CN110701812A - Supercritical CO is striden in ejector pressure boost subcooling expander coupling2System and application - Google Patents
Supercritical CO is striden in ejector pressure boost subcooling expander coupling2System and application Download PDFInfo
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- 239000012530 fluid Substances 0.000 claims abstract description 48
- 239000007788 liquid Substances 0.000 claims abstract description 43
- 239000003507 refrigerant Substances 0.000 claims abstract description 39
- 238000010168 coupling process Methods 0.000 claims abstract description 8
- 238000005859 coupling reaction Methods 0.000 claims abstract description 8
- 238000001816 cooling Methods 0.000 claims description 53
- 238000005057 refrigeration Methods 0.000 claims description 11
- 238000010438 heat treatment Methods 0.000 claims description 4
- 239000000203 mixture Substances 0.000 claims description 3
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 claims description 3
- 238000004781 supercooling Methods 0.000 abstract description 19
- 230000008878 coupling Effects 0.000 abstract description 6
- 238000000034 method Methods 0.000 description 15
- 238000001704 evaporation Methods 0.000 description 13
- 230000008569 process Effects 0.000 description 13
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- 231100000252 nontoxic Toxicity 0.000 description 3
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- 238000012546 transfer Methods 0.000 description 3
- CBENFWSGALASAD-UHFFFAOYSA-N Ozone Chemical compound [O-][O+]=O CBENFWSGALASAD-UHFFFAOYSA-N 0.000 description 2
- 238000004378 air conditioning Methods 0.000 description 2
- 230000008901 benefit Effects 0.000 description 2
- 230000008859 change Effects 0.000 description 2
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- 238000004519 manufacturing process Methods 0.000 description 2
- 239000002994 raw material Substances 0.000 description 2
- 229920006395 saturated elastomer Polymers 0.000 description 2
- 239000003054 catalyst Substances 0.000 description 1
- 238000009833 condensation Methods 0.000 description 1
- 230000005494 condensation Effects 0.000 description 1
- 238000007796 conventional method Methods 0.000 description 1
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- 238000010586 diagram Methods 0.000 description 1
- 238000009792 diffusion process Methods 0.000 description 1
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- 238000002347 injection Methods 0.000 description 1
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- MSSNHSVIGIHOJA-UHFFFAOYSA-N pentafluoropropane Chemical compound FC(F)CC(F)(F)F MSSNHSVIGIHOJA-UHFFFAOYSA-N 0.000 description 1
- 238000006467 substitution reaction Methods 0.000 description 1
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25B—REFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
- F25B5/00—Compression machines, plants or systems, with several evaporator circuits, e.g. for varying refrigerating capacity
- F25B5/04—Compression machines, plants or systems, with several evaporator circuits, e.g. for varying refrigerating capacity arranged in series
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25B—REFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
- F25B41/00—Fluid-circulation arrangements
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25B—REFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
- F25B41/00—Fluid-circulation arrangements
- F25B41/30—Expansion means; Dispositions thereof
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25B—REFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
- F25B43/00—Arrangements for separating or purifying gases or liquids; Arrangements for vaporising the residuum of liquid refrigerant, e.g. by heat
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Abstract
The invention provides an ejector supercharging super-cooling expansion machine coupling transcritical CO2Systems and applications, including CO2Evaporator, CO2The system comprises a gas cooler, a high-temperature-stage evaporator, a medium-temperature-stage evaporator, a low-temperature-stage gas-liquid separator, a low-temperature-stage ejector and a condenser; the outlet of the evaporator is sequentially communicated with CO2Compressor, CO2Heat medium side of gas cooler, heat medium side of high temperature stage evaporator, heat medium side of medium temperature stage evaporator, CO2The inlet of the expander and evaporator; the outlet of the low-temperature ejector is communicated with the common working medium compressor, the heat medium side of the condenser, the refrigerant side of the high-temperature evaporator and the low-temperature gas in sequenceThe inlet of the liquid separator, the refrigerant side of the medium-temperature grade evaporator and the secondary inflow port of the low-temperature grade ejector. The ejector supercharging supercooling expansion machine of the invention is coupled with transcritical CO2The system can greatly reduce the entering CO2Evaporator CO2The dryness of the two-phase fluid and the refrigerating capacity of the system are obviously improved.
Description
Technical Field
The invention belongs to the technical field of refrigeration and heating and heat pumps, and particularly relates to an ejector supercharging supercooling expansion machine coupled transcritical CO2A system and an application.
Background
With the increasing problem of global warming and ozone layer destruction, the refrigeration air-conditioning industry needs to find environment-friendly refrigerants to replace working media such as HFCs, HCFCs and the like which have the effect of destroying the ozone layer and cause the greenhouse effect. The substitution of refrigerant and the environmental protection problem naturally become the focus of attention in the refrigeration air-conditioning industry. Wherein, natural working medium CO2The refrigerant is an environment-friendly natural working medium which is non-toxic, non-combustible, rich in source and large in unit volume refrigerating capacity, and has attracted wide attention due to the fact that ODP (optical density distribution) is 0 and GWP is extremely low.
But due to CO2The lower critical temperature (31.1 ℃) and the higher critical pressure (7.38MPa) lead to larger throttle irreversible loss and lower refrigeration efficiency, and transcritical CO is subjected to vapor compression refrigeration circulation2CO at the outlet of the gas cooler of the refrigeration cycle2The method of cooling is known as mechanical subcooling. The throttle irreversible loss is reduced by increasing the supercooling degree, the circulating refrigerating capacity is increased, and the CO is reduced2The high pressure of the circulation operation and the exhaust pressure of the compressor prolong the service life of the compressor and improve the COP of the circulation.
The ejector is also called an injection pump and is mainly used for changing the pressure of fluid. The main flow high-pressure fluid is expanded at an isentropic speed in the nozzle, the pressure is reduced, the secondary flow is ejected and sucked, and the two flows are mixed in the mixing chamber to the intermediate pressure, so that two different pressures of the high pressure at the outlet of the ejector and the medium pressure of the secondary flow are formed. The high pressure at the outlet of the ejector is sucked by the compressor, so that the pressure ratio of the ejector can be effectively reduced, the efficiency of the compressor is improved, and the cyclic COP is obviously improved.
Disclosure of Invention
In view of this, the present invention aims to provide a coupled transcritical CO of an ejector supercharging and supercooling expansion machine2System to overcome the above-mentioned drawbacks, CO2The fluid at the outlet of the gas cooler is continuously subjected to two-step cooling, and CO2The fluid is fully supercooled, the supercooled fluid enters an expansion machine to do work through expansion and provide power for a compressor, the process is different from the traditional throttling and pressure reducing process of a throttle valve, and the entering CO can be greatly reduced2Evaporator CO2The dryness of the two-phase fluid and the refrigerating capacity of the system are obviously improved and greatly increasedTo a certain extent reduce CO2Irreversible loss of the system.
In order to achieve the purpose, the technical scheme of the invention is realized as follows:
supercritical CO is striden in ejector pressure boost subcooling expander coupling2System of CO2Evaporator, CO2The system comprises a gas cooler, a high-temperature-stage evaporator, a medium-temperature-stage evaporator, a low-temperature-stage gas-liquid separator, a low-temperature-stage ejector and a condenser;
the outlet of the evaporator is sequentially communicated with CO2Compressor, CO2Heat medium side of gas cooler, heat medium side of high temperature stage evaporator, heat medium side of medium temperature stage evaporator, CO2The inlet of the expander and evaporator;
the outlet of the low-temperature ejector is sequentially communicated with a common working medium compressor, a heat medium side of a condenser, an intermediate-temperature throttling valve, a refrigerant side of a high-temperature evaporator, an inlet of a low-temperature gas-liquid separator, the low-temperature throttling valve, the refrigerant side of the intermediate-temperature evaporator and a secondary inflow port of the low-temperature ejector; the gas outlet of the low-temperature-stage gas-liquid separator is communicated with the main flow inlet of the low-temperature-stage ejector;
the refrigerant side of the condenser is communicated with CO2The cold side of the gas cooler.
Further, a fan is installed below the evaporator.
Furthermore, the ejector supercharging supercooling expansion machine is coupled with transcritical CO2The system also comprises a medium-temperature level ejector arranged on a pipeline between the heat medium side of the condenser and the medium-temperature level throttling valve, and a medium-temperature level gas-liquid separator arranged on a pipeline between the medium-temperature level throttling valve and the heat medium side of the high-temperature level evaporator.
Note that, at this time, CO2Evaporator, CO2Compressor, CO2Gas cooler and CO2The expander constitutes transcritical CO2A circulating common working medium compressor, a condenser, a medium-temperature level ejector, a low-temperature level ejector, a medium-temperature level cooling evaporator, a low-temperature level cooling evaporator, a medium-temperature level gas-liquid separator, a low-temperature level gas-liquid separator, a medium-temperature level throttle valve and a low-temperature levelThe stage throttle valve constitutes a double ejector boost subcooling cycle.
Further, an outlet of the medium-temperature level ejector is communicated with the medium-temperature level throttle valve, and a main flow inlet of the medium-temperature level ejector is communicated with a heat medium side of the condenser; and the secondary inflow port of the medium-temperature ejector is communicated with the gas outlet of the medium-temperature gas-liquid separator.
Preferably, the temperature of a secondary inflow port (namely, an inlet of a contraction pipe) of the medium-temperature-level ejector is 10-40 ℃, the temperature of a main flow (namely, an inlet fluid of a nozzle) is 35-55 ℃, and the temperature of an outlet working medium is 30-50 ℃; the working temperature of the medium-temperature stage throttling valve is 30-50 ℃, and the working temperature of the medium-temperature stage gas-liquid separator is 10-40 ℃.
Furthermore, the working temperature of the low-temperature-level throttling valve is-10-20 ℃.
Further, said CO2The heat exchange fluid at the heat medium side of the gas cooler, the heat medium side of the medium-temperature stage cooling evaporator and the heat medium side of the low-temperature stage cooling evaporator is CO2。
Further, said CO2The heat exchange fluid on the refrigerant side of the gas cooler and the refrigerant side of the condenser is water; the heat exchange working media at the heat medium side of the condenser, the refrigerant side of the medium-temperature stage cooling evaporator and the refrigerant side of the low-temperature stage cooling evaporator are pure refrigerants or non-azeotropic mixed working media;
preferably, the pure refrigerant is one of R1234zeZ, R1234zeE, R1233zdE, R1224ydZ, R1336mzzZ, R365mfc, R1234yf, R245 fa; more preferably, the pure refrigerant is R1234 yf;
preferably, the non-azeotropic mixed working medium is CO2/R1234zeE、CO2/R1234zeZ、CO2One of/R1234 yf, R41/R1234zeE, R41/R1234zeZ, R41/R1234yf, R32/R1234zeE, R32/R1234zeZ, R32/R1234 yf; preferably, the zeotropic mixture is R32/R1234 zeZ.
Further, CO2The gas cooler and the condenser are both sleeve type heat exchangers or plate type heat exchangers; CO 22The evaporator, the medium-temperature stage cooling evaporator and the low-temperature stage cooling evaporator respectively adopt a finned tube evaporator, a sleeve type heat exchanger or a plate heat exchanger, and a sleeve type heat exchanger or a plate heat exchanger.
Further, CO2The suction pressure range of the compressor is 0.53-4.50 MPa, and the exhaust pressure range is 7.5-14 MPa; CO 22The temperature range of the evaporator is-56-10 ℃; the temperature range of the medium-temperature stage cooling evaporator is 10-40 ℃; the temperature range of the low-temperature stage cooling evaporator is-10-20 ℃; the temperature range of the medium-temperature grade gas-liquid separator is 10-40 ℃; the working temperature range of the low-temperature-grade gas-liquid separator is 10-40 ℃; the temperature of a secondary inflow port (namely an inlet of a contraction pipe) of the low-temperature ejector is-10-20 ℃, the temperature of a main flow (namely an inlet fluid of a nozzle) is 10-40 ℃, and the temperature of an outlet working medium is 5-35 ℃.
The invention also relates to the ejector supercharging super-cooling expansion machine coupling trans-critical CO2The system is applied to the fields of refrigeration and heating and heat pumps.
Compared with the prior art, the ejector supercharging and supercooling expansion machine coupling transcritical CO2The system has the following advantages:
(1)CO2the fluid at the outlet of the gas cooler is continuously subjected to two-step cooling, and CO2The fluid is fully supercooled, the supercooled fluid enters an expansion machine to do work through expansion and provide power for a compressor, the process is different from the traditional throttling and pressure reducing process of a throttle valve, and the entering CO can be greatly reduced2Evaporator CO2The dryness of the two-phase fluid and the refrigerating capacity of the system are obviously improved, and the CO is greatly reduced2Irreversible loss of the system can overcome CO caused by overhigh ambient temperature2The gas cooler outlet fluid can not be sufficiently cooled, the system is suitable for the regions with hot and warm climates, and the higher the ambient temperature is, the more remarkable the energy efficiency improvement advantage of the system is.
(2) The arrangement of the medium-temperature-stage gas-liquid separator can ensure that the fluid entering the medium-temperature-stage cooling evaporator is saturated liquid, and compared with the conventional gas-liquid two-phase fluid, the distribution of the saturated liquid in each parallel pipeline of the cooling evaporator is more uniform, the friction resistance pressure drop in the pipeline is reduced, the dryness of a working medium inlet in the cooling evaporator is zero, the heat transfer deterioration caused by dry evaporation is not easy to occur in the process of convection evaporation in the pipeline, the heat exchange coefficient is improved, the required heat exchange area is reduced, and the raw materials for manufacturing the equipment are saved.
(3) The arrangement of the medium-temperature-stage ejector ensures that the throttled gas-phase fluid does not participate in the refrigeration evaporation phase change process, and after the throttled gas-phase fluid is directly ejected and mixed by the high-pressure fluid at the outlet of the condenser, the pressure is reduced to the exhaust pressure of the compressor and the intermediate pressure after primary throttling, so that the pressure before throttling is reduced, and the irreversible loss in the throttling process is reduced.
(4) The low-temperature ejector is arranged to improve the pressure of saturated or superheated gas passing through the low-temperature throttling valve, the pressure of fluid sucked into the inlet of the common working medium compressor is finally higher than the evaporating pressure of the low-temperature cooling evaporator, the suction pressure of the common working medium compressor is improved, the compression ratio is reduced, the exhaust temperature of the compressor is reduced, and the overall performance of the system is improved.
(5) Transcritical CO2The circulating refrigerant is natural working medium CO2. ODP is 0, GWP is 1, and the catalyst can not be decomposed at high temperature, is safe and nontoxic and is environment-friendly. The working medium of the double-ejector supercharging supercooling mechanical supercooling cycle can adopt pure refrigerants such as R1234ze (Z), R1234ze (E), R1233zd (E), R1224yd (Z), R1336mzz (Z), R365mfc, R1234yf and R245fa, and can also adopt CO2/R1234ze(E)、CO2/R1234ze(Z)、CO2Non-azeotropic mixed working media such as/R1234 yf, R41/R1234ze (E), R41/R1234ze (Z), R41/R1234yf, R32/R1234ze (E), R32/R1234ze (Z), R32/R1234yf and the like. For the non-azeotropic mixed working medium, a refrigerant with the temperature slippage equivalent to the temperature difference of the inlet and the outlet of the heat exchange fluid of the evaporator is selected, and the slippage temperature difference of the evaporation and condensation processes of the non-azeotropic working medium is not large, so that the heat transfer temperature difference can be reduced, and the irreversible loss can be reduced.
Drawings
FIG. 1 shows an ejector super-cooling and boosting expander coupled transcritical CO according to embodiment 1 of the present invention2A simple schematic diagram of the system;
FIG. 2 shows an ejector super-cooling and boosting expander coupled transcritical CO according to embodiment 2 of the present invention2A simple schematic of the system.
Reference numerals:
1-CO2an evaporator; 2-CO2A compressor; 3-CO2A gas cooler; 4-intermediate temperature stage cooling evaporator; 5-low temperature stage cooling evaporator; 6-CO2An expander; 7-a common working medium compressor; 8-a condenser; 9-a low-temperature level ejector; 10-medium temperature stage throttle valve; 11-a fan; 12-low temperature stage throttle valve; 13-low temperature grade gas-liquid separator; 14-medium temperature grade gas-liquid separator; 15-medium temperature level ejector.
Detailed Description
Unless defined otherwise, technical terms used in the following examples have the same meanings as commonly understood by one of ordinary skill in the art to which the present invention belongs. The test reagents used in the following examples, unless otherwise specified, are all conventional biochemical reagents; the experimental methods are conventional methods unless otherwise specified.
The present invention will be described in detail with reference to the following examples and accompanying drawings.
As shown in figure 1, an ejector supercharging super-cooling expansion machine coupling transcritical CO2System of CO2Evaporator 1, CO2Compressor 2, CO2Gas cooler 3 and CO2The expander 6 constitutes transcritical CO2Circulation, and double-ejector supercharging and supercooling circulation consisting of a common working medium compressor 7, a condenser 8, a medium-temperature-level ejector 15, a low-temperature-level ejector 9, a medium-temperature-level cooling evaporator 4, a low-temperature-level cooling evaporator 5, a medium-temperature-level gas-liquid separator 14, a low-temperature-level gas-liquid separator 13, a medium-temperature-level throttling valve 10 and a low-temperature-level throttling valve 12; transcritical CO2Heat exchange can be carried out between the circulation and the double-ejector supercharging and supercooling circulation.
Specifically, the method comprises the following steps: the outlet of the evaporator 1 is sequentially communicated with CO2Compressor 2, CO2Heat medium side of gas cooler 3, heat medium side of high temperature stage evaporator 4, heat medium side of medium temperature stage evaporator 5, CO2The inlet of the expander 6 and the evaporator 1; the outlet of the low-temperature-stage ejector 9 is sequentially communicated with a common working medium compressor 7, the heat medium side of a condenser 8, the main flow inlet of an intermediate-temperature-stage ejector 15, an intermediate-temperature-stage gas-liquid separator 14, the refrigerant side of the high-temperature-stage evaporator 4, the inlet of a low-temperature-stage gas-liquid separator 13 and the refrigerant side of the intermediate-temperature-stage evaporator 5And a secondary inflow port of the low-temperature ejector 9; a gas outlet of the low-temperature-stage gas-liquid separator 13 is communicated with a main flow inlet of the low-temperature-stage ejector 9; a secondary inflow port of the medium-temperature ejector 15 is communicated with a gas outlet of the medium-temperature gas-liquid separator 14; the refrigerant side of the condenser 8 is communicated with CO2The cold side of the gas cooler 3.
The arrangement of the medium-temperature-stage ejector 15 enables the throttled gas-phase fluid not to participate in the refrigeration evaporation phase change process, and after the throttled gas-phase fluid is directly ejected and mixed by the high-pressure fluid at the outlet of the condenser, the pressure is reduced to the exhaust pressure of the compressor and the intermediate pressure after primary throttling, so that the pressure before throttling is reduced, and the irreversible loss in the throttling process is reduced. The arrangement of the medium-temperature-stage gas-liquid separator 14 can enable the fluid entering the medium-temperature-stage cooling evaporator to be saturated liquid, and compared with the conventional gas-liquid two-phase fluid, the distribution of the saturated liquid in each parallel pipeline of the cooling evaporator is more uniform, the friction resistance pressure drop in the pipeline is reduced, the dryness of the working medium inlet in the cooling evaporator is zero, the heat transfer deterioration caused by dry evaporation is not easy to occur in the process of convection evaporation in the pipeline, the heat exchange coefficient is improved, the required heat exchange area is reduced, and the raw materials for manufacturing the equipment are saved. The low-temperature ejector is arranged to improve the pressure of saturated or superheated gas passing through the low-temperature throttling valve, the pressure of fluid sucked into the inlet of the common working medium compressor is finally higher than the evaporating pressure of the low-temperature cooling evaporator, the suction pressure of the common working medium compressor is improved, the compression ratio is reduced, the exhaust temperature of the compressor is reduced, and the overall performance of the system is improved.
As an alternative embodiment of the present invention, a fan 11 is installed below the evaporator 1 in order to improve the evaporation efficiency.
As an optional embodiment of the invention, the temperature of a secondary inflow port (namely, an inlet of a contraction pipe) of the medium-temperature-level ejector 15 is 10-40 ℃, the temperature of a main flow (namely, an inlet fluid of a nozzle) is 35-55 ℃, and the temperature of an outlet working medium is 30-50 ℃; the working temperature of the medium-temperature stage throttling valve 10 is 30-50 ℃, and the working temperature of the medium-temperature stage gas-liquid separator 14 is 10-40 ℃. The working temperature of the low-temperature-stage throttle valve 12 is-10-20 DEG C
As an alternative embodiment of the invention, due to natureWorking medium CO2Is a non-toxic, non-flammable, environment-friendly natural working medium with rich source and large refrigerating capacity per unit volume, and the CO is very low in GWP because the ODP is 02The heat exchange fluids at the heat medium side of the gas cooler 3, the heat medium side of the medium-temperature stage cooling evaporator 4 and the heat medium side of the low-temperature stage cooling evaporator 5 are all CO2。
As an alternative embodiment of the invention, the CO is2The heat exchange fluid on the refrigerant side of the gas cooler 3 and the refrigerant side of the condenser 8 may be water.
As an alternative embodiment of the present invention, the heat exchange working mediums at the heat medium side of the condenser 8, the refrigerant side of the middle-temperature stage cooling evaporator 4 and the refrigerant side of the low-temperature stage cooling evaporator 5 are pure refrigerants or non-azeotropic mixture working mediums. In particular, the old: the pure refrigerant can be selected from one of R1234zeZ, R1234zeE, R1233zdE, R1224ydZ, R1336mzzZ, R365mfc, R1234yf and R245 fa; preferably R1234 yf. CO can be selected as non-azeotropic mixed working medium2/R1234zeE、CO2/R1234zeZ、CO2One of/R1234 yf, R41/R1234zeE, R41/R1234zeZ, R41/R1234yf, R32/R1234zeE, R32/R1234zeZ, R32/R1234yf, preferably R32/R1234 zeZ.
As an alternative embodiment of the invention, CO2The gas cooler 3 and the condenser 8 are both sleeve-type heat exchangers or plate-type heat exchangers; CO 22The evaporator 1, the medium-temperature-stage cooling evaporator 4 and the low-temperature-stage cooling evaporator 5 respectively adopt a fin tube type evaporator, a double-tube type heat exchanger or a plate heat exchanger. A more preferred embodiment is: CO 22The gas cooler 3 and the condenser 8 are both sleeve type heat exchangers; CO 22The evaporator 1, the medium-temperature stage cooling evaporator 4 and the low-temperature stage cooling evaporator 5 respectively adopt a fin tube type evaporator, a double-pipe type heat exchanger and a plate type heat exchanger.
As an alternative embodiment of the invention, CO2The suction pressure range of the compressor 2 is 0.53-4.50 MPa, and the exhaust pressure range is 7.5-14 MPa; CO 22The temperature range of the evaporator 1 is-56-10 ℃; the temperature range of the intermediate-temperature stage cooling evaporator 4 is 10-40 ℃; of the evaporator 5 with low-temperature stage coolingThe temperature range is-10 to 20 ℃; the temperature range of the medium-temperature-grade gas-liquid separator 14 is 10-40 ℃; the working temperature range of the low-temperature-grade gas-liquid separator 13 is 10-40 ℃; the temperature of a secondary inflow port (namely an inlet of a contraction pipe) of the low-temperature-level ejector 9 is-10-20 ℃, the temperature of a main flow (namely an inlet fluid of a nozzle) is 10-40 ℃, and the temperature of an outlet working medium is 5-35 ℃.
When in use, one preferred process condition is: CO 22The evaporation temperature of the evaporator 1 is 0 ℃, the evaporation temperature of the intermediate-temperature stage cooling evaporator 4 is 20 ℃, the evaporation temperature of the low-temperature stage cooling evaporator 5 is 5 ℃, and CO is evaporated2The suction pressure of the compressor 2 was 3.49MPa, and the discharge pressure was 10 MPa. The working medium flowing through the refrigerant side of the medium-temperature-level cooling evaporator 4, the refrigerant side of the low-temperature-level cooling evaporator 5 and the heat medium side of the condenser 8 is R1234yf, the temperature of a secondary inflow port (namely an inlet of a contraction pipe) of the low-temperature-level ejector 9 is 5 ℃, the pressure is 0.37MPa, the temperature of a main flow (namely an inlet fluid of a nozzle) is 20 ℃, the pressure is 0.59MPa, and the temperature of a working medium at an outlet of the low-temperature-level ejector 9 is 8 ℃, and the pressure is 0.41 MPa. The temperature of a secondary inflow port (namely an inlet of a contraction pipe) of the medium-temperature-level ejector 15 is 20 ℃, the pressure is 0.59MPa, the temperature of a main flow (namely an inlet fluid of a nozzle) is 50 ℃, the pressure is 1.30MPa, the temperature of a working medium at an outlet of the medium-temperature-level ejector 15 is 45 ℃, and the pressure is 1.15 MPa; the working temperature of the medium-temperature-stage throttling valve 10 is 40 ℃, the working temperature of the medium-temperature-stage gas-liquid separator 14 is 25 ℃, and the working temperature of the low-temperature-stage throttling valve 12 is 5 ℃.
The ejector supercharging supercooling expansion machine of the invention is coupled with transcritical CO2The system, when in operation, may include the steps of:
the first step is as follows: CO 22Low temperature and low pressure CO at the outlet of the evaporator 12Into CO2The compressor 2 is compressed to a high temperature and pressure gas, which is then fed to the CO2CO after heat exchange of gas cooler 3 and heat exchange fluid2The temperature is reduced and then flows through a medium-temperature stage cooling evaporator 4CO2Laterally exchanging heat with a common working medium, reducing the temperature again, and then flowing into a low-temperature stage cooling evaporator 5CO2The heat exchange with the common working medium is carried out, the temperature is reduced again, and CO is realized through two continuous heat exchanges2The fluid is subcooled and then cooled in CO2The expansion pressure in the expander 6 is reduced to gas-liquid two-phase fluid, and CO flows into the expander2The evaporator 1 absorbs heat and is then subjected to CO2The compressor 2 sucks in the gas to compress the gas to complete the transcritical CO2And (4) circulating the heat pump. CO 22Work generated by the expander 6 may be transferred to the CO via a coupling or the like2A compressor 2.
The second step is that: the common working medium compressor 7 compresses a common working medium at the outlet of the low-temperature-stage ejector 9 to high-temperature high-pressure gas, the high-temperature high-pressure gas enters the condenser 8 to exchange heat with heat exchange fluid to provide heat for the heat exchange fluid, the working medium at the outlet of the condenser 8 enters the medium-temperature-stage ejector 15 as a main flow to guide gas-phase fluid of the gas-liquid separator 14, the gas-phase fluid is mixed and decompressed and flows out of the ejector 15, the mixed and decompressed gas-phase fluid enters the medium-temperature-stage gas-liquid separator 14 after being subjected to primary throttling decompression, the gas-phase fluid is sucked by the medium-2CO from gas cooler2Carrying out heat exchange, CO2The temperature is reduced after being cooled, and the common working medium flows through the middle-temperature stage cooling evaporator 4 and then enters the low-temperature stage gas-liquid separator 13.
The third step: the gas-liquid separator 13 is provided with two outlets, gas is used as the main flow of the low-temperature-level ejector 9, liquid is throttled again and flows through the low-temperature-level cooling evaporator 5 and the medium-temperature-level cooling evaporator 4CO2Side-vented CO2Heat exchange is carried out again, CO2The fluid is cooled again, the heat-exchanged common working medium is sucked into the diffusion chamber as a secondary flow by the low-temperature ejector 9, the fluid speed is reduced, the pressure is increased between the main flow and the secondary flow, and the common working medium from the low-temperature ejector 9 is sucked by the compressor 7. And completing the pressurization and supercooling circulation of the double-flow diverter.
In the above process, CO2The side is also the heat medium side, the common working medium side is also the refrigerant side of the intermediate temperature stage cooling evaporator and the low temperature stage cooling evaporator, and the common working medium is also the heat medium side of the condenser side.
The invention relates to a coupling transcritical CO of an ejector supercharging supercooling expansion machine2The system is especially used in the fields of refrigeration, heating and heat pump in hot and warm climates.
Example 2
As shown in fig. 2, the ejector super-cooling and boosting expander of this embodiment is coupled to transcritical CO2The system, essentially the same as example 1, differs in that:
the medium-temperature grade ejector 15 and the medium-temperature grade gas-liquid separator 14 are omitted.
Therefore, the throttle irreversible loss of the medium-temperature-stage throttle valve is slightly larger than that of the embodiment 1, but the cost is slightly lower, and the energy efficiency of the system can also be improved.
The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.
Claims (10)
1. Supercritical CO is striden in ejector pressure boost subcooling expander coupling2A system, characterized by: comprising CO2Evaporator (1), CO2The system comprises a gas cooler (3), a high-temperature-stage evaporator (4), a medium-temperature-stage evaporator (5), a low-temperature-stage gas-liquid separator (13), a low-temperature-stage ejector (9) and a condenser (8);
the outlet of the evaporator (1) is communicated with CO in sequence2Compressor (2), CO2Heat medium side of gas cooler (3), heat medium side of high temperature stage evaporator (4), heat medium side of medium temperature stage evaporator (5), CO2The inlet of the expander (6) and the evaporator (1);
the outlet of the low-temperature ejector (9) is sequentially communicated with a common working medium compressor (7), the heat medium side of a condenser (8), an intermediate-temperature throttle valve (10), the refrigerant side of a high-temperature evaporator (4), the inlet of a low-temperature gas-liquid separator (13), a low-temperature throttle valve (12), the refrigerant side of an intermediate-temperature evaporator (5) and the secondary inflow port of the low-temperature ejector (9); a gas outlet of the low-temperature-stage gas-liquid separator (13) is communicated with a main flow inlet of the low-temperature-stage ejector (9);
the refrigerant side of the condenser (8) is communicated with CO2The cold side of the gas cooler (3).
2. The ejector plenum of claim 1Super-cooled expander coupled transcritical CO2A system, characterized by: and a fan (11) is arranged below the evaporator (1).
3. The ejector super-cooled expander coupled transcritical CO of claim 12A system, characterized by: the system also comprises a medium-temperature level ejector (15) arranged on a pipeline between the heat medium side of the condenser (8) and the medium-temperature level throttling valve (10), and a medium-temperature level gas-liquid separator (14) arranged on a pipeline between the medium-temperature level throttling valve (10) and the heat medium side of the high-temperature level evaporator (4).
4. The ejector super-cooled expander coupled transcritical CO of claim 32A system, characterized by: an outlet of the medium-temperature-level ejector (15) is communicated with the medium-temperature-level throttle valve (10), and a main flow inlet of the medium-temperature-level ejector (15) is communicated with a heat medium side of the condenser (8); a secondary inflow port of the medium-temperature ejector (15) is communicated with a gas outlet of the medium-temperature gas-liquid separator (14);
preferably, the temperature of a secondary inlet of the medium-temperature-grade ejector (15) is 10-40 ℃, the temperature of a main stream is 35-55 ℃, and the temperature of an outlet working medium is 30-50 ℃; the working temperature of the medium-temperature-grade throttle valve (10) is 30-50 ℃, and the working temperature of the medium-temperature-grade gas-liquid separator (14) is 10-40 ℃; the working temperature of the low-temperature-stage throttle valve (12) is-10-20 ℃.
5. The ejector super-cooled booster expander coupled transcritical CO according to any one of claims 1 to 42A system, characterized by: the CO is2The heat exchange fluid at the heat medium side of the gas cooler (3), the heat medium side of the medium-temperature stage cooling evaporator (4) and the heat medium side of the low-temperature stage cooling evaporator (5) is CO2。
6. The ejector super-cooled booster expander coupled transcritical CO according to any one of claims 1 to 42A system, characterized by: the CO is2The heat exchange fluid on the refrigerant side of the gas cooler (3) and the refrigerant side of the condenser (8) is water; condenser (8) heat medium side and middle temperature stage cooling evaporator(4) The heat exchange working medium at the refrigerant side of the low-temperature stage cooling evaporator (5) is pure refrigerant or non-azeotropic mixed working medium.
7. The ejector super-cooled booster expander coupled transcritical CO according to any one of claims 1 to 42A system, characterized by: the pure refrigerant is one of R1234zeZ, R1234zeE, R1233zdE, R1224ydZ, R1336mzzZ, R365mfc, R1234yf and R245 fa; preferably, the pure refrigerant is R1234 yf;
preferably, the non-azeotropic mixed working medium is CO2/R1234zeE、CO2/R1234zeZ、CO2One of/R1234 yf, R41/R1234zeE, R41/R1234zeZ, R41/R1234yf, R32/R1234zeE, R32/R1234zeZ, R32/R1234 yf; more preferably, the zeotropic mixture is R32/R1234 zeZ.
8. The ejector super-cooled booster expander coupled transcritical CO according to any one of claims 1 to 42A system, characterized by: CO 22The gas cooler (3) and the condenser (8) are both sleeve-type heat exchangers or plate-type heat exchangers; CO 22The evaporator (1), the medium-temperature-stage cooling evaporator (4) and the low-temperature-stage cooling evaporator (5) are respectively a finned tube evaporator, a double-tube heat exchanger or a plate heat exchanger, or a double-tube heat exchanger or a plate heat exchanger.
9. The ejector super-cooled booster expander coupled transcritical CO according to any one of claims 1 to 42A system, characterized by: CO 22The suction pressure range of the compressor (2) is 0.53-4.50 MPa, and the exhaust pressure range is 7.5-14 MPa; CO 22The temperature range of the evaporator (1) is-56-10 ℃; the temperature range of the medium-temperature stage cooling evaporator (4) is 10-40 ℃; the temperature range of the low-temperature stage cooling evaporator (5) is-10-20 ℃; the temperature range of the medium-temperature grade gas-liquid separator (14) is 10-40 ℃; the working temperature range of the low-temperature-grade gas-liquid separator (13) is 10-40 ℃; the temperature of a secondary inflow port of the low-temperature ejector (9) is-10-20 ℃, the temperature of a main flow is 10-40 ℃, and the temperature of an outlet working medium is 5-35 ℃.
10. The ejector super-cooled booster expander coupled transcritical CO of any one of claims 1 to 92The system is applied to the fields of refrigeration and heating and heat pumps.
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| CN113513854A (en) * | 2021-08-09 | 2021-10-19 | 上海海洋大学 | Transcritical CO with high pressure ejector2Mechanical supercooling refrigerating system |
| CN114623620A (en) * | 2022-02-28 | 2022-06-14 | 河南科技大学 | Double-temperature-position injection compression refrigeration cycle device with expander |
| CN118998598A (en) * | 2024-08-12 | 2024-11-22 | 西安交通大学 | Propellant real-time supercooling and filling system and method based on ejector evacuation and decompression |
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