourth solution heat exchanger L6.

We adjust that the concentrated solution pipe of generator 1 passes through the first solution pump 7, the first solution heat exchanger 4 and then connects the first absorber 2 to that the concentrated solution pipe of the first generator 1 passes through the third solution heat exchanger K6 and then connects the second generator A6. The second generator A6 has the concentrated solution pipe which passes through the fourth solution heat exchanger L6 and then connects the third generator B6. The third generator B6 has the concentrated solution pipe which passes through the first solution pump 7, the fourth solution heat exchanger L6, the third solution heat exchanger K6, the first solution heat exchanger 4 and then connects the first absorber 2. We adjust that the first generator 1 has the refrigerant vapor connected external to that the second generator A6 as liquid refrigerant pipe which passes through the first throttle F6 and then connects condenser C6 after that the first generator 1 has refrigerant vapor channel connected the second generator A6.

The refrigerant vapor produced by the first generator 1 is used as the thermal driving medium of the second generator A6. After that the second generator A6 has refrigerant vapor channel connected the third generator B6, the third generator B6 has liquid refrigerant pipe which flows through the second throttle G6 and then connects condenser C6. The refrigerant vapor produced by the second generator A6 is used as the thermal driving medium of the third generator B6. The third generator B6 has refrigerant vapor channel connected condenser C6.

That the first absorber 2 has refrigerant vapor channel connected external can be considered as that evaporator D6 has refrigerant vapor channel connected the first absorber 2. That the second absorber 3 has refrigerant vapor channel connected external can be considered as that evaporator D6 has refrigerant vapor channel connected the second absorber 3. That the steam bleeding chamber 6 has refrigerant vapor channel connected external can be considered as that the steam bleeding chamber 6 has refrigerant vapor channel connected condenser C6. Condenser C6 has the liquid refrigerant pipe which flows through liquid refrigerant pump H6 and then connects evaporator D6. Condenser C6 has the cooling medium pipe connected external. Evaporator D6 has residual medium pipe connected external too.

Secondly, on the process, the residual heat medium heats up the solution which enters the first generator 1. And the solution releases refrigerant vapor which is provided to the second generator A6. The refrigerant vapor is used as thermal driving medium. The concentrated solution of the first generator 1 flows through the third solution heat exchanger K6 and then enters the second generator A6.

The refrigerant vapor produced by the first generator 1 heat up the solution which enters the second generator A6. The solution releases refrigerant vapor which is provided to the third generator B6. The concentrated solution of the second generator A6 flows through the fourth solution heat exchanger L6 and then enters the third generator B6. The refrigerant vapor produced by the second generator A6 heats up the solution which enters the third generator B6. The solution releases refrigerant vapor which is provided to condenser C6. The concentrated solution of the third generator B6 flows through the first solution pump 7, the fourth solution heat exchanger L6, the third solution heat exchanger K6, the first solution heat exchanger 4 and then enters the first absorber 2. The refrigerant vapor, used as thermal driving medium of the second generator A6, releases heat becoming liquid refrigerant, then the solution flows through the first throttle F6 and then enters condenser C6. The refrigerant vapor, used as thermal driving medium of the third generator B6, releases heat becoming liquid refrigerant, then the solution flows through the second throttle G6 and then enters condenser C6.

The refrigerant vapor released by the steam bleeding chamber 6 enters condenser C6 where the refrigerant vapor releases heat to the cooling medium becoming liquid refrigerant. The liquid refrigerant of condenser C6 flows through liquid refrigerant pump H6 and then enters evaporator D6 in which it absorbs residual heat becoming refrigerant vapor. Then the refrigerant vapor is separately provided to the first absorber 2 and the second absorber 3. The heat release of the first absorber 2 is used to meet the heat demand of heated medium and satisfy the heating demand before the solution vaporization. The heat release of the second absorber 3 is used to meet the (high temperature) heat demand of heated medium. Finally, we get recuperative single stage tandem triple effect second-type absorption heat pump.

The recuperative single stage tandem triple effect second-type absorption heat pump adopting the solution independent cycle recuperative generation-absorption system shown in FIG. 33 can be realized by the following way:

Firstly, structurally, in the solution independent cycle generation-absorption system shown in FIG. 3, we add the second generator A6, the third generator B6, condenser C6, the first evaporator D6, the first throttle F6, the second throttle G6, liquid refrigerant pump H6, the second evaporator I6, the third throttle J6, the third solution heat exchanger K6, the fourth solution heat exchanger L6.

We adjust that the concentrated solution pipe of generator 1 passes through the first solution pump 7, the first solution heat exchanger 4 and then connects the first absorber 2 to that the concentrated solution pipe of the first generator 1 passes through the third solution heat exchanger K6 and then connects the second generator A6. The second generator A6 has the concentrated solution pipe which passes through the fourth solution heat exchanger L6 and then connects the third generator B6. The third generator B6 has the concentrated solution pipe which passes through the first solution pump 7, the fourth solution heat exchanger L6, the third solution heat exchanger K6, the first solution heat exchanger 4 and then connects the first absorber 2. We adjust that the first generator 1 has the refrigerant vapor connected external to that the second generator A6 as liquid refrigerant pipe which passes through the first throttle F6 and then connects condenser C6 after that the first generator 1 has refrigerant vapor channel connected the second generator A6.

The refrigerant vapor produced by the first generator 1 is used as the thermal driving medium of the second generator A6. After that the second generator A6 has refrigerant vapor channel connected the third generator B6, the third generator B6 has liquid refrigerant pipe which flows through the second throttle G6 and then connects condenser C6. The refrigerant vapor produced by the second generator A6 is used as the thermal driving medium of the third generator B6. The third generator B6 has refrigerant vapor channel connected condenser C6.

That the first absorber 2 has refrigerant vapor channel connected external can be considered as that the second evaporator I6 has refrigerant vapor channel connected the first absorber 2. That the second absorber 3 has refrigerant vapor channel connected external can be considered as that the first evaporator D6 has refrigerant vapor channel connected the second absorber 3. That the steam bleeding chamber 6 has refrigerant vapor channel connected external can be considered as that the steam bleeding chamber 6 has refrigerant vapor channel connected condenser C6. Condenser C6 has the liquid refrigerant pipe which flows through liquid refrigerant pump H6 and then connects the first evaporator D6. The first evaporator D6 has the liquid refrigerant pipe which flows through the third throttle J6 and then connects the second evaporator I6. Condenser C6 has the cooling medium pipe connected external. The first evaporator D6 and the second evaporator I6 has residual medium pipe connected external too.

Secondly, on the process, the residual heat medium heats up the solution which enters the first generator 1. And the solution releases refrigerant vapor which is provided to the second generator A6. The refrigerant vapor is used as thermal driving medium. The concentrated solution of the first generator 1 flows through the third solution heat exchanger K6 and then enters the second generator A6.

The refrigerant vapor produced by the first generator 1 heat up the solution which enters the second generator A6. The solution releases refrigerant vapor which is provided to the third generator B6. The concentrated solution of the second generator A6 flows through the fourth solution heat exchanger L6 and then enters the third generator B6. The refrigerant vapor produced by the second generator A6 heats up the solution which enters the third generator B6. The solution releases refrigerant vapor which is provided to condenser C6. The concentrated solution of the third generator B6 flows through the first solution pump 7, the fourth solution heat exchanger L6, the third solution heat exchanger K6, the first solution heat exchanger 4 and then enters the first absorber 2. The refrigerant vapor, used as thermal driving medium of the second generator A6, releases heat becoming liquid refrigerant, then the solution flows through the first throttle F6 and then enters condenser C6. The refrigerant vapor, used as thermal driving medium of the third generator B6, releases heat becoming liquid refrigerant, then the solution flows through the second throttle G6 and then enters condenser C6.

The refrigerant vapor released by the steam bleeding chamber 6 enters condenser C6 where the refrigerant vapor releases heat to the cooling medium becoming liquid refrigerant. The liquid refrigerant of condenser C6 flows through liquid refrigerant pump H6 and then enters evaporator D6 where it is divided into two parts. One part of it absorbs residual heat becoming refrigerant vapor which is provided to the second absorber 3. The other part flows through the third throttle J6 and then enters the second evaporator I6 where it absorbs heat absorbs residual heat becoming refrigerant vapor which is provided to the first absorber 2. The heat release of the first absorber 2 is used to meet the heat demand of heated medium and satisfy the heating demand before the solution vaporization. The heat release of the second absorber 3 is used to meet the (high temperature) heat demand of heated medium. Finally, we get recuperative single stage tandem triple effect second-type absorption heat pump.

The recuperative single stage tandem triple effect second-type absorption heat pump adopting the solution tandem cycle recuperative generation-absorption system shown in FIG. 34 can be realized by the following way:

Firstly, structurally, in the solution tandem cycle generation-absorption system shown in FIG. 1, we add the second generator A6, the third generator B6, condenser C6, the first evaporator D6, the first throttle F6, the second throttle G6, liquid refrigerant pump H6, the second evaporator I6, the third throttle J6, the third solution heat exchanger K6, the fourth solution heat exchanger L6.

We adjust that the concentrated solution pipe of generator 1 passes through the first solution pump 7, the first solution heat exchanger 4, the first absorber 2 and then connects the steam bleeding chamber 6 to that the concentrated solution pipe of the first generator 1 passes through the third solution heat exchanger K6 and then connects the second generator A6. The second generator A6 has the concentrated solution pipe which passes through the fourth solution heat exchanger L6 and then connects the third generator B6. The third generator B6 has the concentrated solution pipe which passes through the first solution pump 7, the fourth solution heat exchanger L6, the third solution heat exchanger K6, the first solution heat exchanger 4, the first absorber 2 and then connects the steam bleeding chamber 6. We adjust that the first generator 1 has the refrigerant vapor connected external to that the second generator A6 as liquid refrigerant pipe which passes through the first throttle F6 and then connects condenser C6 after that the first generator 1 has refrigerant vapor channel connected the second generator A6.

The refrigerant vapor produced by the first generator 1 is used as the thermal driving medium of the second generator A6. After that the second generator A6 has refrigerant vapor channel connected the third generator B6, the third generator B6 has liquid refrigerant pipe which flows through the second throttle G6 and then connects condenser C6. The refrigerant vapor produced by the second generator A6 is used as the thermal driving medium of the third generator B6. The third generator B6 has refrigerant vapor channel connected condenser C6.

That the first absorber 2 has refrigerant vapor channel connected external can be considered as that the second evaporator I6 has refrigerant vapor channel connected the first absorber 2. That the second absorber 3 has refrigerant vapor channel connected external can be considered as that the first evaporator D6 has refrigerant vapor channel connected the second absorber 3. That the steam bleeding chamber 6 has refrigerant vapor channel connected external can be considered as that the steam bleeding chamber 6 has refrigerant vapor channel connected condenser C6. Condenser C6 has the liquid refrigerant pipe which flows through liquid refrigerant pump H6 and then connects the first evaporator D6. The first evaporator D6 has the liquid refrigerant pipe which flows through the third throttle J6 and then connects the second evaporator I6. Condenser C6 has the cooling medium pipe connected external. The first evaporator D6 and the second evaporator I6 has residual medium pipe connected external too.

Secondly, on the process, the residual heat medium heats up the solution which enters the first generator 1. And the solution releases refrigerant vapor which is provided to the second generator A6. The refrigerant vapor is used as thermal driving medium. The concentrated solution of the first generator 1 flows through the third solution heat exchanger K6 and then enters the second generator A6.

The refrigerant vapor produced by the first generator 1 heat up the solution which enters the second generator A6. The solution releases refrigerant vapor which is provided to the third generator B6. The concentrated solution of the second generator A6 flows through the fourth solution heat exchanger L6 and then enters the third generator B6. The refrigerant vapor produced by the second generator A6 heats up the solution which enters the third generator B6. The solution releases refrigerant vapor which is provided to condenser C6. The concentrated solution of the third generator B6 flows through the first solution pump 7, the fourth solution heat exchanger L6, the third solution heat exchanger K6, the first solution heat exchanger 4, the first absorber 2 and then enters the steam bleeding chamber 6. The refrigerant vapor, used as thermal driving medium of the second generator A6, releases heat becoming liquid refrigerant, then the solution flows through the first throttle F6 and then enters condenser C6. The refrigerant vapor, used as thermal driving medium of the third generator B6, releases heat becoming liquid refrigerant, then the solution flows through the second throttle G6 and then enters condenser C6.

The refrigerant vapor released by the steam bleeding chamber 6 enters condenser C6 where the refrigerant vapor releases heat to the cooling medium becoming liquid refrigerant. The liquid refrigerant of condenser C6 flows through liquid refrigerant pump H6 and then enters evaporator D6 where it is divided into two parts. One part of it absorbs residual heat becoming refrigerant vapor which is provided to the second absorber 3. The other part flows through the third throttle J6 and then enters the second evaporator I6 where it absorbs heat absorbs residual heat becoming refrigerant vapor which is provided to the first absorber 2. The heat release of the first absorber 2 is used to meet the heat demand of heated medium and satisfy the heating demand before the solution vaporization. The heat release of the second absorber 3 is used to meet the (high temperature) heat demand of heated medium. Finally, we get recuperative single stage tandem triple effect second-type absorption heat pump.

The recuperative single stage parallel triple effect second-type absorption heat pump adopting the solution independent cycle recuperative generation-absorption system shown in FIG. 35 can be realized by the following way:

Firstly, structurally, in the solution independent cycle generation-absorption system shown in FIG. 3, we add the third solution pump 9, the second generator A6, the third generator B6, condenser C6, evaporator D6, the fourth solution pump E6, the first throttle F6, the second throttle G6, liquid refrigerant pump H6, the third solution heat exchanger K6, the fourth solution heat exchanger L6.

Taking the second generator A6 as medium voltage generator and using the third generator B6 as low pressure generator, the concentrated solution pipe of the second generator A6 passes through the third solution pump 9, the third solution heat exchanger K6 and then connects the first absorber 2. The first absorber 2 has the dilute solution pipe which passes through the third solution heat exchanger K6 and then connects the second generator A6. The concentrated solution pipe of the third generator B6 passes through the fourth solution pump E6, the fourth solution heat exchanger L6 and then connects the first absorber 2. The first absorber 2 has the dilute solution pipe which passes through the fourth solution heat exchanger L6 and then connects the third generator B6.

That the first generator 1 has refrigerant vapor channel connected external can be considered that the second generator A6 has liquid refrigerant pipe which passes through the first throttle F6 and then connects condenser C6 after that the first generator 1 has refrigerant vapor channel connected the second generator A6. The refrigerant vapor produced by the first generator 1 is used as the thermal driving medium of the second generator A6. After that the second generator A6 has refrigerant vapor channel connected the third generator B6, the third generator B6 has liquid refrigerant pipe which flows through the second throttle G6 and then connects condenser C6. The refrigerant vapor produced by the second generator A6 is used as the thermal driving medium of the third generator B6. The third generator B6 has refrigerant vapor channel connected condenser C6.

That the first absorber 2 has refrigerant vapor channel connected external can be considered as that evaporator D6 has refrigerant vapor channel connected the first absorber 2. That the second absorber 3 has refrigerant vapor channel connected external can be considered as that evaporator D6 has refrigerant vapor channel connected the second absorber 3. That the steam bleeding chamber 6 has refrigerant vapor channel connected external can be considered as that the steam bleeding chamber 6 has refrigerant vapor channel connected condenser C6. Condenser C6 has the liquid refrigerant pipe which flows through liquid refrigerant pump H6 and then connects the first evaporator D6. Condenser C6 has the cooling medium pipe connected external. The first evaporator D6 and the second evaporator I6 has residual medium pipe connected external too.

Secondly, on the process, the residual heat medium heats up the solution which enters the first generator 1. And the solution releases refrigerant vapor which is provided to the second generator A6. The refrigerant vapor is used as thermal driving medium. The refrigerant vapor produced by the first generator 1 heat up the solution which flows through the third solution heat exchanger K6 and then enters the second generator A6 from the first absorber 2. And the solution releases refrigerant vapor which is provided to the third generator B6. The concentrated solution of the second generator A6 flows through the third solution pump 9, the third solution heat exchanger K6 and then enters the first absorber 2. The refrigerant vapor produced by the second generator A6 heats up the solution which flows through the fourth solution heat exchanger L6 and then enters the third generator B6 from the first absorber 2. And the solution releases refrigerant vapor which is provided to condenser C6. The concentrated solution of the third generator B6 flows through the fourth solution pump E6, the fourth solution heat exchanger L6 and then enters the first absorber 2.

The refrigerant vapor, used as thermal driving medium of the second generator A6, releases heat becoming liquid refrigerant, then the solution flows through the first throttle F6 and then enters condenser C6. The refrigerant vapor, used as thermal driving medium of the third generator B6, releases heat becoming liquid refrigerant, then the solution flows through the second throttle G6 and then enters condenser C6. The refrigerant vapor released by the steam bleeding chamber 6 enters condenser C6 where the refrigerant vapor releases heat to the cooling medium becoming liquid refrigerant. The liquid refrigerant of condenser C6 flows through liquid refrigerant pump H6 and its pressure is increased. Then the solution enters evaporator D6 in which it absorbs residual heat becoming refrigerant vapor which is separately provided to the first absorber 2 and the second absorber 3. The heat release of the first absorber 2 is used to meet the heat demand of heated medium and satisfy the heating demand before the solution vaporization. The heat release of the second absorber 3 is used to meet the (high temperature) heat demand of heated medium. Finally, we get recuperative single stage parallel triple effect second-type absorption heat pump.

The recuperative single stage parallel triple effect second-type absorption heat pump adopting the solution tandem cycle recuperative generation-absorption system shown in FIG. 36 can be realized by the following way:

Firstly, structurally, in the solution tandem cycle generation-absorption system shown in FIG. 1, we add the second generator A6, the third generator B6, condenser C6, evaporator D6, the first throttle F6, the second throttle G6, liquid refrigerant pump H6, the third solution heat exchanger K6, the fourth solution heat exchanger L6.

Taking the second generator A6 as high pressure generator and using the third generator B6 as medium voltage generator, the concentrated solution pipe of the second generator A6 passes through the third solution heat exchanger K6 and then it joins with the two pipes. One pipe is the concentrated solution pipe of the fourth solution heat exchanger L6 which comes from the third generator B6. The other pipe is the concentrated solution pipe which passes through the first solution pump 7, the first solution heat exchanger 4 from the first generator 1. The first absorber 2 has the dilute solution pipe which passes through the third solution heat exchanger K6 and then connects the second generator A6. The first absorber 2 has the dilute solution pipe which passes through the fourth solution heat exchanger L6 and then connects the third generator B6.

That the first generator 1 has the thermal driving heat medium pipe connected external can be considered that the first generator 1 has liquid refrigerant pipe which passes through the second throttle G6 and then connects condenser C6 after that the third generator B6 has refrigerant vapor channel connected the first generator 1. The refrigerant vapor produced by the third generator B6 is used as the thermal driving medium of the first generator 1. After that the second generator A6 has refrigerant vapor channel connected the third generator B6, the third generator B6 has liquid refrigerant pipe which flows through the first throttle F6 and then connects condenser C6. The refrigerant vapor produced by the second generator A6 is used as the thermal driving medium of the third generator B6.

That the first generator 1 has refrigerant vapor channel connected external can be considered as that the first generator 1 has refrigerant vapor channel connected condenser C6. That the first absorber 2 has refrigerant vapor channel connected external can be considered as that evaporator D6 has refrigerant vapor channel connected the first absorber 2. That the second absorber 3 has refrigerant vapor channel connected external can be considered as that evaporator D6 has refrigerant vapor channel connected the second absorber 3. That the steam bleeding chamber 6 has refrigerant vapor channel connected external can be considered as that the steam bleeding chamber 6 has refrigerant vapor channel connected condenser C6. Condenser C6 has the liquid refrigerant pipe which flows through liquid refrigerant pump H6 and then connects the first evaporator D6. Condenser C6 has the cooling medium pipe connected external. The second generator A6 and evaporator D6 has residual medium pipe connected external too.

Secondly, on the process, the residual heat medium heats up the solution which flows through the third solution heat exchanger K6 and then enters the second generator A6 from the first absorber 2. And the solution releases refrigerant vapor which is provided to the third generator B6. The refrigerant vapor is used as thermal driving medium. The concentrated solution of the second generator A6 flows through the third solution heat exchanger K6 and then it joins with the concentrated solution which flows through the first solution pump 7, the first solution heat exchanger 4 from the first generator 1. The refrigerant vapor produced by the second generator A6 heats up the solution which flows through the fourth solution heat exchanger L6 and then enters the third generator B6 from the first absorber 2. In the third generator B6, it releases refrigerant vapor which is provided to condenser C6. After that the concentrated solution of the third generator B6 flows through the fourth solution heat exchanger L6, it joins with the concentrated solution which flows through the first solution pump 7, the first solution heat exchanger 4 from the first generator 1.

The refrigerant vapor, used as thermal driving medium of the second generator A6, releases heat becoming liquid refrigerant, then the solution flows through the first throttle F6 and then enters condenser C6. The refrigerant vapor, used as thermal driving medium of the third generator B6, releases heat becoming liquid refrigerant, then the solution flows through the second throttle G6 and then enters condenser C6. The refrigerant vapor released by the steam bleeding chamber 6 enters condenser C6 where the refrigerant vapor releases heat to the cooling medium becoming liquid refrigerant. The liquid refrigerant of condenser C6 flows through liquid refrigerant pump H6 and its pressure is increased. Then the solution enters evaporator D6 in which it absorbs residual heat becoming refrigerant vapor which is separately provided to the first absorber 2 and the second absorber 3. The heat release of the first absorber 2 is used to meet the heat demand of heated medium and satisfy the heating demand before the solution vaporization. The heat release of the second absorber 3 is used to meet the (high temperature) heat demand of heated medium. Finally, we get recuperative single stage parallel triple effect second-type absorption heat pump.

The recuperative single stage parallel triple effect second-type absorption heat pump adopting the solution tandem cycle recuperative generation-absorption system shown in FIG. 37 can be realized by the following way:

Firstly, structurally, in the solution tandem cycle generation-absorption system shown in FIG. 1, we add the second generator A6, the third generator B6, condenser C6, the first evaporator D6, the first throttle F6, the second throttle G6, liquid refrigerant pump H6, the second evaporator I6, the third throttle J6, the third solution heat exchanger K6, the fourth solution heat exchanger L6.

Taking the second generator A6 as high pressure generator and using the third generator B6 as medium voltage generator, the concentrated solution pipe of the second generator A6 passes through the third solution heat exchanger K6 and then it joins with the two pipes. One pipe is the concentrated solution pipe of the fourth solution heat exchanger L6 which comes from the third generator B6. The other pipe is the concentrated solution pipe which passes through the first solution pump 7, the first solution heat exchanger 4 from the first generator 1. The first absorber 2 has the dilute solution pipe which passes through the third solution heat exchanger K6 and then connects the second generator A6. The first absorber 2 has the dilute solution pipe which passes through the fourth solution heat exchanger L6 and then connects the third generator B6.

That the first generator 1 has the thermal driving heat medium pipe connected external can be considered that the first generator 1 has liquid refrigerant pipe which passes through the second throttle G6 and then connects condenser C6 after that the third generator B6 has refrigerant vapor channel connected the first generator 1. The refrigerant vapor produced by the third generator B6 is used as the thermal driving medium of the first generator 1. After that the second generator A6 has refrigerant vapor channel connected the third generator B6, the third generator B6 has liquid refrigerant pipe which flows through the first throttle F6 and then connects condenser C6. The refrigerant vapor produced by the second generator A6 is used as the thermal driving medium of the third generator B6.

That the first generator 1 has refrigerant vapor channel connected external can be considered as that the first generator 1 has refrigerant vapor channel connected condenser C6. That the first absorber 2 has refrigerant vapor channel connected external can be considered as that the second evaporator I6 has refrigerant vapor channel connected the first absorber 2. That the second absorber 3 has refrigerant vapor channel connected external can be considered as that the first evaporator D6 has refrigerant vapor channel connected the second absorber 3. That the steam bleeding chamber 6 has refrigerant vapor channel connected external can be considered as that the steam bleeding chamber 6 has refrigerant vapor channel connected condenser C6. Condenser C6 has the liquid refrigerant pipe which flows through liquid refrigerant pump H6 and then connects the first evaporator D6. The first evaporator D6 has liquid refrigerant pipe which flows through the third throttle J6 and then connects the second evaporator I6. Condenser C6 has the cooling medium pipe connected external. The second generator A6, the first evaporator D6 and the second evaporator I6 has residual medium pipe connected external too.

Secondly, on the process, the residual heat medium heats up the solution which flows through the third solution heat exchanger K6 and then enters the second generator A6 from the first absorber 2. And the solution releases refrigerant vapor which is provided to the third generator B6. The refrigerant vapor is used as thermal driving medium. The concentrated solution of the second generator A6 flows through the third solution heat exchanger K6 and then it joins with the concentrated solution which flows through the first solution pump 7, the first solution heat exchanger 4 from the first generator 1. The refrigerant vapor produced by the second generator A6 heats up the solution which flows through the fourth solution heat exchanger L6 and then enters the third generator B6 from the first absorber 2. In the third generator B6, it releases refrigerant vapor which is provided to condenser C6. After that the concentrated solution of the third generator B6 flows through the fourth solution heat exchanger L6, it joins with the concentrated solution which flows through the first solution pump 7, the first solution heat exchanger 4 from the first generator 1.

The refrigerant vapor, used as thermal driving medium of the second generator A6, releases heat becoming liquid refrigerant, then the solution flows through the first throttle F6 and then enters condenser C6. The refrigerant vapor, used as thermal driving medium of the third generator B6, releases heat becoming liquid refrigerant, then the solution flows through the second throttle G6 and then enters condenser C6. The refrigerant vapor released by the steam bleeding chamber 6 enters condenser C6 where the refrigerant vapor releases heat to the cooling medium becoming liquid refrigerant. The liquid refrigerant of condenser C6 flows through liquid refrigerant pump H6 and its pressure is increased. Then the solution enters evaporator D6 in which it is divided into two parts. One part of it absorbs residual heat becoming refrigerant vapor which is provided to the second absorber 3. The other part flows through the third throttle J6 and then enters the second evaporator I6 where it absorbs heat absorbs residual heat becoming refrigerant vapor which is provided to the first absorber 2. The heat release of the first absorber 2 is used to meet the heat demand of heated medium and satisfy the heating demand before the solution vaporization. The heat release of the second absorber 3 is used to meet the (high temperature) heat demand of heated medium. Finally, we get recuperative single stage parallel triple effect second-type absorption heat pump.

The recuperative single-stage single-effect second-type absorption heat pump with high-temperature heating-side which adopts the solution independent cycle recuperative generation-absorption system shown in FIG. 38 can be realized by the following way:

Firstly, structurally, in the recuperative single-stage single-effect second-type absorption heat pump shown in FIG. 7, we add the new added absorption-evaporator a, the new added absorber b, the new added liquid refrigerant pump e, the new added first solution heat exchanger c and the new added second solution heat exchanger d.

The second solution pump 8 has the concentrated solution pipe which passes through the new added second solution heat exchanger d, the new added first solution heat exchanger c and then connects the new added absorber b. The new added absorber b has the dilute solution pipe which passes through the new added first solution heat exchanger c and then connects the new added absorption-evaporator a. The new added absorption-evaporator a has the dilute solution pipe which passes through the new added second solution heat exchanger d and then joins with the other dilute solution pipe which flows through the second solution heat exchanger 5 from the second absorber 3. After that the first evaporator B1 has the liquid refrigerant pipe which flows through the new added liquid refrigerant pump e, the new added absorption-evaporator a, the new added absorption-evaporator a has the refrigerant vapor channel connected the new added absorber b. The first evaporator B1 has the refrigerant vapor channel connected the new added absorption-evaporator a. The new added absorber b has the heated medium pipe connected external.

Secondly, on the process, the solution of the steam bleeding chamber 6 flows through the second solution pump 8, the new added second solution heat exchanger d, the new added first solution heat exchanger c and then enters the new added absorber b in which the solution absorbs refrigerant vapor and releases heat to the heated medium. The dilute solution of the new added absorber b flows through the new added first solution heat exchanger c and then enters the new added absorption-evaporator a where it absorbs the refrigerant vapor coming from the first evaporator B1 and releases heat. The heat heats up the other liquid refrigerant which flows through the new added absorption-evaporator a. And the liquid refrigerant becomes refrigerant vapor which is provided to the new added absorber b. After that the dilute solution of the new added absorption-evaporator a which flows through the new added second solution heat exchanger d, the solution joins with the dilute solution which haven't flowed into the first absorber 2. After the merger, the solution absorbs heat from the first absorber 2 and part of it is vaporization. Then it enters the steam bleeding chamber. The new added absorber b is the adjacent high-temperature heating-side of the second absorber 3.

The recuperative single stage tandem double-effect second-type absorption heat pump with high-temperature heating-side which adopts the solution tandem cycle recuperative generation-absorption system shown in FIG. 39 can be realized by the following way:

Firstly, structurally, in the recuperative single stage tandem double-effect second-type absorption heat pump shown in FIG. 21, we add the new added absorption-evaporator a, the new added absorber b, the new added throttle f, the new added first solution heat exchanger c and the new added second solution heat exchanger d.

The second solution pump 8 has the concentrated solution pipe which passes through the new added second solution heat exchanger d, the new added first solution heat exchanger c and then connects the new added absorber b. The new added absorber b has the dilute solution pipe which passes through the new added first solution heat exchanger c and then connects the new added absorption-evaporator a. The new added absorption-evaporator a has the dilute solution pipe which passes through the new added second solution heat exchanger d and then joins with the other dilute solution pipe which flows through the first solution pump 7, the third solution heat exchanger H5 and the first solution heat exchanger 4 from the first generator 1.

After that condenser B5 has the liquid refrigerant pipe which flows through the liquid refrigerant pump F5 and then connects the new added absorption-evaporator a, the new added absorption-evaporator a has the refrigerant vapor channel connected the new added absorber b. At the same time, we adjust that the liquid refrigerant pipe from condenser B5 flows through the liquid refrigerant pump F5 and then connects evaporator C5 to that the liquid refrigerant pipe from condenser B5 flows through the liquid refrigerant pump F5, the new added throttle f and then connects evaporator C5. Evaporator C5 has the refrigerant vapor channel connected the new added absorption-evaporator a. The new added absorber b has the heated medium pipe connected external.

Secondly, on the process, the solution of the steam bleeding chamber 6 flows through the second solution pump 8, the new added second solution heat exchanger d, the new added first solution heat exchanger c and then enters the new added absorber b in which the solution absorbs refrigerant vapor and releases heat to the heated medium. The dilute solution of the new added absorber b flows through the new added first solution heat exchanger c and then enters the new added absorption-evaporator a where it absorbs the refrigerant vapor coming from evaporator C5 and releases heat. The heat heats up the other liquid refrigerant which flows through the new added absorption-evaporator a. And the liquid refrigerant becomes refrigerant vapor which is provided to the new added absorber b. After that the dilute solution of the new added absorption-evaporator a that flows through the new added second solution heat exchanger d, the solution joins with the dilute solution which haven't flowed into the first absorber 2. After the merger, the solution absorbs heat from the first absorber 2 and part of it is vaporization. Then it enters the steam bleeding chamber. The new added absorber b is the adjacent high-temperature heating-side of the second absorber 3.

FIG. 38 and FIG. 39 are two representatives of the recuperative second-type absorption heat pumps with high-temperature heating-side. Refer to the two examples and the above detailed content of this invention, the others second-type absorption heat pumps which bases on the recuperative generation-absorption system all can take similar methods and steps to add the high-temperature heating-side.

INDUSTRIAL APPLICABILITY

The recuperative generation-absorption system and the recuperative second-type absorption heat pump which are put forward by the invention have the effect and advantages as following:

{circle around (1)} The recuperative generation-absorption systems of this invention use the combine of the steam bleeding chamber and absorber. In this way, the structure is simple and the heat transfer link in the recuperative process is least. We also can improve the heating temperature of the system and reduce the production cost.

{circle around (2)} The recuperative generation-absorption systems of this invention have simple structure and reasonable process. We can reduce the equipment cost.

{circle around (3)} Using the recuperative generation-absorption systems of this invention, we can choose the extent of recuperative heat based on the heating temperature. Thereby, we can realize the parallelism between the heating temperature and performance index. That is beneficial to maintain a higher performance index and improve the utilization efficiency of waste heat.

{circle around (4)} The second-type absorption heat pump in this invention can use the residual heat with lower temperature, provide a higher temperature heating and expand the heating temperature range.

{circle around (5)} The recuperative generation-absorption system and the second-type absorption heat pump which are put forward by the invention have low temperature heating-side and high temperature heating-side. We can get a further improving the energy-saving benefit when the invention is used in the temperature range of heated medium.

In a word, the recuperative generation-absorption system and the second-type absorption heat pump which are put forward by the invention can realize the diversity of second-type absorption heat pump, the simplification of units' structure and the high temperature heating of units. At the same time, the units can maintain a higher performance index and meet the heat demand of users. They own a well novelty, creativity and practicality.

Claims

1. A recuperative generation-absorption system comprising a generator, a first absorber, a second absorber, a first solution heat exchanger, a second solution heat exchanger, a steam bleeding chamber, a first solution pump, a second solution pump or one more a third solution pump,

wherein a concentrated solution pipe of the generator (1) passes through the first solution pump (7), the first solution heat exchanger (4) and the first absorber (2) and then connects the steam bleeding chamber (6), a concentrated solution pipe of the steam bleeding chamber (6) passes through the second solution pump (8) and the second solution heat exchanger (5) and then connects the second absorber (3), a dilute solution pipe of the second absorber (3) passes through the second solution heat exchanger (5), the third solution pump (9) if the system has the third solution pump (9) and then connects the first absorber (2), and a dilute solution pipe of the first absorber (2) passes through the first solution heat exchanger (4) and then connects generator (1),

wherein the generator (1) has a pipe of residual heat medium or a pipe of thermal driving medium and a channel of refrigerant vapor which separately connect external, the first absorber (2) has a pipe of heated medium and a channel of refrigerant vapor which separately connect external, the second absorber (3) has a channel of refrigerant vapor and a channel of heated medium which separately connect external, and the steam bleeding chamber (6) has a channel of refrigerant vapor which connects external,

wherein a dilute solution of generator (1) is heated by the residual heat medium or the thermal driving medium and releases refrigerant vapor at the same time, a concentrated solution of the generator (1) flows through the first solution pump (7), the first solution heat exchanger (4), the first absorber (2) in which it absorbs heat and a part of it is vaporized and then enters the steam bleeding chamber (6) which releases refrigerant vapor, the concentrated solution pipe of the steam bleeding chamber (6) flows through the second solution pump (8), the second solution heat exchanger (5) and then enters the second absorber (3) in which it absorbs the refrigerant vapor coming from outside the system and releases heat to the heated medium at the same time, the dilute solution of the second absorber (3) flows through the second solution heat exchanger (5), the third solution pump (9) if the system has it and then enters the first absorber (2) in which it absorbs the refrigerant vapor coming from outside the system and heats up the solution which flows through the first absorber (2) and meets the heat demand of heated medium, the dilute solution of the first absorber (2) flows through the first solution heat exchanger (4) and then flows back to generator (1) in which it releases refrigerant vapor, thereby obtaining the recuperative generation-absorption system of solution tandem cycle,

wherein when the first absorber (2) hasn't the pipe of heated medium connected external, the heat which is released by absorbing the refrigerant vapor in the first absorber (2) is used to heat the solution which flows through the first absorber (2).

2. A recuperative generation-absorption system comprising a generator, a first absorber, a second absorber, a first solution heat exchanger, a second solution heat exchanger, a steam bleeding chamber, a first solution pump, and a second solution pump,

wherein a concentrated solution pipe of the generator (1) passes through the first solution pump (7), the first solution heat exchanger (4) and then connects the first absorber (2), a dilute solution pipe of the first absorber (2) passes through the first solution heat exchanger (4) and then connects generator (1), a dilute solution pipe of the second absorber (3) passes through the second solution heat exchanger (5), the first absorber (2) and then connects the steam bleeding chamber (6), a concentrated solution pipe of the steam bleeding chamber (6) passes through the second solution pump (8), the second solution heat exchanger (5) and then connects the second absorber (3),

wherein the generator (1) has a pipe of residual heat medium or a pipe of thermal driving medium and a channel of refrigerant vapor which separately connect external, the first absorber (2) has a pipe of heated medium and a channel of refrigerant vapor which separately connect external, the second absorber (3) has a channel of refrigerant vapor and a channel of heated medium which separately connect external, and the steam bleeding chamber (6) has a channel of refrigerant vapor which connects external,

wherein a dilute solution of the generator (1) is heated by the residual heat medium or the thermal driving medium and releases refrigerant vapor at the same time, a concentrated solution of the generator (1) flows through the first solution pump (7), the first solution heat exchanger (4) and then enters the first absorber (2) in which it absorbs the refrigerant vapor coming from outside the system and heats up the solution which flows through the first absorber (2) and meets the heat demand of heated medium, a dilute solution of the first absorber (2) flows through the first solution heat exchanger (4) and then flows back to generator (1), the solution which flows through the first absorber (2) absorbs heat and a part of it is vaporization and then enters the steam bleeding chamber (6) which releases refrigerant vapor, the concentrated solution pipe of the steam bleeding chamber (6) flows through the second solution pump (8), the second solution heat exchanger (5) and then enters the second absorber (3) in which it absorbs the refrigerant vapor coming from outside the system and releases heat to the heated medium at the same time, the dilute solution of the second absorber (3) flows through the second solution heat exchanger (5), the first absorber (2) and then enters the steam bleeding chamber (6), thereby obtaining the recuperative generation-absorption system with solution independent loop,

wherein when the first absorber (2) hasn't the pipe of heated medium connected external, the heat which is released by absorbing the refrigerant vapor in the first absorber (2) is used to heat the solution which flows through the first absorber (2).

3. The recuperative generation-absorption system, as recited in claim 1 or 2, wherein a recuperative single-stage single-effect second-type absorption heat pump is formed by adding a condenser (A1), a first evaporator (B1), a liquid refrigerant pump (C1), a second evaporator (D1), and a throttle (E1) and taking residual heat medium as thermal driving medium,

wherein that the refrigerant vapor channel of the generator (1) connects external can be considered as that the refrigerant vapor channel of the generator (1) connects the condenser (A1), that the refrigerant vapor channel of the steam bleeding chamber (6) connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber (6) connects condenser (A1), that the refrigerant vapor channel of the first absorber (2) connects external can be considered as that the refrigerant vapor channel of the second evaporator (D1) connects the first absorber (2), that the refrigerant vapor channel of the second absorber (3) connects external can be considered as that the refrigerant vapor channel of the first evaporator (B1) connects the second absorber (3), the liquid refrigerant channel of condenser (A1) passes through liquid refrigerant pump (C1) and then connects the first evaporator (B1), the liquid refrigerant channel of the first evaporator (B1) passes through the throttle (E1) and then connects the second evaporator (D1), the condenser (A1) has the pipe of cooling medium which connects external, the first evaporator (B1) and the second evaporator (D1) also have the pipe of residual heat medium which separately connects external,

wherein when the system hasn't the second evaporator (D1) and the throttle (E1), the channel of refrigerant vapor in the first evaporator (B1) separately connects the first absorber (2) and the second absorber (3).

4. The recuperative generation-absorption system, as recited in claim 1 or 2, wherein a recuperative single generator two-stage second-type absorption heat pump in which the absorption-evaporator (C2) separately provides refrigerant vapor to the first absorber (2) and the second absorber (3) is formed by adding a condenser (A2), an evaporator (B2), an absorption-evaporator (C2), a liquid refrigerant pump (D2), a throttle (E2), and a third solution heat exchanger (F2) and taking residual heat medium as thermal driving medium, that the dilute solution pipe of the first absorber (2) passes through the first solution heat exchanger (4) and then connects generator (1) is changed to that the dilute solution pipe passes through the first solution heat exchanger (4) and then connects generator (1) after that the dilute solution pipe of the first absorber (2) passes through the third solution heat exchanger (F2) and then connects absorption-evaporator (C2), that the concentrated solution pipe of generator (1) passes through the first solution pump (7), the first solution heat exchanger (4) and then connects the first absorber (2) or the concentrated solution pipe of generator (1) passes through the first solution pump (7), the first solution heat exchanger (4), the first absorber (2) and then connects the steam bleeding chamber (6) is adjusted to that the concentrated solution pipe of generator (1) passes through the first solution pump (7), the first solution heat exchanger (4), the third solution heat exchanger (F2) and then connects the first absorber (2) or the concentrated solution pipe of generator (1) passes through the first solution pump (7), the first solution heat exchanger (4), the third solution heat exchanger (F2), the first absorber (2) and then connects the steam bleeding chamber (6), that the refrigerant vapor channel of generator (1) connects external can be considered as that the refrigerant vapor channel of generator (1) connects condenser (A2), that the refrigerant vapor channel of the steam bleeding chamber (6) connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber (6) connects condenser (A2), that the refrigerant vapor channel of the first absorber (2) and the second absorber (3) separately connects external can be considered as that the refrigerant vapor channel of absorption-evaporator (C2) separately connects the first absorber (2) and the second absorber (3) after that the liquid refrigerant channel of condenser (A2) passes through liquid refrigerant pump (D2) and then connects absorption-evaporator (C2), the liquid refrigerant pipe of liquid refrigerant pump (D2) passes through the throttle (E2) and then connects evaporator (B2), the refrigerant vapor channel of evaporator (B2) connects absorption-evaporator (C2), the condenser (A2) has the pipe of cooling medium (A2) connects external, and the evaporator (B2) has the pipe of residual heat medium which connects external.

5. The recuperative generation-absorption system, as recited in claim 1 or 2, wherein a recuperative single generator two-stage second-type absorption heat pump in which absorption-evaporator (C2) separately provides refrigerant vapor to the first absorber (2) and the second absorber (3) is formed by adding a condenser (A2), an evaporator (B2), an absorption-evaporator (C2), a first liquid refrigerant pump (D2), a second liquid refrigerant pump (G2), and a third solution heat exchanger (F2) and taking residual heat medium as thermal driving medium, that the dilute solution pipe of the first absorber (2) passes through the first solution heat exchanger (4) and then connects generator (1) is adjusted to that the dilute solution pipe of absorption-evaporator (C2) passes through the first solution heat exchanger (4) and then connects generator (1) after that the dilute solution pipe of the first absorber (2) passes through the third solution heat exchanger (F2) and then connects absorption-evaporator (C2),

wherein that the concentrated solution pipe of generator (1) passes through the first solution pump (7), the first solution heat exchanger (4) and then connects the first absorber (2) or the concentrated solution pipe of generator (1) passes through the first solution pump (7), the first solution heat exchanger (4), the first absorber (2) and then connects the steam bleeding chamber (6) is adjusted to that the concentrated solution pipe of generator (1) passes through the first solution pump (7), the first solution heat exchanger (4), the third solution heat exchanger (F2) and then connects the first absorber (2) or the concentrated solution pipe of generator (1) passes through the first solution pump (7), the first solution heat exchanger (4), the third solution heat exchanger (F2), the first absorber (2) and then connects the steam bleeding chamber (6),

wherein that the refrigerant vapor channel of generator (1) connects external can be considered as that the refrigerant vapor channel of generator (1) connects condenser (A2), that the refrigerant vapor channel of the steam bleeding chamber (6) connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber (6) connects condenser (A2), that the refrigerant vapor channel of the first absorber (2) and the second absorber (3) separately connects external can be considered as that the refrigerant vapor channel of absorption-evaporator (C2) separately connects the first absorber (2) and the second absorber (3) after that the liquid refrigerant channel of evaporator (B2) passes through the second liquid refrigerant pump (G2) and then connects absorption-evaporator (C2), the condenser (A2) has the pipe of liquid refrigerant which passes through the first liquid refrigerant pump (D2) and then connects evaporator (B2), the evaporator (B2) has the refrigerant vapor channel which connects absorption-evaporator (C2), the condenser (A2) has the pipe of cooling medium (A2) which connects external, and the evaporator (B2) has the pipe of residual heat medium which connects external.

6. The recuperative generation-absorption system, as recited in claim 1 or 2, wherein a recuperative single generator three-stage second-type absorption heat pump in which two-stage absorption-evaporator (D3) separately provides refrigerant vapor to the first absorber (2) and the second absorber (3) is formed by adding a condenser (A3), an evaporator (B3), a one-level absorption-evaporator (C3), a two-stage absorption-evaporator (D3), a liquid refrigerant pump (E3), a first throttle (F3), a second throttle (G3), a third solution heat exchanger (H3), and a fourth solution heat exchanger (I3) and taking residual heat medium as thermal driving medium,

wherein that the dilute solution pipe of the first absorber (2) passes through the first solution heat exchanger (4) and then connects generator (1) is adjusted to that the dilute solution pipe of the first absorber (2) passes through the third solution heat exchanger (H3) and then connects two-stage absorption-evaporator (D3), the dilute solution pipe of two-stage absorption-evaporator (D3) passes through the fourth solution heat exchanger (I3) and then connects one-level absorption-evaporator (C3), the dilute solution pipe of one-level absorption-evaporator (C3) passes through the first solution heat exchanger (4) and then connects generator (1),

wherein that the concentrated solution pipe of generator (1) passes through the first solution pump (7), the first solution heat exchanger (4) and then connects the first absorber (2) or the concentrated solution pipe of generator (1) passes through the first solution pump (7), the first solution heat exchanger (4), the first absorber (2) and then connects the steam bleeding chamber (6) is adjusted to that the concentrated solution pipe of generator (1) passes through the first solution pump (7), the first solution heat exchanger (4), the fourth solution heat exchanger (I3), the third solution heat exchanger (H3) and then connects the first absorber (2) or the concentrated solution pipe of generator (1) passes through the first solution pump (7), the first solution heat exchanger (4), the fourth solution heat exchanger (I3), the third solution heat exchanger (H3), the first absorber (2) and then connects the steam bleeding chamber (6),

wherein that the refrigerant vapor channel of generator (1) connects external can be considered as that the refrigerant vapor channel of generator (1) connects condenser (A3), that the refrigerant vapor channel of the steam bleeding chamber (6) connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber (6) connects condenser (A3), that the refrigerant vapor channel of the first absorber (2) and the second absorber (3) separately connects external can be considered as that the channel of refrigerant vapor separately connects the first absorber (2) and the second absorber (3) after that the liquid refrigerant channel of condenser (A3) passes through the liquid refrigerant pump (E3) and then connects two-stage absorption-evaporator (D3), the liquid refrigerant pipe of the liquid refrigerant pump (E3) passes through the first throttle (F3) and then connects evaporator (B3), the refrigerant vapor channel of evaporator (B3) and then connects one-level absorption-evaporator (C3), the refrigerant vapor pipe of the one-level absorption-evaporator (C3) connects two-stage absorption-evaporator (D3) after that the liquid refrigerant pipe of the liquid refrigerant pump (E3) passes through the second throttle (G3) and then connects one-level absorption-evaporator (C3).

7. The recuperative generation-absorption system, as recited in claim 1 or 2, wherein a recuperative single generator three-stage second-type absorption heat pump in which two-stage absorption-evaporator (D3) separately provides refrigerant vapor to the first absorber (2) and the second absorber (3) is formed by adding a condenser (A3), an evaporator (B3), a one-level absorption-evaporator (C3), a two-stage absorption-evaporator (D3), a first liquid refrigerant pump (E3), a third solution heat exchanger (H3), a fourth solution heat exchanger (I3), a second liquid refrigerant pump (J3), and a third liquid refrigerant pump (K3) and taking residual heat medium as thermal driving medium,

wherein that the dilute solution pipe of the first absorber (2) passes through the first solution heat exchanger (4) and then connects generator (1) is adjusted to that the dilute solution pipe of the first absorber (2) passes through the third solution heat exchanger (H3) and then connects two-stage absorption-evaporator (D3), the dilute solution pipe of two-stage absorption-evaporator (D3) passes through the fourth solution heat exchanger (I3) and then connects one-level absorption-evaporator (C3), the dilute solution pipe of one-level absorption-evaporator (C3) passes through the first solution heat exchanger (4) and then connects generator (1),

wherein that the concentrated solution pipe of generator (1) passes through the first solution pump (7), the first solution heat exchanger (4) and then connects the first absorber (2) or the concentrated solution pipe of generator (1) passes through the first solution pump (7), the first solution heat exchanger (4), the first absorber (2) and then connects the steam bleeding chamber (6) is adjusted to that the concentrated solution pipe of generator (1) passes through the first solution pump (7), the first solution heat exchanger (4), the fourth solution heat exchanger (I3), the third solution heat exchanger (H3) and then connects the first absorber (2) or the concentrated solution pipe of generator (1) passes through the first solution pump (7), the first solution heat exchanger (4), the fourth solution heat exchanger (I3), the third solution heat exchanger (H3), the first absorber (2) and then connects the steam bleeding chamber (6),

wherein that the refrigerant vapor channel of generator (1) connects external can be considered as that the refrigerant vapor channel of generator (1) connects condenser (A3), that the refrigerant vapor channel of the steam bleeding chamber (6) connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber (6) connects condenser (A3), that the refrigerant vapor channel of the first absorber (2) and the second absorber (3) separately connects external can be considered as that the refrigerant vapor channel of two-stage absorption-evaporator (D3) separately connects the first absorber (2) and the second absorber (3) after that evaporator (B3) passes through the second liquid refrigerant pump (J3), the third liquid refrigerant pump (K3) and then connects two-stage absorption-evaporator (D3), the refrigerant vapor channel of the one-level absorption-evaporator (C3) connects two-stage absorption-evaporator (D3) after that the liquid refrigerant pipe of the second liquid refrigerant pump (J3) connects one-level absorption-evaporator (C3),

wherein the liquid refrigerant pipe of condenser (A3) passes through the first liquid refrigerant pump (E3) and then connects evaporator (B3), the evaporator (B3) has the channel of refrigerant vapor which connects one-level absorption-evaporator (C3), the condenser (A3) has the pipe of cooling medium which connects external, and the evaporator (B3) has the pipe of residual heat medium which connects external.

8. The recuperative generation-absorption system, as recited in claim 1 or 2, wherein a recuperative two-generator two-stage second-type absorption heat pump in which the absorption-evaporator (C4) separately provides refrigerant vapor to the first absorber (2), the second absorber (3) and the generator (1) can be formed by adding a condenser (A4), an evaporator (B4), an absorption-evaporator (C4), a first liquid refrigerant pump (D4), a first throttle (E4), a low-temperature generator (F4), a fourth liquid refrigerant pump (G4), a second throttle (H4) and a third solution heat exchanger (I4),

wherein that the dilute solution pipe of the first absorber (2) passes through the first solution heat exchanger (4) and then connects the generator (1) is adjusted to that the dilute solution pipe of the first absorber (2) passes through the first solution heat exchanger (4) and then connects the absorption-evaporator (C4), the dilute solution pipe of the absorption-evaporator (C4) passes through the third solution heat exchanger (I4) and then connects the low-temperature generator (F4), the concentrated solution pipe of the low-temperature generator (F4) passes through the fourth liquid refrigerant pump (G4), the third solution heat exchanger (I4) and then connects the generator (1),

wherein that the refrigerant vapor channel of the first absorber (2), the second absorber (3) connects external can be considered as that the refrigerant vapor channel of the absorption-evaporator (C4) separately connects the first absorber (2) and the second absorber (3) after that the liquid refrigerant pipe of the condenser (A4) passes through the liquid refrigerant pump (D4) and then connects the absorption-evaporator (C4), that the thermal driving medium pipe of the generator (1) connects external can be considered as that the liquid refrigerant pipe of the liquid refrigerant pump (D4) connects the absorption-evaporator (C4), the refrigerant vapor pipe of the absorption-evaporator (C4) connects the generator (1) and the liquid refrigerant pipe of the generator (1) passes through the first throttle (E4) and then connects the condenser (A4), a part of the refrigerant vapor produced by the absorption-evaporator (C4) can be used as thermal driving medium, that the refrigerant vapor channel of the generator (1) connects external can be considered as that the refrigerant vapor channel of the generator (1) connects the condenser (A4), that the refrigerant vapor channel of the steam bleeding chamber (6) connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber (6) connects the condenser (A4), the liquid refrigerant pipe of the liquid refrigerant pump (D4) passes through the second throttle (H4) and then connects the evaporator (B4), the evaporator (B4) has the pipe of residual heat medium which connects external and the channel of refrigerant vapor which connects the absorption-evaporator (C4), the low-temperature generator (F4) has the pipe of residual heat medium which connects external and the channel of refrigerant vapor which connects the condenser (A4).

9. The recuperative generation-absorption system, as recited in claim 1 or 2, wherein a recuperative two-generator two-stage second-type absorption heat pump in which the absorption-evaporator (C4) separately provides refrigerant vapor to the first absorber (2), the second absorber (3) and the generator (1) can be formed by adding a condenser (A4), an evaporator (B4), an absorption-evaporator (C4), a first liquid refrigerant pump (D4), a throttle (E4), a low-temperature generator (F4), a fourth liquid refrigerant pump (G4), a second liquid refrigerant pump (J4) and a third solution heat exchanger (I4),

wherein that the dilute solution pipe of the first absorber (2) passes through the first solution heat exchanger (4) and then connects the generator (1) is adjusted to that the dilute solution pipe of the first absorber (2) passes through the first solution heat exchanger (4) and then connects the absorption-evaporator (C4), the dilute solution pipe of the absorption-evaporator (C4) passes through the third solution heat exchanger (I4) and then connects the low-temperature generator (F4), the concentrated solution pipe of the low-temperature generator (F4) passes through the fourth liquid refrigerant pump (G4), the third solution heat exchanger (I4) and then connects the generator (1),

wherein that the refrigerant vapor channel of the first absorber (2), the second absorber (3) connects external can be considered as that the refrigerant vapor channel of the absorption-evaporator (C4) separately connects the first absorber (2) and the second absorber (3) after that the liquid refrigerant pipe of evaporator (B4) passes through the second liquid refrigerant pump (J4) and then connects the absorption-evaporator (C4), that the thermal driving medium pipe of the generator (1) connects external can be considered as that the liquid refrigerant pipe of the second liquid refrigerant pump (J4) connects the absorption-evaporator (C4), the refrigerant vapor pipe of the absorption-evaporator (C4) connects the generator (1) and the liquid refrigerant pipe of the generator (1) passes through the first throttle (E4) and then connects the condenser (A4), a part of the refrigerant vapor produced by the absorption-evaporator (C4) can be used as thermal driving medium, that the refrigerant vapor channel of the generator (1) connects external can be considered as that the refrigerant vapor channel of the generator (1) connects the condenser (A4), that the refrigerant vapor channel of the steam bleeding chamber (6) connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber (6) connects the condenser (A4), the liquid refrigerant pipe of the condenser (A4) passes through the first liquid refrigerant pump (D4) and then connects the evaporator (B4), the evaporator (B4) has the pipe of residual heat medium which connects external and the channel of refrigerant vapor which connects the absorption-evaporator (C4), the low-temperature generator (F4) has the pipe of residual heat medium which connects external and the channel of refrigerant vapor which connects the condenser (A4).

10. The recuperative generation-absorption system, as recited in claim 1, wherein a recuperative single stage tandem double-effect second-type absorption heat pump can be formed by adding a second generator (A5), a condenser (B5), a first evaporator (C5), a first throttle (D5), a liquid refrigerant pump (E5), a second evaporator (F5), and a second throttle (G5), and taking the second generator (A5) as the high-pressure generator, that the concentrated solution pipe of the first generator (1) passes through the first solution pump (7), the first solution heat exchanger (4), the first absorber (2) and then connects the steam bleeding chamber (6) is adjusted to that the concentrated solution pipe of the first generator (1) passes through the first solution pump (7) and then connects the second generator (A5), the concentrated solution pipe of the second generator (A5) passes through the first solution heat exchanger (4), the first absorber (2) and then connects the steam bleeding chamber (6),

wherein after that the thermal driving medium pipe of the first generator (1) connects external can be considered as that the refrigerant vapor channel of the second generator (A5) connects the first generator (1), the liquid refrigerant pipe of the first generator (1) passes through the first throttle (D5) and then connects the condenser (B5), using the refrigerant vapor produced by the second generator (A5) as the thermal driving medium of the first generator (1), that the refrigerant vapor channel of the first generator (1) connects external can be considered as that the refrigerant vapor channel of the first generator (1) connects condenser (B5),

wherein that the refrigerant vapor channel of the steam bleeding chamber (6) connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber (6) connects the condenser (B5), that the refrigerant vapor channel of the first absorber (2) connects external can be considered as that the refrigerant vapor channel of the second evaporator (F5) connects the first absorber (2), that the refrigerant vapor channel of the second absorber (3) connects external can be considered as that the refrigerant vapor channel of the first evaporator (C5) connects the second absorber (3), the liquid refrigerant pipe of the condenser (B5) passes through the liquid refrigerant pump (E5) and then connects the first evaporator (C5), the liquid refrigerant pipe of the first evaporator (C5) passes through the second throttle (G5) and then connects the second evaporator (F5), the condenser (B5) has the pipe of cooling medium which connects external, the second generator (A5), the first evaporator (C5) and the second evaporator (F5) have the pipe of residual heat medium which separately connects external, when the system hasn't the second evaporator (F5) and the second throttle (G5), the refrigerant vapor channel of the first evaporator (C5) separately connects the first absorber (2) and the second absorber (3).

11. The recuperative generation-absorption system, as recited in claim 2, wherein a recuperative single stage tandem double-effect second-type absorption heat pump can be formed by adding a third solution pump (9), a second generator (A5), a condenser (B5), a first evaporator (C5), a first throttle (D5), a liquid refrigerant pump (E5), a second evaporator (F5) and a second throttle (G5),

wherein taking the second generator (A5) as a high-pressure generator, that the concentrated solution pipe of the first generator (1) passes through the first solution pump (7), the first solution heat exchanger (4) and then connects the first absorber (2) is adjusted to that the concentrated solution pipe of the first generator (1) passes through the first solution pump (7) and then connects the second generator (A5), the concentrated solution pipe of the second generator (A5) passes through the third solution pump (9), the first solution heat exchanger (4) and then connects the first absorber (2),

wherein after that the thermal driving medium pipe of the first generator (1) connects external can be considered as that the refrigerant vapor channel of the second generator (A5) connects the first generator (1), the liquid refrigerant pipe of the first generator (1) passes through the first throttle (D5) and then connects the condenser (B5), using the refrigerant vapor produced by the second generator (A5) as the thermal driving medium of the first generator (1), that the refrigerant vapor channel of the first generator (1) connects external can be considered as that the refrigerant vapor channel of the first generator (1) connects the condenser (B5),

wherein that the refrigerant vapor channel of the steam bleeding chamber (6) connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber (6) connects the condenser (5), that the refrigerant vapor channel of the first absorber (2) connects external can be considered as that the refrigerant vapor channel of the second evaporator (F5) connects the first absorber (2), that the refrigerant vapor channel of the second absorber (3) connects external can be considered as that the refrigerant vapor channel of the first evaporator (C5) connects the second absorber (3), the liquid refrigerant pipe of the condenser (B5) passes through the liquid refrigerant pump (E5) and then connects the first evaporator (C5), the liquid refrigerant pipe of the first evaporator (C5) passes through the second throttle (G5) and then connects the second evaporator (F5), the condenser (B5) has the pipe of cooling medium which connects external, the second generator (A5), the first evaporator (C5) and the second evaporator (F5) have the pipe of residual heat medium which separately connects external, when the system hasn't the second evaporator (F5) and the second throttle (G5), the refrigerant vapor channel of the first evaporator (C5) separately connects the first absorber (2) and the second absorber (3).

12. The recuperative generation-absorption system, as recited in claim 1 or 2, wherein a recuperative single stage tandem double-effect second-type absorption heat pump can be formed by adding a second generator (A5), a condenser (B5), a first evaporator (C5), a first throttle (D5), a liquid refrigerant pump (E5), a second evaporator (F5), a second throttle (G5) and a third solution heat exchanger (H5),

wherein taking the second generator (A5) as a low-pressure generator, that the concentrated solution pipe of the first generator (1) passes through the first solution pump (7), the first solution heat exchanger (4) and then connects the first absorber (2) or the concentrated solution pipe of the first generator (1) passes through the first solution pump (7), the first solution heat exchanger (4), the first absorber (2) and then connects the steam bleeding chamber (6) is adjusted to that the concentrated solution pipe of the first generator (1) passes through the third solution heat exchanger (H5) and then connects the second generator (A5), the concentrated solution pipe of the second generator (A5) passes through the first solution pump (7), the third solution heat exchanger (H5) and the first solution heat exchanger (4) and then connects the first absorber (2), or the concentrated solution pipe of the second generator (A5) passes through the first solution pump (7), the third solution heat exchanger (H5), the first solution heat exchanger (4), the first absorber (2) and then connects the steam bleeding chamber (6),

wherein after that the refrigerant vapor channel of the first generator (1) connects external can be considered as that the refrigerant vapor channel of the first generator (1) connects the second generator (A5), the liquid refrigerant pipe of the second generator (A5) passes through the first throttle (D5) and then connects the condenser (B5), using the refrigerant vapor produced by the first generator (1) as the thermal driving medium of the second generator (A5), the refrigerant vapor channel of the second generator (A5) connects the condenser (B5),

wherein that the refrigerant vapor channel of the steam bleeding chamber (6) connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber (6) connects the condenser (B5), that the refrigerant vapor channel of the first absorber (2) connects external can be considered as that the refrigerant vapor channel of the second evaporator (F5) connects the first absorber (2), that the refrigerant vapor channel of the second absorber (3) connects external can be considered as that the refrigerant vapor channel of the first evaporator (C5) connects the second absorber (3), the liquid refrigerant pipe of the condenser (B5) passes through the liquid refrigerant pump (E5) and then connects the first evaporator (C5), the liquid refrigerant pipe of the first evaporator (C5) passes through the second throttle (G5) and then connects the second evaporator (F5), the condenser (B5) has the pipe of cooling medium which connects external, the first evaporator (C5) and the second evaporator (F5) have the pipe of residual heat medium which separately connects external, when the system hasn't the second evaporator (F5) and the second throttle (G5), the refrigerant vapor channel of the first evaporator (C5) separately connects the first absorber (2) and the second absorber (3).

13. The recuperative generation-absorption system, as recited in claim 1, wherein a recuperative single stage parallel double-effect second-type absorption heat pump can be formed by adding a second generator (A5), a condenser (B5), a first evaporator (C5), a first throttle (D5), a liquid refrigerant pump (E5), a second evaporator (F5), a second throttle (G5) and a third solution heat exchanger (H5),

wherein taking the second generator (A5) as a high-pressure generator, after that the concentrated solution pipe of the second generator (A5) passes through the third solution heat exchanger (H5), it joins with the solution pipe which passes through the first solution pump (7), the first solution heat exchanger (4) from the first generator (1), the dilute solution pipe of the first absorber (2) passes through the third solution heat exchanger (H5) and then connects the second generator (A5),

wherein after that the refrigerant vapor channel of the first generator (1) connects external can be considered as that the refrigerant vapor channel of the second generator (A5) connects the first generator (1), the liquid refrigerant pipe of the first generator (1) passes through the first throttle (D5) and then connects the condenser (B5), using the refrigerant vapor produced by the second generator (A5) as the thermal driving medium of the first generator (1), that the refrigerant vapor channel of the first generator (1) connects external can be considered as that the refrigerant vapor channel of the first generator (1) connects the condenser (B5),

wherein that the refrigerant vapor channel of the steam bleeding chamber (6) connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber (6) connects the condenser (B5), that the refrigerant vapor channel of the first absorber (2) connects external can be considered as that the refrigerant vapor channel of the second evaporator (F5) connects the first absorber (2), that the refrigerant vapor channel of the second absorber (3) connects external can be considered as that the refrigerant vapor channel of the first evaporator (C5) connects the second absorber (3), the liquid refrigerant pipe of the condenser (B5) passes through the liquid refrigerant pump (E5) and then connects the first evaporator (C5), the liquid refrigerant pipe of the first evaporator (C5) passes through the second throttle (G5) and then connects the second evaporator (F5), the condenser (B5) has the pipe of cooling medium which connects external, the second generator (A5), the first evaporator (C5) and the second evaporator (F5) have the pipe of residual heat medium which separately connects external, when the system hasn't the second evaporator (F5) and the second throttle (G5), the refrigerant vapor channel of the first evaporator (C5) separately connects the first absorber (2) and the second absorber (3).

14. The recuperative generation-absorption system, as recited in claim 2, wherein a recuperative single stage parallel double-effect second-type absorption heat pump can be formed by adding a third solution pump (9), a second generator (A5), a condenser (B5), a first evaporator (C5), a first throttle (D5), a liquid refrigerant pump (E5), a second evaporator (F5), a second throttle (G5) and a third solution heat exchanger (H5),

wherein taking the second generator (A5) as a low-pressure generator, the concentrated solution pipe of the second generator (A5) passes through the third solution pump (9), the third solution heat exchanger (H5) and then connects the first absorber (2), the dilute solution pipe of the first absorber (2) passes through the third solution heat exchanger (H5) and then connects the second generator (A5),

wherein after that the refrigerant vapor channel of the first generator (1) connects external can be considered as that the refrigerant vapor channel of the first generator (1) connects the second generator (A5), the liquid refrigerant pipe of the second generator (A5) passes through the first throttle (D5) and then connects the condenser (B5), using the refrigerant vapor produced by the first generator (1) as the thermal driving medium of the second generator (A5), the refrigerant vapor channel of the second generator (A5) connects the condenser (B5),

wherein that the refrigerant vapor channel of the steam bleeding chamber (6) connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber (6) connects the condenser (B5), that the refrigerant vapor channel of the first absorber (2) connects external can be considered as that the refrigerant vapor channel of the second evaporator (F5) connects the first absorber (2), that the refrigerant vapor channel of the second absorber (3) connects external can be considered as that the refrigerant vapor channel of the first evaporator (C5) connects the second absorber (3), the liquid refrigerant pipe of the condenser (B5) passes through the liquid refrigerant pump (E5) and then connects the first evaporator (C5), the liquid refrigerant pipe of the first evaporator (C5) passes through the second throttle (G5) and then connects the second evaporator (F5), the condenser (B5) has the pipe of cooling medium which connects external, the first evaporator (C5) and the second evaporator (F5) have the pipe of residual heat medium which separately connects external, when the system hasn't the second evaporator (F5) and the second throttle (G5), the refrigerant vapor channel of the first evaporator (C5) separately connects the first absorber (2) and the second absorber (3).

15. The recuperative generation-absorption system, as recited in claim 1, wherein a recuperative single stage parallel double-effect second-type absorption heat pump can be formed by adding a second generator (A5), a condenser (B5), a first evaporator (C5), a first throttle (D5), a liquid refrigerant pump (E5), a second evaporator (F5), a second throttle (G5), a third solution heat exchanger (H5) and a fourth solution pump (I5),

wherein taking the second generator (A5) as a low-pressure generator, the concentrated solution pipe of the second generator (A5) passes through the fourth solution pump (I5), the third solution heat exchanger (H5) and then connects the first absorber (2), The dilute solution pipe of the first absorber (2) passes through the third solution heat exchanger (H5) and then connects the second generator (A5),

wherein after that the refrigerant vapor channel of the first generator (1) connects external can be considered as that the refrigerant vapor channel of the first generator (1) connects the second generator (A5), the liquid refrigerant pipe of the second generator (A5) passes through the first throttle (D5) and then connects the condenser (B5), using the refrigerant vapor produced by the first generator (1) as the thermal driving medium of the second generator (A5), the refrigerant vapor channel of the second generator (A5) connects the condenser (B5),

wherein that the refrigerant vapor channel of the steam bleeding chamber (6) connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber (6) connects the condenser (B5), that the refrigerant vapor channel of the first absorber (2) connects external can be considered as that the refrigerant vapor channel of the second evaporator (F5) connects the first absorber (2), that the refrigerant vapor channel of the second absorber (3) connects external can be considered as that the refrigerant vapor channel of the first evaporator (C5) connects the second absorber (3), the liquid refrigerant pipe of the condenser (B5) passes through the liquid refrigerant pump (E5) and then connects the first evaporator (C5), the liquid refrigerant pipe of the first evaporator (C5) passes through the second throttle (G5) and then connects the second evaporator (F5), the condenser (B5) has the pipe of cooling medium which connects external, the first evaporator (C5) and the second evaporator (F5) have the pipe of residual heat medium which separately connects external, when the system hasn't the second evaporator (F5) and the second throttle (G5), the refrigerant vapor channel of the first evaporator (C5) separately connects the first absorber (2) and the second absorber (3).

16. The recuperative generation-absorption system, as recited in claim 1, wherein a recuperative single stage parallel double-effect second-type absorption heat pump can be formed by adding a second generator (A5), a condenser (B5), a first evaporator (C5), a first throttle (D5), a liquid refrigerant pump (E5), a second evaporator (F5), a second throttle (G5), a third solution heat exchanger (H5) and a fourth solution pump (I5),

where taking the second generator (A5) as a high-pressure generator, the concentrated solution pipe of the second generator (A5) passes through the fourth solution pump (I5), the third solution heat exchanger (H5) and then connects the first absorber (2), the dilute solution pipe of the first absorber (2) passes through the third solution heat exchanger (H5) and then connects the second generator (A5),

wherein after that the thermal driving medium channel of the first generator (1) connects external can be considered as that the refrigerant vapor channel of the second generator (A5) connects the first generator (1), the liquid refrigerant pipe of the first generator (1) passes through the first throttle (D5) and then connects the condenser (B5), using the refrigerant vapor produced by the second generator (A5) as the thermal driving medium of the first generator (1), that the refrigerant vapor channel of the first generator (1) connects external can be considered as that the refrigerant vapor channel of the first generator (1) connects the condenser (B5),

wherein that the refrigerant vapor channel of the steam bleeding chamber (6) connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber connects the condenser (B5), that the refrigerant vapor channel of the first absorber (2) connects external can be considered as that the refrigerant vapor channel of the second evaporator (F5) connects the first absorber (2), that the refrigerant vapor channel of the second absorber (3) connects external can be considered as that the refrigerant vapor channel of the first evaporator (C5) connects the second absorber (3), the liquid refrigerant pipe of the condenser (B5) passes through the liquid refrigerant pump (E5) and then connects the first evaporator (C5), the liquid refrigerant pipe of the first evaporator (C5) passes through the second throttle (G5) and then connects the second evaporator (F5), the condenser (B5) has the pipe of cooling medium which connects external, the second generator (A5), the first evaporator (C5) and the second evaporator (F5) have the pipe of residual heat medium which separately connects external. When the system hasn't the second evaporator (F5) and the second throttle (G5), the refrigerant vapor channel of the first evaporator (C5) separately connects the first absorber (2) and the second absorber (3).

17. The recuperative generation-absorption system, as recited in claim 1, wherein a recuperative single stage tandem triple effect second-type absorption heat pump can be formed by adding a second generator (A6), a third generator (B6), a condenser (C6), a first evaporator (D6), a fourth solution pump (E6), a first throttle (F6), a second throttle (G6), a liquid refrigerant pump (H6), a second evaporator (I6) and a third throttle (J6),

wherein that the concentrated solution pipe of the first generator (1) passes through the first solution pump (7), the first solution heat exchanger (4), the first absorber (2) and then connects the steam bleeding chamber (6) is adjusted to that the concentrated solution pipe of the first generator (1) passes through the first solution pump (7) and then connects the third generator (B6), the concentrated solution pipe of the third generator (B6) passes through the fourth solution pump (E6) and then connects the second generator (A6), the concentrated solution pipe of the second generator (A6) passes through the first solution heat exchanger (4), the first absorber (2) and then connects the steam bleeding chamber (6),

wherein after that the thermal driving medium channel of the first generator (1) connects external can be considered as that the refrigerant vapor channel of the third generator (B6) connects the first generator (1), the liquid refrigerant pipe of the first generator (1) passes through the second throttle (G6) and then connects the condenser (C6), using the refrigerant vapor produced by the third generator (B6) as the thermal driving medium of the first generator (1), the liquid refrigerant pipe of the third generator (B6) passes through the first throttle (F6) and then connects the condenser (C6) after that the refrigerant vapor channel of the second generator (A6) connects the third generator (B6),

wherein using the refrigerant vapor produced by the second generator (A6) as the thermal driving medium of the third generator (B6), that the refrigerant vapor channel of the first generator (1) connects external can be considered as that the refrigerant vapor channel of the first generator (1) connects the condenser (C6), that the refrigerant vapor channel of the first absorber (2) connects external can be considered as that the refrigerant vapor channel of the second evaporator (I6) connects the first absorber (2), that the refrigerant vapor channel of the second absorber (3) connects external can be considered as that the refrigerant vapor channel of the first evaporator (D6) connects the second absorber (3),

wherein the liquid refrigerant pipe of the condenser (C6) passes through the liquid refrigerant pump (H6) and then connects the first evaporator (D6), the liquid refrigerant pipe of the first evaporator (D6) passes through the third throttle (J6) and then connects the second evaporator (I6), the condenser (C6) has the pipe of cooling medium which connects external, the second generator (A6), the first evaporator (D6) and the second evaporator (I6) has the pipe of residual heat medium which separately connects external, when the system hasn't the second evaporator (I6) and the third throttle (J6), the refrigerant vapor channel of the first evaporator (D6) separately connects the first absorber (2) and the second absorber (3).

18. The recuperative generation-absorption system, as recited in claim 2, wherein a recuperative single stage tandem triple effect second-type absorption heat pump can be formed by adding a third solution pump (9), a second generator (A6), a third generator (B6), a condenser (C6), a first evaporator (D6), a fourth solution pump (E6), a first throttle (F6), a second throttle (G6), a liquid refrigerant pump (H6), a second evaporator (I6), and a third throttle (J6),

wherein that the concentrated solution pipe of the first generator (1) passes through the first solution pump (7), the first solution heat exchanger (4) and then connects the first absorber (2) is adjusted to that the concentrated solution pipe of the first generator (1) passes through the first solution pump (7) and then connects the third generator (B6), the concentrated solution pipe of the third generator (B6) passes through the fourth solution pump (E6) and then connects the second generator (A6), the concentrated solution pipe of the second generator (A6) passes through the third solution pump (9), the first solution heat exchanger (4) and then connects the first absorber (2),

wherein after that the thermal driving medium channel of the first generator (1) connects external can be considered as that the refrigerant vapor channel of the third generator (B6) connects the first generator (1), the liquid refrigerant pipe of the first generator (1) passes through the second throttle (G6) and then connects the condenser (C6), using the refrigerant vapor produced by the third generator (B6) as the thermal driving medium of the first generator (1), the liquid refrigerant pipe of the third generator (B6) passes through the first throttle (F6) and then connects the condenser (C6) after that the refrigerant vapor channel of the second generator (A6) connects the third generator (B6),

wherein using the refrigerant vapor produced by the second generator (A6) as the thermal driving medium of the third generator (B6), that the refrigerant vapor channel of the first generator (1) connects external can be considered as that the refrigerant vapor channel of the first generator (1) connects the condenser (C6), that the refrigerant vapor channel of the first absorber (2) connects external can be considered as that the refrigerant vapor channel of the second evaporator (I6) connects the first absorber (2), that the refrigerant vapor channel of the second absorber (3) connects external can be considered as that the refrigerant vapor channel of the first evaporator (D6) connects the second absorber (3), that the refrigerant vapor channel of the steam bleeding chamber (6) connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber (6) connects the condenser (C6),

wherein the liquid refrigerant pipe of the condenser (C6) passes through the liquid refrigerant pump (H6) and then connects the first evaporator (D6), the liquid refrigerant pipe of the first evaporator (D6) passes through the third throttle (J6) and then connects the second evaporator (I6), the condenser (C6) has the pipe of cooling medium which connects external, the second generator (A6), the first evaporator (D6) and the second evaporator (I6) have the pipe of residual heat medium which separately connects external, when the system hasn't the second evaporator (I6) and the third throttle (J6), the refrigerant vapor channel of the first evaporator (D6) separately connects the first absorber (2) and the second absorber (3).

19. The recuperative generation-absorption system, as recited in claim 1 or 2, wherein a recuperative single stage tandem triple effect second-type absorption heat pump can be formed by adding a second generator (A6), a third generator (B6), a condenser (C6), a first evaporator (D6), a first throttle (F6), a second throttle (G6), a liquid refrigerant pump (H6), a second evaporator (I6), a third throttle (J6), a third solution heat exchanger (K6), and a fourth solution heat exchanger (L6),

wherein that the concentrated solution pipe of the first generator (1) passes through the first solution pump (7), the first solution heat exchanger (4) and then connects the first absorber (2) or the concentrated solution pipe of the first generator (1) passes through the first solution pump (7), the first solution heat exchanger (4), the first absorber (2) and then connects the steam bleeding chamber (6) is adjusted to that the concentrated solution pipe of the first generator (1) passes through the third solution heat exchanger (K6) and then connects the second generator (A6), the concentrated solution pipe of the second generator (A6) passes through the fourth solution heat exchanger (L6) and then connects the third generator (B6), the concentrated solution pipe of the third generator (B6) passes through the first solution pump (7), the fourth solution heat exchanger (L6), the third solution heat exchanger (K6), the first solution heat exchanger (4) and then connects the first absorber (2) or the concentrated solution pipe of the third generator (B6) passes through the first solution pump (7), the fourth solution heat exchanger (L6), the third solution heat exchanger (K6), the first solution heat exchanger (4), the first absorber (2) and then connects the steam bleeding chamber (6),

wherein after that the refrigerant vapor channel of the first generator (1) connects external can be considered as that the refrigerant vapor channel of the first generator (1) connects the second generator (A6), the liquid refrigerant pipe of the second generator (A6) passes through the first throttle (F6) and then connects the condenser (C6),

wherein using the refrigerant vapor produced by the first generator (1) as the thermal driving medium of the second generator (A6), that the liquid refrigerant channel of the third generator (B6) passes through the second throttle (G6) and then connects the condenser (C6) after that the refrigerant vapor channel of the second generator (A6) connects the third generator (B6), using the refrigerant vapor produced by the second generator (A6) as the thermal driving medium of the third generator (B6), the refrigerant vapor channel of the third generator (B6) connects the condenser (C6),

wherein that the refrigerant vapor channel of the first absorber (2) connects external can be considered as that the refrigerant vapor channel of the second evaporator (I6) connects the first absorber (2), that the refrigerant vapor channel of the second absorber (3) connects external can be considered as that the refrigerant vapor channel of the first evaporator (D6) connects the second absorber (3), that the refrigerant vapor channel of the steam bleeding chamber (6) connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber (6) connects the condenser (C6),

wherein the liquid refrigerant pipe of the condenser (C6) passes through the liquid refrigerant pump (H6) and then connects the first evaporator (D6), the liquid refrigerant pipe of the first evaporator (D6) passes through the third throttle (J6) and then connects the second evaporator (I6), the condenser (C6) has the pipe of cooling medium which connects external, the first evaporator (D6) and the second evaporator (I6) have the pipe of residual heat medium which separately connects external, when the system hasn't the second evaporator (I6) and the third throttle (J6), the refrigerant vapor channel of the first evaporator (D6) separately connects the first absorber (2) and the second absorber (3).

20. The recuperative generation-absorption system, as recited in claim 2, wherein a recuperative single stage parallel triple effect second-type absorption heat pump can be formed by adding a second generator (A6), a third generator (B6), a condenser (C6), a first evaporator (D6), a third solution pump (9), a fourth solution pump (E6), a first throttle (F6), a second throttle (G6), a liquid refrigerant pump (H6), a second evaporator (I6), a third throttle (J6), a third solution heat exchanger (K6), and a fourth solution heat exchanger (L6),

wherein taking the second generator (A6) as a medium voltage generator and using the third generator (B6) as a low-pressure generator, the concentrated solution pipe of the second generator (A6) passes through the third solution pump (9), the third solution heat exchanger (K6) and then connects the first absorber (2), the dilute solution pipe of the first absorber (2) passes through the third solution heat exchanger (K6) and then connects the second generator (A6), the concentrated solution pipe of the third generator (B6) passes through the fourth solution pump (E6), the fourth solution heat exchanger (L6) and then connects the first absorber (2), the dilute solution pipe of the first absorber (2) passes through the fourth solution heat exchanger (L6) and then connects the third generator (B6), that the refrigerant vapor channel of the first generator (1) connects external can be considered as that the liquid refrigerant pipe of the second generator (A6) passes through the first throttle (F6) and then connects the condenser (C6) after that the refrigerant vapor channel of the first generator (1) connects the second generator (A6),

wherein using the refrigerant vapor produced by the first generator (1) as the thermal driving medium of the second generator (A6), the liquid refrigerant pipe of the third generator (B6) passes through the second throttle (G6) and then connects the condenser (C6) after that the refrigerant vapor channel of the second generator (A6) connects the third generator (B6), using the refrigerant vapor produced by the second generator (A6) as the thermal driving medium of the third generator (B6), the refrigerant vapor channel of the third generator (B6) connects the condenser (C6),

wherein that the refrigerant vapor channel of the first absorber (2) connects external can be considered as that the refrigerant vapor channel of the second evaporator (I6) connects the first absorber (2), that the refrigerant vapor channel of the second absorber (3) connects external can be considered as that the refrigerant vapor channel of the first evaporator (D6) connects the second absorber (3), that the refrigerant vapor channel of the steam bleeding chamber (6) connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber (6) connects the condenser (C6),

wherein the liquid refrigerant pipe of the condenser (C6) passes through the liquid refrigerant pump (H6) and then connects the first evaporator (D6), the liquid refrigerant pipe of the first evaporator (D6) passes through the third throttle (J6) and then connects the second evaporator (I6), the condenser (C6) has the pipe of cooling medium which connects external, the first evaporator (D6) and the second evaporator (I6) have the pipe of residual heat medium which separately connects external, when the system hasn't the second evaporator (I6) and the third throttle (J6), the refrigerant vapor channel of the first evaporator (D6) separately connects the first absorber (2) and the second absorber (3).

21. The recuperative generation-absorption system, as recited in claim 1, wherein a recuperative single stage parallel triple effect second-type absorption heat pump can be formed by adding a second generator (A6), a third generator (B6), a condenser (C6), a first evaporator (D6), a first throttle (F6), a second throttle (G6), a liquid refrigerant pump (H6), a second evaporator (I6), a third throttle (J6), a third solution heat exchanger (K6), and a fourth solution heat exchanger (L6),

wherein taking the second generator (A6) as a high-pressure generator and using the third generator (B6) as a medium voltage generator, the concentrated solution pipe of the second generator (A6) which passes through the third solution heat exchanger (K6) and the concentrated solution pipe of the third generator (B6) which passes through the fourth solution heat exchanger (L6) all join with the solution pipe which passes through the first solution pump (7), the first solution heat exchanger (4) from the first generator (1), the dilute solution pipe of the first absorber (2) passes through the third solution heat exchanger (K6) and then connects the second generator (A6), the dilute solution pipe of the first absorber (1) passes through the fourth solution heat exchanger (L6) and then connects the third generator (B6),

wherein that the refrigerant vapor channel of the first generator (1) connects external can be considered as that the liquid refrigerant pipe of the first generator (1) passes through the second throttle (G6) and then connects the condenser (C6) after that the refrigerant vapor channel of the third generator (B6) connects the first generator (1),

wherein using the refrigerant vapor produced by the third generator (B6) as the thermal driving medium of the first generator (1), the liquid refrigerant pipe of the third generator (B6) passes through the first throttle (F6) and then connects the condenser (C6) after that the refrigerant vapor channel of the second generator (A6) connects the third generator (B6), using the refrigerant vapor produced by the second generator (A6) as the thermal driving medium of the third generator (B6), that the refrigerant vapor channel of the first generator (1) connects external can be considered as that the refrigerant vapor channel of the first generator (1) connects the condenser (C6),

wherein that the refrigerant vapor channel of the first absorber (2) connects external can be considered as that the refrigerant vapor channel of the second evaporator (I6) connects the first absorber (2), that the refrigerant vapor channel of the second absorber (3) connects external can be considered as that the refrigerant vapor channel of the first evaporator (D6) connects the second absorber (3), that the refrigerant vapor channel of the steam bleeding chamber (6) connects external can be considered as that the refrigerant vapor channel of the steam bleeding chamber (6) connects the condenser (C6),

wherein the liquid refrigerant pipe of the condenser (C6) passes through the liquid refrigerant pump (H6) and then connects the first evaporator (D6), the liquid refrigerant pipe of the first evaporator (D6) passes through the third throttle (J6) and then connects the second evaporator (I6), the condenser (C6) has the pipe of cooling medium which connects external, the second generator (A6), the first evaporator (D6) and the second evaporator (I6) have the pipe of residual heat medium which separately connects external, when the system hasn't the second evaporator (I6) and the third throttle (J6), the refrigerant vapor channel of the first evaporator (D6) separately connects the first absorber (2) and the second absorber (3).

22. The recuperative generation-absorption system, as recited in any one of claim 3, and 10 to 21, wherein a recuperative second-type absorption heat pump with high-temperature heating-side can be formed by adding a new added absorption-evaporator (a), a new added absorber (b), a new added liquid refrigerant pump (e), a new added first solution heat exchanger (c) and a new added second solution heat exchanger (d),

wherein the concentrated solution pipe added by the second solution pump passes through the new added second solution heat exchanger (d), the new added first solution heat exchanger (c) and then connects the new added absorber (b), the dilute solution pipe of the new added absorber (b) passes through the new added first solution heat exchanger (c) and then connects the new added absorption-evaporator (a), the dilute solution pipe of the new added absorption-evaporator (a) passes through the new added second solution heat exchanger (d) and then joins with the solution pipe which hasn't passed through the first absorber,

wherein after that the liquid refrigerant pipe added by the first evaporator passes through the new added liquid refrigerant pump (e) and then connect the new added absorption-evaporator (a), the refrigerant vapor channel of the new added absorption-evaporator (a) connects the new added absorber (b), the refrigerant vapor channel added by the first evaporator connects the new added absorption-evaporator (a), the new added absorber (b) has the pipe of heated medium which connects external, the solution of the steam bleeding chamber which flows through the second solution pump, the new added second solution heat exchanger (d) and the new added first solution heat exchanger (c) is provided to the new added absorber (b), at the same time, the solution of the new added absorber (b) absorbs the refrigerant vapor coming from the new added absorption-evaporator (a) and releases heat to the heated medium,

wherein the dilute solution of the new added absorber (b) flows through the new added first solution heat exchanger (c) and enters the new added absorption-evaporator (a), at the same time, the solution of the new added absorption-evaporator (a) absorbs the refrigerant vapor coming from the first evaporator and releases heat to another way of the liquid refrigerant which flows through the new added absorption-evaporator (a) too, the liquid refrigerant becomes refrigerant vapor which is provided to the new added absorber (b),

wherein after that the dilute solution of the new added absorption-evaporator (a) flows through the new added second solution heat exchanger (d), it joins with the dilute solution which haven't flowed into the first absorber, then the dilute solution absorbs heat from the first absorber and then enters the steam bleeding chamber, the new added absorber (b) turns into adjacent high-temperature heating-side of the second absorber.

23. The recuperative generation-absorption system, as recited in any one of claim 3, and 10 to 21, wherein a recuperative second-type absorption heat pump with high-temperature heating-side can be formed by adding a new added absorption-evaporator (a), a new added absorber (b), a new added throttle (f), a new added first solution heat exchanger (c) and a new added second solution heat exchanger (d),

wherein the concentrated solution pipe added by the second solution pump passes through the new added second solution heat exchanger (d), the new added first solution heat exchanger (c) and then connects the new added absorber (b), the dilute solution pipe of the new added absorber (b) passes through the new added first solution heat exchanger (c) and then connects the new added absorption-evaporator (a), the dilute solution pipe of the new added absorption-evaporator (a) passes through the new added second solution heat exchanger (d) and then joins with the solution pipe which hasn't passed through the first absorber,

wherein after that the liquid refrigerant pipe added by the condenser connects the new added absorption-evaporator (a), the refrigerant vapor channel of the new added absorption-evaporator (a) connects the new added absorber (b),

wherein at the same time, that the condenser which passes through the liquid refrigerant pump directly connects the first generator is adjusted to that condenser which passes through liquid refrigerant pump and the new added throttle (f) connects the first generator, the refrigerant vapor channel added by the first evaporator connects the new added absorption-evaporator (a), the new added absorber (b) has the pipe of heated medium which connects external, the solution of the steam bleeding chamber which flows through the second solution pump, the new added second solution heat exchanger (d) and the new added first solution heat exchanger (c) is provided to the new added absorber (b), at the same time, the solution of the new added absorber (b) absorbs the refrigerant vapor coming from the new added absorption-evaporator (a) and releases heat to the heated medium,

wherein the dilute solution of the new added absorber (b) flows through the new added first solution heat exchanger (c) and enters the new added absorption-evaporator (a), at the same time, the solution of the new added absorption-evaporator (a) absorbs the refrigerant vapor coming from the first evaporator and releases heat to another way of the liquid refrigerant which flows through the new added absorption-evaporator (a) too, the liquid refrigerant becomes refrigerant vapor which is provided to the new added absorber (b),

wherein after that the dilute solution of the new added absorption-evaporator (a) flows through the new added second solution heat exchanger (d), it joins with the dilute solution which haven't flowed into the first absorber, then the dilute solution absorbs heat from the first absorber and then enters the steam bleeding chamber, the new added absorber (b) turns into an adjacent high-temperature heating-side of the second absorber.

24. The recuperative generation-absorption system, as recited in claim 4 or 5, wherein a recuperative second-type absorption heat pump with high-temperature heating-side can be formed by adding a new added absorption-evaporator (a), a new added absorber (b), a new added liquid refrigerant pump (e), a new added first solution heat exchanger (c) and a new added second solution heat exchanger (d),

wherein the concentrated solution pipe added by the second solution pump passes through the new added second solution heat exchanger (d), the new added first solution heat exchanger (c) and then connects the new added absorber (b), the dilute solution pipe of the new added absorber (b) passes through the new added first solution heat exchanger (c) and then connects the new added absorption-evaporator (a), the dilute solution pipe of the new added absorption-evaporator (a) passes through the new added second solution heat exchanger (d) and then joins with the solution pipe which hasn't passed through the first absorber,

wherein after that the liquid refrigerant pipe of the first liquid refrigerant pump which passes through the new added liquid refrigerant pump (e) connects the new added absorption-evaporator (a), the refrigerant vapor channel of the new added absorption-evaporator (a) connects the new added absorber (b), the refrigerant vapor channel added by absorption-evaporator connects the new added absorption-evaporator (a), the new added absorber (b) has the pipe of heated medium which connects external, the solution of the steam bleeding chamber which flows through the second solution pump, the new added second solution heat exchanger (d) and the new added first solution heat exchanger (c) is provided to the new added absorber (b), at the same time, the solution of the new added absorber (b) absorbs the refrigerant vapor coming from the new added absorption-evaporator (a) and releases heat to the heated medium,

wherein the dilute solution of the new added absorber (b) flows through the new added first solution heat exchanger (c) and enters the new added absorption-evaporator (a), at the same time, the solution of the new added absorption-evaporator (a) absorbs the refrigerant vapor coming from the absorption-evaporator and releases heat to another way of the liquid refrigerant which flows through the new added absorption-evaporator (a) too, the liquid refrigerant becomes refrigerant vapor which is provided to the new added absorber (b),

wherein after that the dilute solution of the new added absorption-evaporator (a) flows through the new added second solution heat exchanger, it joins with the dilute solution which haven't flowed into the first absorber, then the dilute solution absorbs heat from the first absorber and then enters the steam bleeding chamber, the new added absorber (b) turns into an adjacent high-temperature heating-side of the second absorber.

25. The recuperative generation-absorption system, as recited in claim 6 or 7, wherein a recuperative second-type absorption heat pump with high-temperature heating-side can be formed by adding a new added absorption-evaporator (a), a new added absorber (b), a new added liquid refrigerant pump (e), a new added first solution heat exchanger (c) and a new added second solution heat exchanger (d),

wherein the concentrated solution pipe added by the second solution pump passes through the new added second solution heat exchanger (d), the new added first solution heat exchanger (c) and then connects the new added absorber (b), the dilute solution pipe of the new added absorber (b) passes through the new added first solution heat exchanger (c) and then connects the new added absorption-evaporator (a), the dilute solution pipe of the new added absorption-evaporator (a) passes through the new added second solution heat exchanger (d) and then joins with the solution pipe which hasn't passed through the first absorber,

wherein after that the liquid refrigerant pipe of the first liquid refrigerant pump which passes through the new added liquid refrigerant pump (e) connects the new added absorption-evaporator (a), the refrigerant vapor channel of the new added absorption-evaporator (a) connects the new added absorber (b), the refrigerant vapor channel added by two-stage absorption-evaporator connects the new added absorption-evaporator (a), the new added absorber (b) has the pipe of heated medium which connects external, the solution of the steam bleeding chamber which flows through the second solution pump, the new added second solution heat exchanger (d) and the new added first solution heat exchanger (c) is provided to the new added absorber (b), at the same time, the solution of the new added absorber (b) absorbs the refrigerant vapor coming from the new added absorption-evaporator (a) and releases heat to the heated medium,

wherein the dilute solution of the new added absorber (b) flows through the new added first solution heat exchanger (c) and enters the new added absorption-evaporator (a), at the same time, the solution of the new added absorption-evaporator (a) absorbs the refrigerant vapor coming from the first two-stage absorption-evaporator and releases heat to another way of the liquid refrigerant which flows through the new added absorption-evaporator (a) too, the liquid refrigerant becomes refrigerant vapor which is provided to the new added absorber (b),

wherein after that the dilute solution of the new added absorption-evaporator (a) flows through the new added second solution heat exchanger (d), it joins with the dilute solution which haven't flowed into the first absorber, then the dilute solution absorbs heat from the first absorber and then enters the steam bleeding chamber, the new added absorber (b) turns into an adjacent high-temperature heating-side of the second absorber.

26. The recuperative generation-absorption system, as recited in claim 8 or 9, wherein a recuperative second-type absorption heat pump with high-temperature heating-side can be formed by adding a new added absorption-evaporator (a), a new added absorber (b), a new added liquid refrigerant pump (e), a new added first solution heat exchanger (c) and a new added second solution heat exchanger (d),

wherein the concentrated solution pipe added by the second solution pump passes through the new added second solution heat exchanger (d), the new added first solution heat exchanger (c) and then connects the new added absorber (b), the dilute solution pipe of the new added absorber (b) passes through the new added first solution heat exchanger (c) and then connects the new added absorption-evaporator (a), the dilute solution pipe of the new added absorption-evaporator (a) passes through the new added second solution heat exchanger (d) and then joins with the solution pipe which hasn't passed through the first absorber,

wherein after that the liquid refrigerant pipe of the first liquid refrigerant pump which passes through the new added liquid refrigerant pump connects the new added absorption-evaporator (a), the refrigerant vapor channel of the new added absorption-evaporator (a) connects the new added absorber (b), \the refrigerant vapor channel added by absorption-evaporator connects the new added absorption-evaporator (a), the new added absorber (b) has the pipe of heated medium which connects external, the solution of the steam bleeding chamber which flows through the second solution pump, the new added second solution heat exchanger (d) and the new added first solution heat exchanger (c) is provided to the new added absorber (b), at the same time, the solution of the new added absorber (b) absorbs the refrigerant vapor coming from the new added absorption-evaporator (a) and releases heat to the heated medium,

wherein the dilute solution of the new added absorber (b) flows through the new added first solution heat exchanger (c) and enters the new added absorption-evaporator (a), at the same time, the solution of the new added absorption-evaporator (a) absorbs the refrigerant vapor coming from absorption-evaporator and releases heat to another way of the liquid refrigerant which flows through the new added absorption-evaporator (a) too, the liquid refrigerant becomes refrigerant vapor which is provided to the new added absorber (b),

wherein after that the dilute solution of the new added absorption-evaporator (a) flows through the new added second solution heat exchanger (d), it joins with the dilute solution which haven't flowed into the first absorber, then the dilute solution absorbs heat from the first absorber and then enters the steam bleeding chamber, the new added absorber (b) turns into an adjacent high-temperature heating-side of the second absorber.