REFRIGERATION APPARATUS
A refrigeration apparatus includes a high-temperature side circulation circuit and a low-temperature side circulation circuit. The high-temperature side circulation circuit A is configured by connecting a high-temperature side compressor, a high-temperature side condenser, a high-temperature side expansion valve, and a high-temperature side evaporator of a cascade heat exchanger to one another. The low-temperature side circulation circuit is configured by connecting a low-temperature side compressor, a low-temperature side condenser of the cascade heat exchanger, a receiver that stores a liquid refrigerant, a solenoid valve, a low-temperature side expansion valve, and a low-temperature side evaporator to one another. A refrigerant in the low-temperature side circulation circuit includes a zeotropic refrigerant mixture containing at least CO2 and R32. The content of R32 in the entire zeotropic refrigerant mixture is 50% to 74% by mass, and the GWP of the zeotropic refrigerant mixture is equal to or less than 500.
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This application is a U.S. national stage application of PCT/JP2012/071263 filed on Aug. 23, 2012, the contents of which are incorporated herein by reference.
TECHNICAL FIELDThe present invention relates to a refrigeration apparatus that performs a binary refrigeration cycle.
BACKGROUNDIn the conventional refrigeration apparatus, a low-temperature side circulation circuit in which a low-temperature refrigerant circulates and a high-temperature side circulation circuit in which a high-temperature refrigerant circulates are connected to one another by a cascade condenser. For such a refrigeration apparatus, the use of carbon dioxide (CO2) as a refrigerant in a low-temperature side circulation circuit has been proposed (see, for example, Patent Literature 1). Since CO2 occurs in nature and has a low global warming potential (GWP), the use of CO2 can avoid damaging the ozone layer even upon leakage of CO2 from a refrigeration cycle apparatus due to an unexpected accident. Thus, a refrigeration apparatus friendly to the global environment can be provided.
PATENT LITERATUREPatent Literature 1: Japanese Unexamined Patent Application Publication No. 2004-190917 (page 14, FIG. 1)
To achieve a low-GWP refrigeration apparatus, CO2 is preferably used as a refrigerant in a low-temperature side circulation circuit. However, the use of CO2 poses the following problems. Specifically, tuna, for example, requires refrigeration in a freezer at temperatures of about −50 degrees C., and this can be done by setting the evaporating temperature in a low-temperature side evaporator to about −80 degrees C. to −60 degrees C. However, when a single refrigerant of CO2 is used in a low-temperature side circulation circuit, such an evaporating temperature cannot be achieved because the triple point of CO2 is −56.6 degrees C. That is, in a refrigeration apparatus that performs a binary refrigeration cycle using a single refrigerant of CO2, it is difficult to achieve an evaporating temperature of about −80 degrees C. The use of R404A for the low-temperature side circulation circuit can reduce the evaporating temperature to about −65 degrees C. However, R404A, which has a GWP of 3920, may accelerate global warming upon leakage of a refrigerant due to an accident.
In addition, in a refrigeration apparatus, an appropriate type of zeotropic refrigerant mixture is generally known to be used to obtain a low evaporating temperature that is unattainable when a single refrigerant is used. Thus, the use of a zeotropic refrigerant mixture containing CO2 as one mixture component is expected to obtain both a low evaporating temperature and a low GWP. However, a definite type of component to be contained in the refrigerant mixture, in addition to CO2, that can obtain an evaporating temperature of −80 degrees C. to −60 degrees C. has not yet been proposed in the conventional techniques.
The inventors of the present invention have examined this issue and reached the conclusion that the use of a zeotropic refrigerant mixture containing at least CO2 and R32 in a low-temperature side circulation circuit can obtain a composition of a zeotropic refrigerant mixture with an evaporating temperature of −80 degrees C. to −60 degrees C.
SUMMARYThe present invention has been made to solve the above-mentioned problem, and has as its object to provide a refrigeration apparatus that uses a zeotropic refrigerant mixture containing at least CO2 and R32 in a low-temperature side circulation circuit to obtain an evaporating temperature of −80 degrees C. to −60 degrees C. in a low-temperature side evaporator of the low-temperature side circulation circuit with a low GWP.
A refrigeration apparatus according to the present invention includes: a high-temperature side circulation circuit configured by connecting a high-temperature side compressor, a high-temperature side condenser, a high-temperature side expansion valve, and a high-temperature side evaporator of a cascade heat exchanger to one another; and a low-temperature side circulation circuit configured by connecting a low-temperature side compressor, a low-temperature side condenser of the cascade heat exchanger, a receiver that stores a liquid refrigerant, a solenoid valve, a low-temperature side expansion valve, and a low-temperature side evaporator to one another. A refrigerant in the low-temperature side circulation circuit includes a zeotropic refrigerant mixture containing at least CO2 and R32. The content of R32 in the entire zeotropic refrigerant mixture is 50% to 74% by mass. The GWP of the zeotropic refrigerant mixture is equal to or less than 500.
The present invention can provide a refrigeration apparatus which has a low GWP and includes a low-temperature side evaporator that achieves an evaporating temperature of −80 degrees C. to −60 degrees C.
The refrigeration apparatus includes a high-temperature side circulation circuit A and a low-temperature side circulation circuit B. The high-temperature side circulation circuit A forms a series connection of a high-temperature side compressor 1, a high-temperature side condenser 2, a high-temperature side expansion valve 3, and a high-temperature side evaporator 4. The high-temperature side circulation circuit A uses R410A, R134a, R32, or a HFO refrigerant.
The low-temperature side circulation circuit B forms a series connection of a low-temperature side compressor 5, a low-temperature side condenser 6, a low-temperature side expansion valve 9, and a low-temperature side evaporator 10, and includes a receiver 7 for storing an excess refrigerant and a solenoid valve 8 both at the outlet of the low-temperature side condenser 6. The low-temperature side circulation circuit B uses a zeotropic refrigerant mixture containing at least CO2 and R32. The zeotropic refrigerant mixture refers to a refrigerant mixture containing two or more types of refrigerants having different boiling points. Note that CO2 is a low-boiling-point refrigerant and R32 is a high-boiling-point refrigerant.
The high-temperature side circulation circuit A and the low-temperature side circulation circuit B share a cascade condenser 14. The cascade condenser 14 includes the high-temperature side evaporator 4 and the low-temperature side condenser 6. The cascade condenser 14 is implemented using, for example, a plate heat exchanger and exchanges heat with a high-temperature refrigerant circulating in the high-temperature side circulation circuit A and a low-temperature refrigerant (a zeotropic refrigerant mixture) circulating in the low-temperature side circulation circuit B.
Features of the composition of a refrigerant circulating in the refrigeration cycle of the refrigeration apparatus using a zeotropic refrigerant mixture specified in the foregoing way for the low-temperature side circulation circuit B will now be described. The zeotropic refrigerant mixture exhibits characteristics as shown in
A region above the saturated vapor line represents a superheated vapor state, a region below the saturated liquid line represents a subcooling state, and a region enclosed by the saturated vapor line and the saturated liquid line represents a gas-liquid two-phase state. Referring to
In the refrigeration cycle using a zeotropic refrigerant mixture, the composition of a refrigerant circulating in the refrigeration cycle (circulation composition) is not necessarily the same as the composition of a refrigerant charged in the refrigeration cycle (charging composition). This is because in a gas-liquid two-phase portion of the refrigeration cycle indicated by point A in
An excess liquid refrigerant generated depending on the operating conditions and the load conditions in the refrigeration apparatus is accumulated in the receiver 7. The refrigerant in the receiver 7 is separated into a liquid refrigerant rich in a high-boiling-point component and a gas refrigerant rich in a low-boiling-point component, and the liquid refrigerant rich in a high-boiling-point component is stored in the receiver 7. Thus, in the presence of the liquid refrigerant in the receiver 7, the circulation composition of the zeotropic refrigerant mixture circulating in the low-temperature side circulation circuit B is likely to have a larger amount of low-boiling-point component than the charging composition. That is, the circulation composition (that is, the composition ratio of a low-boiling-point component) is likely to increase.
When the operating conditions and the load conditions change so that the amount of refrigerant stored in the receiver 7 changes, the circulation composition in the refrigeration cycle changes. With a change in circulation composition in the refrigeration cycle, the relationship between the pressure and the saturation temperature of the refrigerant changes, as can be seen from
Table 1 below shows the values of the physical characteristics of CO2 refrigerant mixtures each containing CO2 as a refrigerant mixture component and one of three types of refrigerants to be combined with CO2. Table 1 also shows the GWP and the flame resistance of each type of refrigerant to be contained in the refrigerant mixture, the mixing ratio (the mole ratio and the mass ratio) between a refrigerant to be contained in the refrigerant mixture and CO2, the GWP of a refrigerant mixture with the mixing ratio, the freezing point of the refrigerant mixture, and the −70 degrees C. temperature gradient of the refrigerant mixture.
Possible examples of a combination that can keep the freezing point below −70 degrees C. include R290, R32, and R125, as shown in Table 1. However, R290 has a poor flame resistance, that is, is flammable, is required in a large amount in, for example, a display case or a unit cooler, and thus is difficult to use due to concerns for safety.
Regarding R125, the GWP is 3500 in itself, and is more than 2000 even when it is mixed with CO2. Thus, the use of R125 is difficult in terms of preventing global warming.
Regarding R32, the GWP is 675 in itself, which is sufficiently lower than that of R125. A mixture of R32 with CO2 can keep the GWP lower than that in the case without a mixture. Thus, R32 is suitable as a refrigerant that can have no adverse effect in preventing global warming. As shown in (a) of
To achieve the object of the present invention by setting the freezing point low to keep the evaporating temperature of the low-temperature side evaporator 10 to fall within the range of −80 degrees C. to −60 degrees C., the proportion of R32 need only be increased, as described above. As is obvious from
Thus, in Embodiment, the GWP is kept as low as 500 or less, which is lower than a GWP of 3920 for R404A, and the refrigerant mixing ratio is determined in order to increase the COP to 80% or more of that in the case of using R404A. The line representing 80% of the COP in the case of using R404A is shown in (b) of
As described above, in the zeotropic refrigerant mixture, R32 is preferably mixed with CO2 such that the proportion of R32 is 50% to 74% by mass. In this case, the freezing point of the zeotropic refrigerant mixture can be reduced to −81 degrees C. or less, which is lower than the triple point of CO2. Thus, an evaporating temperature of −80 degrees C. to −60 degrees C. can be obtained, and the refrigeration apparatus has a low GWP.
The refrigerant mixture containing CO2 and R32 includes a zeotropic refrigerant mixture, and disadvantageously has a high temperature gradient (11 to 12 K) as shown in Table 1. Thus, in an appropriate operation, the circulation composition needs to be determined accurately. A configuration for detecting a circulation composition will now be described with reference to
As illustrated in
The operation of the refrigeration apparatus will now be described. In the high-temperature side circulation circuit A, a refrigerant discharged from the high-temperature side compressor 1 is condensed in the high-temperature side condenser 2 into a liquid refrigerant. The liquid refrigerant is decompressed by the high-temperature side expansion valve 3, and evaporates in the high-temperature side evaporator 4 of a cascade heat exchanger into a gas refrigerant. This gas refrigerant is drawn by suction into the high-temperature side compressor 1 again, and this cycle is repeated.
On the other hand, in the low-temperature side circulation circuit B, a vapor of a high-temperature high-pressure zeotropic refrigerant mixture compressed by the low-temperature side compressor 5 is liquefied into a condensate by the low-temperature side condenser 6, and the resulting refrigerant enters the receiver 7. The liquid refrigerant that has flowed out of the receiver 7 passes through an open solenoid valve 8 and is decompressed by the low-temperature side expansion valve 9. This refrigerant becomes a low-temperature, low-pressure gas-liquid two-phase refrigerant and flows into the low-temperature side evaporator (a display case or a unit cooler) 10. The refrigerant that has flowed into the low-temperature side evaporator 10 exchanges heat with the air in the display case, evaporates, and returns to the low-temperature side compressor 5. By repeating this cycle, cooled air is generated in the low-temperature side evaporator 10 and cools the inside of the display case.
In the above-described operation, an excess zeotropic refrigerant mixture generated in accordance with the operating conditions and load conditions is accumulated in the receiver 7. As described above, when the amount of refrigerant stored in the receiver 7 changes, the circulation composition in the refrigeration cycle changes. The principle of detecting the circulation composition in the refrigeration cycle by the composition calculator 17 will be described with reference to
The composition calculator 17 receives the pressure P and the temperature T of the liquid refrigerant in the receiver 7 from the pressure detector 15 and the temperature detector 16. The saturated liquid temperature of the zeotropic refrigerant mixture at the pressure P changes according to the circulation composition in the refrigeration cycle, as shown in
The detection of the circulation composition is not limited to the above-described method and may be performed in the following manner. In a two-component zeotropic refrigerant mixture, the circulation composition can be detected on the basis of a quality X (=mass flow rate of refrigerant vapor/flow rate of entire refrigerant) of a refrigerant and the temperature and the pressure of the refrigerant having the quality X. Specifically, in the two-component zeotropic refrigerant mixture, under a constant pressure P, the temperature of a refrigerant and the circulation composition Z with the quality X have a relationship as indicated by an alternate long and short dashed line in
That is, the temperature of the zeotropic refrigerant mixture in a gas-liquid two-phase state having the quality X at the pressure P changes depending on the circulation composition in the refrigeration cycle as shown in
In Embodiment, the pressure detector 15 is provided to the receiver 7. Alternatively, the pressure detector 15 may be provided on the discharge side of the low-temperature side compressor 5, detect the discharge pressure of the low-temperature side compressor 5, and determine, as the pressure of a liquid refrigerant that has flowed into the receiver 7, the pressure obtained by converting a pressure loss of the low-temperature side condenser 6. In Embodiment, the temperature detector 16 is provided to the receiver 7. Alternatively, the temperature detector 16 may be provided at the outlet of the low-temperature side condenser 6, and determine, as the temperature of a liquid refrigerant that has flowed into the receiver 7, the outlet liquid temperature of the low-temperature side condenser
In this manner, the circulation composition in the case of using the two-component zeotropic refrigerant mixture of CO2 and R32 for the low-temperature side circulation circuit B can accurately be detected. Thus, the rotation speed of the low-temperature side compressor 5 of the low-temperature side circulation circuit B and/or the opening degree of the low-temperature side expansion valve 9 can be optimally controlled in accordance with the circulation composition, and an ultra-low temperature freezer (for example, for storing tuna) with a low GWP and an ultra-low evaporating temperature of about −80 degrees C. to −60 degrees C. can be obtained.
As described above, in Embodiment, a refrigerant in the low-temperature side circulation circuit B includes a zeotropic refrigerant mixture containing at least CO2 and R32 and having a GWP of 500 or less, and the proportion of R32 in the mixture is 50% to 74% by mass. Thus, a refrigeration apparatus which has a low GWP and includes a low-temperature side evaporator 10 that achieves an evaporating temperature of −80 degrees C. to −60 degrees C. can be obtained. This refrigeration apparatus implements an ultra-low temperature freezer (for example, for storing tuna) having a freezer internal temperature of about −50 degrees C.
Accurate detection of the circulation composition allows control of the rotation speed of the low-temperature side compressor 5 and/or the opening degree of the low-temperature side expansion valve 9 in consideration of a change in circulation composition in the low-temperature side circulation circuit B. Thus, a refrigeration apparatus that can perform optimum control in accordance with the circulation composition and operate stably can be obtained.
Claims
1. A refrigeration apparatus comprising:
- a high-temperature side circulation circuit configured by connecting a high-temperature side compressor, a high-temperature side condenser, a high-temperature side expansion valve, and a high-temperature side evaporator of a cascade heat exchanger to one another; and
- a low-temperature side circulation circuit configured by connecting a low-temperature side compressor, a low-temperature side condenser of the cascade heat exchanger, a receiver that stores a liquid refrigerant, a solenoid valve, a low-temperature side expansion valve, and a low-temperature side evaporator to one another, wherein
- a refrigerant in the low-temperature side circulation circuit includes a zeotropic refrigerant mixture containing at least CO2 and R32,
- a content of R32 in the entire zeotropic refrigerant mixture is 50% to 74% by mass, and
- a GWP of the zeotropic refrigerant mixture is not more than 500.
2. The refrigeration apparatus of claim 1, further comprising:
- a composition calculation unit that obtains a composition of the refrigerant circulating in the low-temperature side circulation circuit; and
- a controller that controls the low-temperature side circulation circuit based on the composition of the refrigerant obtained by the composition calculation unit.
3. The refrigeration apparatus of claim 2, wherein
- the composition calculation unit includes
- a pressure detector that detects a pressure of a liquid refrigerant in the receiver,
- a temperature detector that detects a temperature of the liquid refrigerant in the receiver, and
- a composition calculator that obtains the composition of the refrigerant circulating in the low-temperature side circulation circuit, based on the pressure detected by the pressure detector and the temperature detected by the temperature detector.
Type: Application
Filed: Aug 23, 2012
Publication Date: Jun 4, 2015
Applicant: Mitsubishi Electric Corporation (Tokyo)
Inventors: Takeshi Sugimoto (Tokyo), So Nomoto (Tokyo), Tomotaka Ishikawa (Tokyo), Keisuke Takayama (Tokyo), Takashi Ikeda (Tokyo)
Application Number: 14/401,916