The present disclosure relates to the use of a composition as a refrigerant in a compressor, the compressor, and a refrigeration cycle apparatus.
Conventionally, hydrofluoroolefins (HFO refrigerants) having lower global warming potential (hereinafter also simply referred to as GWP) than HFC refrigerants have attracted attention for refrigeration apparatuses. For example, 1,2-difluoroethylene (HFO-1132) is considered as a refrigerant with low GWP in Patent Literature 1 (Japanese Patent Laid-Open No. 2019-196312).
The use of a composition as a refrigerant in a compressor according to a first aspect is the use of a composition as a refrigerant in a compressor in which the flow rate of the refrigerant flowing through a region around an ignition energy generation portion in the compressor under a predetermined high-pressure condition is greater than or equal to 1 m/s. The composition includes one or more compounds selected from the group consisting of ethylene-based fluoroolefins, 2,3,3,3-tetrafluoropropene (HFO-1234yf), and 1,3,3,3-tetrafluoropropene (HFO-1234ze).
Hereinafter, a compressor, a refrigeration cycle apparatus, and the use of a composition as a refrigerant in such a compressor or an apparatus will be specifically described with reference to examples. However, the following description is not intended to limit the present disclosure.
A refrigeration cycle apparatus 1 is an apparatus for performing vapor-compression refrigeration cycles to process a heat load of a target space. For example, the refrigeration cycle apparatus 1 is an air-conditioning apparatus for conditioning air in a target space.
The refrigeration cycle apparatus 1 mainly includes an outdoor unit 20; an indoor unit 30; a liquid-side refrigerant communication pipe 6 and a gas-side refrigerant communication pipe 5 each connecting the outdoor unit 20 and the indoor unit 30; a remote controller (not illustrated); and a controller 7 that controls the operation of the refrigeration cycle apparatus 1.
In the refrigeration cycle apparatus 1, refrigeration cycles are performed such that a refrigerant enclosed in a refrigerant circuit 10 is compressed, and is then cooled or condensed, and is then decompressed, and is then heated or evaporated, and is then compressed again. In the present embodiment, the refrigerant circuit 10 is filled with a refrigerant for performing vapor-compression refrigeration cycles.
Examples of the refrigerant filling the refrigerant circuit 10 include one or more compounds selected from the group consisting of ethylene-based fluoroolefins, 2,3,3,3-tetrafluoropropene (HFO-1234yf), and 1,3,3,3-tetrafluoropropene (HFO-1234ze). Note that regarding the burning velocity defined by the ISO 817, 1,3,3,3-tetrafluoropropene (HFO-1234ze) with a burning velocity of 1.2 cm/s is more preferable than 2,3,3,3-tetrafluoropropene (HFO-1234yf) with a burning velocity of 1.5 cm/s. Regarding the LFL (Lower Flammability Limit) defined by the ISO 817, 1,3,3,3-tetrafluoropropene (HFO-1234ze) with a LFL of 65000 vol.ppm or 6.5% is more preferable than 2,3,3,3-tetrafluoropropene (HFO-1234yf) with a LFL of 62000 vol.ppm or 6.2%. In particular, the refrigerant may include one or more compounds selected from the group consisting of 1,2-difluoroethylene (HFO-1132), 1,1-difluoroethylene (HFO-1132a), 1,1,2-trifluoroethylene (HFO-1123), monofluoroethylene (HFO-1141), and perhaloolefins. Above all, the refrigerant, including 1,2-difluoroethylene (HFO-1132) and/or 1,1,2-trifluoroethylene (HFO-1123), is preferable.
Herein, examples of ethylene-based fluoroolefins include 1,2-difluoroethylene (HFO-1132), 1,1-difluoroethylene (HFO-1132a), 1,1,2-trifluoroethylene (HFO-1123), monofluoroethylene (HFO-1141), and perhaloolefins. Examples of perhaloolefins include chlorotrifluoroethylene (CFO-1113) and tetrafluoroethylene (FO-1114).
Note that the refrigerant circuit 10 is also filled with refrigerator oil together with the aforementioned refrigerant.
The outdoor unit 20 is connected to the indoor unit 30 via the liquid-side refrigerant communication pipe 6 and the gas-side refrigerant communication pipe 5, and consists part of the refrigerant circuit 10. The outdoor unit 20 mainly includes a compressor 21, a four-way switching valve 22, an outdoor heat exchanger 23, an outdoor expansion valve 24, an outdoor fan 25, a receiver 41, a gas-side shut-off valve 28, and a liquid-side shut-off valve 29.
The compressor 21 is a device that compresses a low-pressure refrigerant in a refrigeration cycle up to a high pressure. Herein, the compressor 21 may be a hermetic compressor in which a rotary-type or scroll-type positive-displacement compression element is rotationally driven by a compressor motor. In the present embodiment, a rotary compressor is used. The compressor motor is used to change the volume, and its operating frequency can be controlled with an inverter.
The four-way switching valve 22 switches a flow channel of the refrigerant circuit 10. Specifically, the four-way switching valve 22 can switch between a state in which the discharge side of the compressor 21 and the outdoor heat exchanger 23 are connected and the suction side of the compressor 21 and the gas-side shut-off valve 28 are connected and a state in which the discharge side of the compressor 21 and the gas-side shut-off valve 28 are connected and the suction side of the compressor 21 and the outdoor heat exchanger 23 are connected.
The outdoor heat exchanger 23 is a heat exchanger that functions as a radiator or a condenser for a high-pressure refrigerant in a refrigeration cycle during the cooling operation, and functions as an evaporator for a low-pressure refrigerant in a refrigeration cycle during the heating operation.
The outdoor expansion valve 24 is provided between the liquid-side outlet of the outdoor heat exchanger 23 and the liquid-side shut-off valve 29 in the refrigerant circuit 10. The outdoor expansion valve 24 is a motor-operated expansion valve with an adjustable opening degree.
The outdoor fan 25 produces an air flow for causing outdoor air to be sucked into the outdoor unit 20, and causing the sucked air to exchange heat with a refrigerant in the outdoor heat exchanger 23, and then causing the air to be discharged to the outside. The outdoor fan 25 is rotationally driven by an outdoor fan motor.
The receiver 41 is a refrigerant container that is provided between the suction side of the compressor 21 and one of connection ports of the four-way switching valve 22, and that can store an excess refrigerant in the refrigerant circuit 10 as a liquid refrigerant.
The liquid-side shut-off valve 29 is a manual valve disposed at a portion of the outdoor unit 20 connected to the liquid-side refrigerant communication pipe 6.
The gas-side shut-off valve 28 is a manual valve disposed at a portion of the outdoor unit 20 connected to the gas-side refrigerant communication pipe 5.
The outdoor unit 20 includes an outdoor unit controller 27 that controls the operation of each portion forming the outdoor unit 20. The outdoor unit controller 27 has a microcomputer including a CPU and a memory, for example. The outdoor unit controller 27 is connected to an indoor unit controller 34 of each indoor unit 30 via a communication line, and transmits and receives control signals, for example.
The outdoor unit 20 is provided with a discharge pressure sensor 61, a discharge temperature sensor 62, a suction pressure sensor 63, a suction temperature sensor 64, an outdoor heat exchange temperature sensor 65, and an outdoor air temperature sensor 66, for example. Each of such sensors is electrically connected to the outdoor unit controller 27, and transmits a detection signal to the outdoor unit controller 27. The discharge pressure sensor 61 detects the pressure of a refrigerant flowing through a discharge pipe that connects the discharge side of the compressor 21 and one of the connection ports of the four-way switching valve 22. The discharge temperature sensor 62 detects the temperature of the refrigerant flowing through the discharge pipe. The suction pressure sensor 63 detects the pressure of a refrigerant flowing through a suction pipe that connects the suction side of the compressor 21 and the receiver 41. The suction temperature sensor 64 detects the temperature of the refrigerant flowing through the suction pipe. The outdoor heat exchange temperature sensor 65 detects the temperature of a refrigerant flowing through the liquid-side outlet of the outdoor heat exchanger 23 on the side opposite to the side connecting to the four-way switching valve 22. The outdoor air temperature sensor 66 detects the temperature of outdoor air before it passes through the outdoor heat exchanger 23.
The indoor unit 30 is disposed on an indoor wall surface or ceiling as a target space, for example. The indoor unit 30 is connected to the outdoor unit 20 via the liquid-side refrigerant communication pipe 6 and the gas-side refrigerant communication pipe 5, and consists part of the refrigerant circuit 10.
The indoor unit 30 includes an indoor heat exchanger 31 and an indoor fan 32.
The indoor heat exchanger 31 is connected on its liquid side to the liquid-side refrigerant communication pipe 6, and is connected on its gas side to the gas-side refrigerant communication pipe 5. The indoor heat exchanger 31 is a heat exchanger that functions as an evaporator for a low-pressure refrigerant in a refrigeration cycle during the cooling operation, and functions as a condenser for a high-pressure refrigerant in a refrigeration cycle during the heating operation.
The indoor fan 32 produces an air flow for causing indoor air to be sucked into the indoor unit 30, and causing the sucked air to exchange heat with a refrigerant in the indoor heat exchanger 31, and then causing the air to be discharged to the outside. The indoor fan 32 is rotationally driven by an indoor fan motor.
The indoor unit 30 includes the indoor unit controller 34 that controls the operation of each unit forming the indoor unit 30. The indoor unit controller 34 includes a microcomputer including a CPU and a memory, for example. The indoor unit controller 34 is connected to the outdoor unit controller 27 via the communication line, and transmits and receives control signals, for example.
The indoor unit 30 is provided with an indoor liquid-side heat exchange temperature sensor 71 and an indoor air temperature sensor 72, for example. Each of such sensors is electrically connected to the indoor unit controller 34, and transmits a detection signal to the indoor unit controller 34. The indoor liquid-side heat exchange temperature sensor 71 detects the temperature of a refrigerant flowing through the liquid-refrigerant-side outlet of the indoor heat exchanger 31. The indoor air temperature sensor 72 detects the temperature of indoor air before it passes through the indoor heat exchanger 31.
In the refrigeration cycle apparatus 1, the outdoor unit controller 27 and the indoor unit controller 34 are connected via the communication line, thus consisting the controller 7 that controls the operation of the refrigeration cycle apparatus 1.
The controller 7 mainly includes a CPU (central processing unit) and a memory, such as ROM and RAM. Note that various processes and control performed by the controller 7 are implemented as the portions, which are included in the outdoor unit controller 27 and/or the indoor unit controller 34, function in an integrated manner.
The refrigeration cycle apparatus 1 can execute at least a cooling operation mode and a heating operation mode.
The controller 7 determines whether the instruction indicates the cooling operation mode or the heating operation mode, based on an instruction received from the remote controller or the like, and executes the mode.
In the cooling operation mode, the operating frequency of the compressor 21 is controlled to control the volume so that the evaporating temperature of the refrigerant in the refrigerant circuit 10 reaches a target evaporating temperature, for example.
The gaseous refrigerant discharged from the compressor 21 is condensed in the outdoor heat exchanger 23 via the four-way switching valve 22. The refrigerant that has flowed through the outdoor heat exchanger 23 is decompressed while passing through the outdoor expansion valve 24.
The refrigerant decompressed in the outdoor expansion valve 24 flows through the liquid-side refrigerant communication pipe 6 via the liquid-side shut-off valve 29, and is then sent to the indoor unit 30. After that, the refrigerant evaporates in the indoor heat exchanger 31, and then flows into the gas-side refrigerant communication pipe 5. The refrigerant that has flowed through the gas-side refrigerant communication pipe 5 is sucked into the compressor 21 again via the gas-side shut-off valve 28, the four-way switching valve 22, and the receiver 41.
In the heating operation mode, the operating frequency of the compressor 21 is controlled to control the volume so that the condensation temperature of the refrigerant in the refrigerant circuit 10 reaches a target condensation temperature, for example.
The gaseous refrigerant discharged from the compressor 21 flows through the four-way switching valve 22 and the gas-side refrigerant communication pipe 5, and then flows into the gas-side end of the indoor heat exchanger 31 of the indoor unit 30 so that the refrigerant is condensed or is allowed to radiate heat in the indoor heat exchanger 31. The refrigerant, which has been condensed or has been allowed to radiate heat in the indoor heat exchanger 31, flows through the liquid-side refrigerant communication pipe 6, and then flows into the outdoor unit 20.
The refrigerant that has passed through the liquid-side shut-off valve 29 of the outdoor unit 20 is decompressed in the outdoor expansion valve 24. The refrigerant that has been decompressed in the outdoor expansion valve 24 evaporates in the outdoor heat exchanger 23, and is sucked into the compressor 21 again via the four-way switching valve 22 and the receiver 41.
The compressor 21 of the present embodiment is a one-cylinder rotary compressor as illustrated in
The drive mechanism 82 is housed in the upper part of the internal space of the casing 81, and drives the compression mechanism 88. The drive mechanism 82 includes a motor 83 as a drive source, and a crankshaft 84 as a drive shaft attached to the motor 83.
The motor 83 is a motor for rotationally driving the crankshaft 84, and mainly includes a rotor 85 and a stator 86. The rotor 85 has the crankshaft 84 fit-inserted in its internal space, and rotates together with the crankshaft 84. The rotor 85 includes laminated electromagnetic steel plates and a magnet embedded in a rotor body. The stator 86 is disposed radially outward of the rotor 85 with a predetermined space from the rotor 85. The stator 86 is disposed while being divided into a plurality of sections at predetermined intervals in the circumferential direction. That is, the stator 86 includes a plurality of sections provided in the circumferential direction each including laminated electromagnetic steel plates and a coil 86a wound around a stator body 86c having teeth 86b. In the motor 83, the rotor 85 is caused to rotate together with the crankshaft 84 with an electromagnetic force that is generated in the stator 86 as a current is passed through the coil 86a. The coil 86a of the stator 86 is supplied with power via a wire (not illustrated) connected to a terminal portion 98 provided at the upper end of the casing 81.
The crankshaft 84 is fit-inserted in the rotor 85, and rotates about the rotation axis. As illustrated in
The compression mechanism 88 is housed in the lower part of the casing 81. The compression mechanism 88 compresses a refrigerant sucked thereinto via a suction pipe 99. The compression mechanism 88 is a rotary compression mechanism, and mainly includes a front head 91, a cylinder 92, the piston 89, and a rear head 93. A refrigerant compressed in a compression chamber S1 of the compression mechanism 88 is discharged to a space in which the motor 83 is disposed and the lower end of a discharge pipe 95 is located from a front-head discharge hole 91c formed in the front head 91 via a muffler space S2 surrounded by the front head 91 and a muffler 94.
The cylinder 92 is a metal cast member. The cylinder 92 includes a cylindrical central portion 92a, a first extension portion 92b extending radially outward from the central portion 92a to one side, and a second extension portion 92c extending from the central portion 92a to a side opposite to the first extension portion 92b. The first extension portion 92b has formed therein a suction hole 92e for sucking a low-pressure refrigerant in a refrigeration cycle. A cylindrical space on the inner side of an inner peripheral face 92a1 of the central portion 92a corresponds to a cylinder chamber 92d into which a refrigerant sucked through the suction hole 92e flows. The suction hole 92e extends from the cylinder chamber 92d to an outer peripheral face of the first extension portion 92b, and is open at the outer peripheral face of the first extension portion 92b. The suction hole 92e has inserted therein the tip end portion of the suction pipe 99. In addition, the cylinder chamber 92d houses the piston 89 for compressing a refrigerant that has flowed into the cylinder chamber 92d, for example.
The cylinder chamber 92d, which is formed by the cylindrical central portion 92a of the cylinder 92, has at its lower end a first end that is open, and has at its upper end a second end that is open. The first end that is the lower end of the central portion 92a is closed by the rear head 93 described below. The second end that is the upper end of the central portion 92a is closed by the front head 91 described below.
The cylinder 92 has formed therein a blade oscillation space 92f in which a bushing 89c and a blade 89b described below are disposed. The blade oscillation space 92f is formed across a region from the central portion 92a to the first extension portion 92b, and the blade 89b of the piston 89 is oscillatably supported on the cylinder 92 via the bushing 89c. The blade oscillation space 92f is formed to extend toward the outer periphery side from the cylinder chamber 92d around the suction hole 92e as seen in plan view.
As illustrated in
The front-head disc portion 91b has formed therein the front-head discharge hole 91c at a plane position illustrated in
As illustrated in
The muffler 94 has formed therein a central muffler opening (not illustrated) for passing the upper bearing portion 91a, and a muffler discharge hole (not illustrated) through which a refrigerant is flowed from the muffler space S2 to a housing space for the motor 83 above the muffler space S2.
Note that the muffler space S2, the housing space for the motor 83, the space where the discharge pipe 95 is located above the motor 83, and a space where lubricating oil accumulates below the compression mechanism 88, for example, are all continuous, and form a high-pressure space with equal pressure.
The rear head 93 includes a rear-head disc portion 93b that closes the opening at the first end, which is the lower end, of the cylinder 92, and a lower bearing portion 93a as a bearing extending downward from the peripheral edge portion of the opening in the center of the rear-head disc portion 93b. The front-head disc portion 91b, the rear-head disc portion 93b, and the central portion 92a of the cylinder 92 form the cylinder chamber 92d as illustrated in
The piston 89 is disposed in the cylinder chamber 92d, and is attached to the crankpin 84a that is the eccentric portion of the crankshaft 84. The piston 89 is a member integrating the roller 89a and the blade 89b. The blade 89b of the piston 89 is disposed in the blade oscillation space 92f formed in the cylinder 92, and is oscillatably supported on the cylinder 92 via the bushing 89c as described above. The blade 89b is slidable on the bushing 89c, and oscillates and also repeatedly moves away from the crankshaft 84 and closer to the crankshaft 84 during operation.
As illustrated in
In the foregoing compressor 21, the volume of the compression chamber S1 changes with the movement of the piston 89 of the compression mechanism 88 that revolves with the eccentric rotation of the crankpin 84a. Specifically, first, while the piston 89 starts revolving, a low-pressure refrigerant is sucked into the compression chamber S1 through the suction hole 92e. The volume of the compression chamber S1 facing the suction hole 92e gradually increases while it sucks the refrigerant. When the piston 89 further revolves, the communication state between the compression chamber S1 and the suction hole 92e is canceled so that the refrigerant starts to be compressed in the compression chamber S1. After that, the volume of the compression chamber S1 that communicates with the front-head discharge hole 91c becomes significantly small, and the pressure of the refrigerant therein increases. After that, as the piston 89 further revolves, the refrigerant with the increased pressure pushes and opens the discharge valve through the front-head discharge hole 91c, and thus is discharged to the muffler space S2. The refrigerant introduced into the muffler space S2 is discharged to a space above the muffler space S2 through the muffler discharge hole of the muffler 94. The refrigerant discharged to the outside of the muffler space S2 passes through a space between the rotor 85 and the stator 86 of the motor 83 to cool the motor 83, and is then discharged from the discharge pipe 95.
During operation in the cooling operation mode and operation in the heating operation mode, for example, the controller 7 controls the operating frequency of the compressor 21 to control its volume so as to attain a predetermined target evaporating temperature and a predetermined target condensation temperature, respectively, as target values.
Herein, even when a disproportionation reaction of a refrigerant has occurred in the compressor 21, the controller 7 controls the compressor so as to suppress the propagation of the disproportionation reaction to a region around the portion where the disproportionation reaction has occurred.
During the control, the controller 7 controls the operating frequency so that the flow rate of a gaseous refrigerant flowing through a region around the ignition energy generation portion becomes greater than or equal to 1 m/s when the compressor 21 has entered an operation state in which its discharge pressure is greater than or equal to 1 MPa. Herein, the controller 7 performs control of increasing the operating frequency in the aforementioned volume control if necessary for allowing the flow rate of the gaseous refrigerant flowing through the region around the ignition energy generation portion to become greater than or equal to 1 m/s. Herein, the way of controlling the flow rate of the gaseous refrigerant flowing through the region around the ignition energy generation portion to be greater than or equal to 1 m/s is not limited. For example, it is possible to conduct a simulation analysis to identify in advance data on a relational expression or a correspondence table in which a parameter including the operating frequency of the compressor 21 is associated with the flow rate of a refrigerant flowing through the region around the ignition energy generation portion, and store the data in a memory so as to control the operating frequency of the compressor 21 based on the data. The region around the ignition energy generation portion may be in the range of 5 cm, 3 cm, or 1 cm from the ignition energy generation portion, for example. Alternatively, the region around the ignition energy generation portion may be a portion where the flow rate is the lowest in the range of 5 cm, 3 cm, or 1 cm from the ignition energy generation portion, for example.
Note that the controller 7 can use the pressure of the refrigerant detected by the discharge pressure sensor 61 as the discharge pressure of the compressor 21.
Examples of the ignition energy generation portion include a region around the coil 86a, a region around the upper bearing portion 91a, and a region around the lower bearing portion 93a.
In the region around the coil 86a, energy needed for ignition is likely to be generated due to a current flow therethrough when an insulating film for an electric wire has a production defect generated during the production of the coil 86a or when the insulating film has peeled off due to contact with something.
In each of the region around the upper bearing portion 91a and the region around the lower bearing portion 93a, energy needed for ignition is likely to be generated on the sliding surface between the portion and the crankshaft 84 due to friction while the compressor 21 is driven.
In the refrigeration cycle apparatus 1 of the present embodiment, a refrigerant that may undergo a disproportionation reaction is used. Such a disproportionation reaction of the refrigerant occurs with a certain probability under an environment where predetermined high-temperature conditions, high-pressure conditions, and ignition energy conditions are satisfied. Then, the disproportionation reaction may propagate to surrounding regions from the portion where the disproportionation reaction has occurred.
In response, the inventors used 1,2-difluoroethylene (HFO-1132) as the refrigerant, and prepared a predetermined flow channel connecting to an ignition source to conduct a test of observing a view in which a disproportionation reaction generated in the ignition source propagates, using a super slow camera while changing the flow rate of the refrigerant. The test results demonstrate that the propagation of the disproportionation reaction can be suppressed more when the flow rate of the refrigerant is greater than or equal to 1 m/s than when the flow rate of the refrigerant is less than 1 m/s, and also demonstrate that the effects of suppressing the propagation of the disproportionation reaction are more excellent when the flow rate of the refrigerant is even greater.
In response, the inventors conducted a simulation to analyze a flow rate distribution of a refrigerant in the compressor 21.
The compressor 21 for which the refrigerant of the present embodiment is used, and the refrigeration cycle apparatus 1 including such a compressor 21 are configured such that the flow rate of a refrigerant flowing through a region around the coil 86a, the upper bearing portion 91a, or the lower bearing portion 93a, each corresponding to the ignition energy generation portion in the compressor 21, under a predetermined high-pressure condition becomes greater than or equal to 1 m/s. Accordingly, even when an unstable refrigerant is used in the compressor 21 and the refrigeration cycle apparatus 1 of the present embodiment, and such a refrigerant has undergone a disproportionation reaction in the compressor 21, it is possible to suppress the propagation of the disproportionation reaction to a region around the portion where the disproportionation reaction has occurred.
The foregoing embodiment has exemplarily illustrated a case where the operating frequency is controlled such that the flow rate of a gaseous refrigerant flowing through a region around the coil 86a, the upper bearing portion 91a, or the lower bearing portion 93a, each corresponding to the ignition energy generation portion, becomes greater than or equal to 1 m/s when the compressor 21 has entered an operation state in which its discharge pressure is greater than or equal to 1 MPa.
In contrast, it is also possible to control the operating frequency such that the flow rate of a gaseous refrigerant flowing through a region around the coil 86a, the upper bearing portion 91a, or the lower bearing portion 93a, each corresponding to the ignition energy generation portion, becomes greater than or equal to 1 m/s when the compressor 21 has entered an operation state in which its discharge pressure is greater than or equal to 3 MPa or greater than or equal to 5 MPa, which is more likely to cause a disproportionation reaction.
The foregoing embodiment has exemplarily illustrated a case where the flow rate of a refrigerant flowing through a region around the coil 86a, the upper bearing portion 91a, or the lower bearing portion 93a, each corresponding to the ignition energy generation portion, is controlled to be greater than or equal to 1 m/s so that the propagation of a disproportionation reaction is suppressed.
In contrast, the flow rate to be controlled is not limited to 1 m/s. For example, the flow rate of a refrigerant flowing through a region around the ignition energy generation portion may be controlled to be greater than or equal to 3 m/s, or greater than or equal to 5 m/s, or further, greater than or equal to 10 m/s. In this manner, the higher the flow rate of a refrigerant flowing through a region around the ignition energy generation portion in the compressor 21, the more effectively the propagation of a disproportionation reaction can be suppressed.
The foregoing embodiment has exemplarily illustrated a case where a rotary compressor is used as the compressor 21.
In contrast, the compressor for suppressing the propagation of a disproportionation reaction by increasing the flow rate of a refrigerant flowing through a region around the ignition energy generation portion is not limited to a rotary compressor, and may be a known scroll compressor or swing compressor.
Note that the ignition energy generation portion in the compressor under a predetermined high-pressure condition is not limited. For example, when the compressor includes a teeth and a coil wound around the teeth, the ignition energy generation portion may include the coil in the compressor. In addition, when the compressor includes a crankshaft and a bearing portion that rotatably supports the crankshaft, for example, the ignition energy generation portion may include a portion where the crankshaft and the bearing portion are in contact with each other.
Note that the compressor may be a compressor in which the flow rate of a refrigerant flowing through a region around an ignition energy generation portion in the compressor under a predetermined high-pressure condition is greater than or equal to 5 m/s, or greater than or equal to 10 m/s. The higher the flow rate of the refrigerant flowing through the region around the ignition energy generation portion in the compressor, the more effectively the propagation of disproportionation can be suppressed.
Note that 1,2-difluoroethylene may be trans-1,2-difluoroethylene [(E)-HFO-1132], cis-1,2-difluoroethylene [(Z)-HFO-1132], or a mixture of them. (Supplement)
Although the embodiments of the present disclosure have been described above, it is to be understood that various changes to the forms or details are possible without departing from the spirit or scope of the present disclosure recited in the claims.
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[Patent Literature 1] Japanese Patent Laid-Open No. 2019-196312
Number | Date | Country | Kind |
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2020-115911 | Jul 2020 | JP | national |
This application is a Continuation of PCT International Application No. PCT/JP2021/025309, filed on Jul. 5, 2021, which claims priority under 35 U.S.C. 119(a) to Patent Application No. 2020-115911, filed in Japan on Jul. 3, 2020, all of which are hereby expressly incorporated by reference into the present application.
Number | Date | Country | |
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Parent | PCT/JP2021/025309 | Jul 2021 | WO |
Child | 18091670 | US |