EXPANDER LUBRICATION IN VAPOUR POWER SYSTEMS

Abstract

A vapour power generating system including a closed circuit for a working fluid, and includes a heat exchanger assembly for heating the fluid under pressure with heat from the source, a separator for separating the vapour phase of the heated fluid from the liquid phase thereof, an expander for expanding the vapour to generate power, a condenser for condensing the outlet fluid from the expander, a feed pump for returning condensed fluid from the condenser to the heater and a return path for returning the liquid phase from the separator to the heater. The liquid phase of the working fluid contains a lubricant which lubricant is soluble or miscible in the liquid phase and a bearing supply path is arranged to deliver liquid phase pressurised by the feed pump to at least one bearing for a rotary element of the expander.

Description

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. application Ser. No. 11/921,836, filed Mar. 24, 2009, which is the national stage of International Application No. PCT/GB2006/002148, filed Jun. 9, 2006, which claims the benefit of GB0526413.0, filed Dec. 23, 2005, and GB0511864.1, filed Jun. 10, 2005, all of the above referenced disclosures are hereby incorporated by reference in their entireties.

This invention relates to the lubrication of expanders used in closed-circuit vapour power generating systems in which lubricant is soluble in, or miscible with, the working fluid. The invention is particularly, but not exclusively, concerned with systems for generating power from moderate or low grade heat sources such as geothermal brines, industrial waste heat sources and internal combustion engine waste heat streams where the maximum temperature for the working fluid of the system is rarely in excess of 150° C. Such systems typically use organic working fluids such as tetrafluroethane, chlorotetrafluoroethane 1.1.1.3.3-Pentafluoropropane or light hydrocarbons such as isoButane, n-Butane, isoPentane, and n-Pentane and operate on the Rankine cycle or some variant of it.

According to one aspect of the invention there is provided a vapour power generating system for generating power by using heat from a source of moderate or low grade heat, comprising a closed circuit for a working fluid, the system including heating means for heating the fluid under pressure at a temperature not usually more than 200° C. with heat from the source, a separator for separating the vapour phase of the fluid from the liquid phase thereof, an expander for expanding the vapour to generate power, a condenser for condensing the outlet fluid from the expander. feed pump means for returning condensed fluid from the condenser to the heater and a return path for returning liquid phase from the separator to the heater, wherein the liquid phase contains a lubricant for the bearing which lubricant is soluble or miscible in the liquid phase and a bearing supply path is arranged to deliver liquid phase pressurised by the feed pump means to at least one bearing for a rotary element of the expander. The condenser may also initially desuperheat the vapour from the expander.

With this system the lubricant is dissolved or emulsified with the liquid phase of the working fluid and a proportion of the liquid phase leaving the separator is fed along the bearing supply path to the bearing where heat generated in the bearing evaporates the working fluid, leaving sufficiently concentrated lubricant in the bearing to provide adequate lubrication of the bearing. Preferably, collection spaces are provided around and below the bearing. Lubricant leaving the bearing and entering the expander travels to the condenser with the working fluid exhaust from the expander. The lubricant again mixes with, or dissolves in, the liquid phase formed in the condenser and returns, via the feed pump, to the heater. Build-up or deposit of lubricant in the evaporator section of the heater, which would reduce its efficiency, is prevented by its retention in the liquid recirculating through the evaporator section and partially drawn off to flow through the expander, condenser and feed pump. Advantageously, each bearing supporting the rotary element or elements of the expander is lubricated in this manner. The total mass of lubricant required is not more than 5% of the mass of working fluid. Typically 0.5% to 2% is sufficient.

The expander may be a rotary expander. The expander may for example be a turbine of the radial-inflow or axial flow type. Particularly where power outputs up to about 3 MW are required, the expander may be of the twin-screw type. Where the twin-screw type expander is of the lubricated rotor type, the lubricant will be an appropriate oil and some of the mixture of oil and liquid from the separator will be fed into the expander, typically through the normal lubrication port provided for lubricated rotor twin-screw machines or a similar port nearer the high pressure port.

According to another aspect of the invention there is provided a vapour power generating system for generating power by using heat from a source of heat, comprising a closed circuit for a working fluid, the system including heating means for heating the fluid under pressure with heat from the source to generate vapour, a plural screw expander for expanding the vapour to generate power, a condenser for condensing the outlet fluid from the expander and feed pump means for returning condensed fluid from the condenser to the heater wherein a bearing supply path is arranged to deliver liquid phase pressurised by the feed pump means to at least one bearing for a rotary element of the expander, and the liquid phase delivered to the at least one bearing contains a lubricant for the expander which lubricant is soluble or miscible in the liquid phase.

In embodiments of the invention the liquid phase may be delivered from an intermediate point of the heater.

The invention will now be further described by way of example with reference to the drawings in which:

FIG. 1 is a circuit diagram of a vapour power generating system according to the invention,

FIG. 2 is a circuit diagram similar to FIG. 1 but incorporating a modification,

FIG. 3 is a sectional view through the rotor axes of a twin screw expander suitable for use in the circuit of FIG. 1 or 2,

FIG. 4 is a longitudinal section on the line IV-IV of FIG. 3,

FIG. 5 is a diagram showing the vertical disposition of components of a system similar to those shown in FIGS. 1 and 2, and

FIG. 6 is a circuit diagram of an alternative embodiment of the invention using a single pass boiler.

The Organic Rankine Cycle system shown in FIG. 1 defines a closed circuit for an organic working fluid having a boiling point at atmospheric pressure below 100° C. Up to 5% (usually between 0.5 and 2%) by weight of a compatible natural or synthetic lubricating oil is added to the fluid.

The circuit comprises a heat exchanger assembly 1 for heating the working fluid in counterflow heat exchange with a hot liquid such as geothermal brine or waste from an industrial source at a temperature up to about 150° C.

The heat exchanger assembly 1 defines a path 2 for the hot fluid from the source, the path 2 extending from an inlet 3 to an outlet 4. The assembly also defines a path, extending in counterflow heat exchange with the path 2, through a heater section 5, for heating liquid working fluid, and an evaporator section 6 for evaporating at least some of the working fluid.

A line 7 leads from the outlet of the evaporator 6 to a separator 8, at a higher level than the heater section 5, for separating the vapour component of the evaporator output from the liquid component. Lines 9 and 10 serve to return the hot liquid component to the junction 11 between the heater and evaporator sections 5 and 6.

A line 12 connects the vapour output of the separator 8 to the inlet 13 of a twinscrew expander 14 for expanding the vapour to a lower pressure and thereby generating power to drive an external load such as an electrical generator G.

A line 15 leads from the exhaust outlet 16 of the expander to a condenser 17 for condensing the expanded vapour in heat exchange with a cooling fluid flowing through a circuit 18.

A line 19 connects the liquid outlet of the condenser to a feed pump F for returning the liquid to the heater under pressure through a line 20. To lubricate and cool the bearings of the expander 14, a line 21 leads from the junction 22 of the lines 9 and 10 to inlets 27, 28 in bearing housings 23, 24 containing bearings for the rotating elements of the expander.

The bearing housings 23, 24 provide sufficient space around the bearings for the oil content of the liquid working fluid to be concentrated as the working liquid evaporates into the expander as a result of heat generated in the bearings. Since much of the working fluid leaves the separator 8 as vapour, and thus free of this oil, the oil content in the lines 9, 10 and 21 will already be increased. As oil leaves the bearings and flows into the expander, it is constantly replaced by further oil from the line 21. The oil leaves the expander outlet 16 with the vapour and dissolves into the liquid condensed in the condenser 17.

Since the separator 8 is higher than the heater section 5 (and preferably higher than the evaporator 6), and since the column of liquid in the line 9 is denser than the column of fluid in the evaporator 6 and line 7, there will be continuous circulation through the evaporator section.

Similarly, the feed pump F ensures continuous circulation through the heater section 5. By tapping off the flow from the junction 22 to the bearings, a continuous circulation occurs through the heater section, bearings, condenser and feed pump so that an accumulation of oil on the surfaces of the heater and evaporator sections, which would lower their efficiencies, is prevented.

Where the expander is of the lubricated-rotor type, the line 21 may also be connected, by a line 25, to the normal oil-supply port 26 of the expander.

The circuit shown in FIG. 2 differs from that shown in FIG. 1 in that the lubricant-containing liquid tapped off from the junction 11 is cooled, for example from 80° C. to 35° C., in a heat-exchanger 30, in counterflow with the liquid delivered by the feed pump F to the inlet of the heater section 5. Thus, the outlet of the feed pump F is connected by a line 31 to the inlet of a pre-heater section 32 of the heat exchanger 30. The outlet of the pre-heater section 32 is connected by a line 33 to the inlet of the main heater section 5.

Instead of feeding the lubricating flow directly from the junction 22 to the bearings, this flow is taken by a line 34 to the inlet of a cooler section 35 of the heat exchanger to flow therethrough in cooling heat exchange with the liquid in the pre-heater section 32 before being fed by a line 36 to the expander bearings 23, 24. Where the expander is a twin-screw expander, the lubricating flow may also be taken to the rotor surface lubrication inlet 37.

By cooling the lubrication flow, for example from 90° C. to 35° C., the risk of the working liquid flashing into vapour, and thus interrupting the supply of lubricant, is avoided. Further, the flow can be controlled by means of restrictors or control valves, again without vaporisation. By this means also heat that would otherwise be wasted in the bearings is recovered and used to increase the power output of the expander. The flow rate delivered to the inlet 37 depends on the working fluid and the operating conditions of the cycle but typically is of the order of two to four times the total flow delivered to the rotor bearings.

FIGS. 3 and 4 show a twin-screw expander suitable for use in the circuits of FIGS. 1 and 2. The expander has a housing 40 containing a helically lobed rotor 41 meshing with a helically grooved rotor 42. The rotor profiles, as seen in cross section are of the low friction type having helical involute bands in the region of their pitch circles, being preferably of the type disclosed in EP 0,898,655. The rotors 41 and 42 are supported in rolling bearings 43, 44 in the bearing housings 23, 24. The rotor 41 has an extension 45 projecting through the bearing housing 24, with a sealing assembly 46, to drive the external load such as the generator G.

The housing is formed with the rotor surface lubrication inlet 37 in a position just downstream of the vapour inlet 13 to ensure a sufficient pressure drop to provide an adequate lubrication flow.

The working liquid portion of this flow forms the major part of this flow and is free to vaporise and provide work as it flows through the expander while depositing lubricant on the rotor surfaces. The resulting surplus lubricant is carried by the flow of vapour leaving the expander to the condenser and is thus recirculated.

It may be found advantageous to provide collecting spaces (47, 48) adjacent to the rotor bearings.

Where the source of heat is formed by the exhaust gases and cooling jacket of an internal combustion engine, chlorotetrafluoroethane is a particularly suitable working fluid.

As shown in FIG. 5, the condenser 17 is positioned at the highest point in the system and the heater 1 and feed pump are positioned low down. Since the expander 14 is of the positive displacement type (e.g. twin screw expander) which can tolerate the possible presence of liquid droplets in the vapour flow, the separator 8 and liquid return line 9 can be omitted. Instead, the vapour from the evaporator section 6 is supplied by a line 51 to the inlet 13 of the expander 14.

The expander inlet 13 is at the bottom at one end and the low pressure vapour outlet 16 is at the top of the expander (in contrast to the orientation shown in FIG. 4). Although excess oil will tend to be expelled with the vapour into the line 15, residual oil may remain in the expander 14. This will ensure adequate lubrication of the rotor surfaces under all working conditions, and also improve the sealing of the working fluid by filling up the leakage gaps formed by the inevitable clearances between the rotors and between the rotors and the casing with oil.

As shown, the liquid condensed in the condenser 17 is conveyed by a line 19A to a liquid receiver 52 which holds a reservoir of working liquid. Liquid from the receiver 52 is conveyed by a line 198 to the inlet of the feed pump F. The hydrostatic head between the condenser 17 and the feed pump reduces or avoids the risk of cavitation in the inlet to the feed pump.

If it is found that the build of up oil in the expander is too great, an oil return line 53, of very small bore, connects an outlet 54 in the bottom of the casing of the expander to the return path from the condenser to the feed pump, in this case being connected to the liquid receiver 52. The outlet 54 is positioned just up stream of the main outlet 16 of the screw expander in a position where the pressure is just sufficiently higher than that in the receiver 52 to enable the excess oil to leave the expander.

The heater 1, preferably a plate-type heat exchanger and the liquid flow to the bearings of the expander may be accumulated in a storage vessel 55 before or after cooling in the heat exchanger 30 and being supplied to the bearing housings 23 and 24 and if necessary to the rotor surface lubricating inlet 26.

As shown in FIG. 6, in an alternative embodiment the working fluid is heated in a single pass boiler 60 in which cold liquid enters at the inlet 61 and slightly wet vapour leaves at the exit 62, without internal recirculation through a separator. In this case, the lubricant e.g. oil contained in the working fluid cannot accumulate in the boiler but is transported by the vapour to enter the expander 14. However, the presence of oil in the working fluid has the effect of raising the saturation temperature of the vapour for a given pressure and this effect can be used to advantage in this embodiment.

At oil concentrations of 5% or less, by mass, this temperature displacement is, in most cases, negligible and the working fluid thermodynamic properties are virtually identical with those of the pure working fluid. In the case of a boiler in which the working fluid recirculates through the evaporator, the recirculation flow rate is normally at least 5 times the bulk flow of fluid through the boiler. Thus, if the oil concentration is initially, say 2% by mass, the increase in concentration of oil as a result of evaporation of about 20% of the fluid, has a negligible effect on the fluid behaviour.

However, in a single pass boiler, with the same initial concentration of oil, the presence of oil has an increasing effect on the fluid behaviour as evaporation proceeds. Thus, initially, as evaporation proceeds, the working fluid behaves as a pure fluid. However, when 80-90% of the evaporation is complete, the oil concentration in the remaining liquid will become significant and further heat transfer to it, from the external heat source to the boiler, will result in the remaining liquid becoming superheated while retaining most of the oil. This means that the working fluid will enter the expander 14, as a wet vapour, with some 5-10% liquid containing a high percentage of oil. In a screw or any other type of positive displacement expander, the presence of liquid can be beneficial since

• • i) It may help to seal the gaps and lubricate the machine.
  • ii) It evaporates during the expansion process and thereby decreases the superheat with which organic working fluids normally leave the expander 14.

Thus, the superheated liquid effectively carries the oil to the rotating parts of the expander and leaves an oil deposit there as expansion proceeds in exactly the same manner as it would, if drawn from the recirculated liquid of a conventional boiler.

The oil build up in the expander will eventually drain or be transported into the condenser 17 where it will be redissolved or entrained. Thus, the cold working fluid leaving the feed pump will contain oil. Cold liquid can therefore be drawn from downstream of the pump and delivered directly to the bearings without preheating and the consequent need of a regenerative heat exchanger. Thus, the use of a single pass boiler leads to further simplification to the lubrication system, as shown.

Although it is not shown in FIG. 6, the arrangement of that figure could also include a liquid receiver arrangement of the type shown in FIG. 5 to collect and hold liquid condensed in the condenser 17 and/or excess oil from the expander.

Claims

1. A closed circuit vapor power generator system comprising:

A. a closed circuit;

B. a working fluid in the closed circuit, the working fluid comprising a vapor phase, a liquid phase, and a lubricant soluble or miscible in the liquid phase;

C. a working fluid heater in the closed circuit;

D. a heat source in communication with the working fluid heater;

E. a separator in the closed circuit in communication with the working fluid heater;

F. an expander in the closed circuit in communication with the separator;

G. a condenser in the closed circuit in communication with the expander;

H. a working fluid feed pump in the closed circuit in communication with the working fluid heater;

I. a working fluid return path in the closed circuit from the separator to the working fluid heater; and

J. a bearing lubricant supply path in the closed circuit from the working fluid feed pump to at least one bearing element for at least one rotary element of the expander.

2. The closed circuit vapor power generator system of claim 1 wherein:

(i) the heat source is in heating communication with the working fluid heater;

(ii) the separator is in working fluid transfer communication with the working fluid heater;

(iii) the expander is in working fluid transfer communication with the separator;

(iv) the condenser is in working fluid transfer communication with the expander; and

(v) the working fluid feed pump is in working fluid communication with the working fluid heater.

3. The closed circuit vapor power generator system of claim 1 wherein the working fluid heater includes an evaporator section and a heater section, and the working fluid return path leads to a junction between the working fluid heater and the evaporator section.

4. The closed circuit vapor power generator system of claim 1 wherein collection spaces are in communication with the at least one bearing element.

5. The closed circuit vapor power generator system of claim 1 wherein the bearing lubrication supply path includes a working fluid cooling heat exchanger.

6. The closed circuit vapor power generator system of claim 1 wherein the expander is a rotary expander.

7. The closed circuit vapor power generator system of claim 2 wherein the expander is a rotary expander.

8. The closed circuit vapor power generator system of claim 6 wherein the expander includes two rotary expander screws.

9. The closed circuit vapor power generator system of claim 7 wherein the expander includes two rotary expander screws.

10. The closed circuit vapor power generator system of claim 8 wherein the bearing fluid supply path leads to the at least one bearing element for a first rotary screw and the at least one second bearing element for a second rotary screw.

11. The closed circuit vapor power generator system of claim 1 wherein a liquid phase receiver is in communication with the condenser and the feed pump.

12. The closed circuit vapor power generator system of claim 2 wherein a liquid phase receiver is in working fluid transfer communication with the condenser and the feed pump.

13. The closed circuit vapor power generator system of claim 1 wherein the heat source comprises a source of moderate or low grade heat.

14. The closed circuit vapor power generator system of claim 1 wherein the heat source includes an internal combustion engine.

15. The closed circuit vapor power generator system of claim 1 wherein the working fluid includes an organic fluid.

16. The closed circuit vapor power generator system of claim 1 wherein the working fluid includes chlorotetrafluoroethane, tetrafluroethane, pentafluoropropane, or light hydrocarbons such as isoButane, n-Butane, isopentane, or n-Pentane.

17. The closed circuit vapor power generator system of claim 1 wherein the at least one bearing element for the at least one rotary element of the expander is a heat generating bearing, whereby the at least one rotary element of the expander evaporates liquid phase of the working fluid.

18. The closed circuit vapor power generator system of claim 1 wherein the working fluid heater includes a single pass boiler.

19. The closed circuit vapor power generator system of claim 1 wherein working fluid heater is in heating communication with an internal combustion engine and the working fluid includes an organic working fluid.

20. The closed circuit vapor power generator system of claim 1 wherein a percentage by weight of lubricant is up to 5% of a weight of the working fluid.

21. The closed circuit vapor power generator system of claim 1 wherein the percentage by weight of lubricant is 0.5 to 2% of the weight of the working fluid.

22. The closed circuit vapor power generator system of claim 2 wherein a percentage by weight of lubricant is up to 5% of a weight of the working fluid.

23. The closed circuit vapor power generator system of claim 2 wherein the percentage by weight of lubricant is 0.5 to 2% of the weight of the working fluid.

24. A closed flow circuit vapor power generating system comprising:

A. a closed flow mixed lubricant-working fluid circuit;

B. a mixed lubricant-working fluid heater in the closed flow mixed lubricant-working fluid circuit;

C. an expander having an expander support structure and being in the closed flow mixed lubricant-working fluid circuit in flow communication with the mixed lubricant-working fluid heater;

D. a condenser in the mixed lubricant-working fluid closed flow circuit in flow communication with the expander;

E. a working fluid feed pump in the closed flow mixed lubricant-working fluid circuit in flow communication with the condenser and the mixed lubricant-working fluid heater; and

F. a mixed lubricant-working fluid supply path in the closed flow mixed lubricant-working fluid circuit in flow communication from the working fluid working fluid feed pump to the expander support structure.

25. The closed flow circuit vapor power generating system of claim 24 wherein:

(i) the expander includes a first screw and a second screw, the first screw supported by a first screw support structure and the second screw supported by a second screw support structure; and

(ii) the mixed lubricant-working fluid supply path is in flow communication from the working fluid feed pump to the first screw support structure and second screw support structure.

26. The closed flow circuit vapor power generating system of claim 24 wherein the mixed lubricant-working fluid heater comprises a source of moderate or low grade heat.

27. The closed flow circuit vapor power generating system of claim 26 wherein the mixed lubricant-working fluid heater includes a single pass boiler.

28. The closed flow circuit vapor power generating system of claim 24 wherein the expander support structure includes a screw expander bearing in lubricating communication with the working fluid feed pump.

29. The closed flow circuit vapor power generating system of claim 24 wherein the source of heat is in heating communication with an internal combustion engine and the working fluid includes an organic working fluid.

30. The closed flow circuit vapor power generating system of claim 24 further comprising a mixed lubricant-working fluid including a liquid phase, a vapor phase, and a lubricant miscible with or soluble in the liquid phase, and wherein a percentage by weight of the lubricant in the liquid phase is up to 5% of a weight of the mixed lubricant-working fluid.

31. The closed flow circuit vapor power generating system of claim 24 wherein the percentage by weight of lubricant is 0.5 to 2% of the weight of the working fluid.

32. A vapor power generating system comprising:

A. a closed circuit with a lubricating working fluid;

B. a pressurized lubricating working fluid heater in the closed circuit;

C. a heat source in communication with the pressurized lubricating working fluid heater;

D. a separator in the closed circuit in communication with the pressurized lubricating working fluid heater;

E. a power generating expander in the closed circuit in communication with the separator;

F. a working fluid condenser in the closed circuit in communication with the power generating expander;

G. a working fluid feed pump in the closed circuit in communication with the working fluid condenser and the pressurized lubricating working fluid heater;

H. a working fluid return path in the closed circuit from the separator to the pressurized lubricating working fluid heater;

I. a working fluid bearing supply path in the closed circuit from the working fluid feed pump to at least one bearing section for at least one rotary element of the power generating vapor phase expander; and

J. a condenser in the working fluid bearing supply path.

33. The vapor power generating system of claim 32 further comprising a working fluid in the closed circuit and having a vapor phase, a liquid phase, and a lubricant mixed with the liquid phase.

34. The vapor power generating system of claim 32, wherein the percentage by weight of the lubricant in the liquid phase of the lubricating working fluid is less than or equal to 5% of a weight of the working fluid.

35. The vapor power generating system of claim 32 wherein the percentage by weight of the lubricant in the liquid phase of the lubricating working fluid is 0.5 to 2% of the weight of the working fluid.