JP2009210249A - Fluid machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a compact fluid machine applied to a refrigerant circuit performing a refrigerating cycle by circulating a refrigerant, and collecting energy caused by a pressure rise of oil. <P>SOLUTION: The refrigerant circuit 11 is provided with an oil power recovery type compression unit C/O. The oil power recovery-type compression unit C/O is composed of a power recovering mechanism 40 and a compressing mechanism 20 accommodated in a casing 40a. In the power recovering mechanism 40, a piston 50 is rotated and driven by oil separated from the high-pressure refrigerant, and rotating power is recovered as the driving power of the compressing mechanism 20 through an output shaft 42. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a fluid machine connected to a refrigerant circuit that performs a refrigeration cycle by circulating refrigerant.

  Conventionally, a refrigeration apparatus including a refrigerant circuit that performs a refrigeration cycle has been widely applied to air conditioning apparatuses that perform indoor air conditioning.

  Patent Document 1 discloses this type of air conditioner. The air conditioner is provided with a refrigerant circuit that performs a refrigeration cycle by circulating the refrigerant. A compressor, an indoor heat exchanger, an expansion valve, an outdoor heat exchanger, and the like are connected to the refrigerant circuit. For example, during the cooling operation of the air conditioner, the refrigerant compressed by the compressor is condensed (radiated) by the outdoor heat exchanger and then decompressed by the expansion valve. The refrigerant after decompression evaporates in the indoor heat exchanger, thereby cooling the room air and cooling it.

In the refrigerant circuit described in the document, oil (refrigerator oil) for lubricating the sliding portion of the compressor is mixed. That is, in the compression mechanism of the compressor, the piston, the bearing portion of the drive shaft, and the like are lubricated with oil. This oil is discharged from the compressor together with the refrigerant. Therefore, the refrigerant circuit is provided with an oil separator on the discharge side of the compressor. In the oil separator, oil is separated from the high-pressure refrigerant. The separated oil flows into the oil return pipe, is decompressed by the capillary tube, and then supplied to the compressor.
JP 2007-147212 A

  As disclosed in Patent Document 1, the oil separated from the high-pressure refrigerant is depressurized by a capillary tube or the like and then sent to the suction side of the compressor. In other words, in the conventional refrigeration system, the energy of the oil is wasted by the decompression mechanism such as the capillary tube even though the compressor spends energy for boosting the oil, resulting in the efficiency of the compressor. Has led to a decline.

  The present invention has been made in view of such a point, and an object of the present invention is to apply a compact fluid machine that can be applied to a refrigerant circuit in which a refrigerant circulates and performs a refrigeration cycle to recover energy caused by oil pressure increase. It is to propose.

  The first invention is directed to a fluid machine, and is driven to rotate by oil separated from high-pressure refrigerant compressed by a compression mechanism (20) of a refrigerant circuit (11) in which a refrigerant circulates and performs a refrigeration cycle. A power recovery mechanism (40) having a portion (50) and an output shaft (42) connected to the movable portion (50), and connected to an output shaft (42) of the power recovery mechanism (40). And a casing (40a) for accommodating the power recovery mechanism (40) and the drive target (20, 45) therein. is there.

  In the fluid machine of the first invention, the power recovery mechanism (40) and the predetermined drive target (20, 45) are accommodated in the casing (40a). The power recovery mechanism (40) includes a movable part (50) and an output shaft (42), and the movable part (50) and the drive target (20, 45) are connected to each other by the output shaft (42).

  On the other hand, in the refrigerant circuit (11) to which the fluid machine of the present invention is applied, a refrigeration cycle is performed by circulating the refrigerant, and indoor cooling or the like is performed by the refrigerant. Here, the said movable part (50) is rotationally driven by the motive power (namely, energy which oil has) isolate | separated from the high pressure refrigerant | coolant of a refrigerant circuit (11). In other words, the oil separated from the high-pressure refrigerant has the power used to pressurize the oil in the compression mechanism (20) as energy such as kinetic energy, potential energy, and pressure energy. The movable part (50) is driven by the energy of such high-pressure oil. When the movable part (50) is driven, the output shaft (42) connected to the movable part (50) is also rotationally driven. As a result, the drive target is driven by the rotational power of the output shaft (42). As described above, in the fluid machine of the present invention, the energy of the oil separated from the high-pressure refrigerant is recovered as the driving power of the driving object (20, 45).

  According to a second aspect of the present invention, in the fluid machine according to the first aspect of the present invention, the drive target is composed of the compression mechanism (20).

  In the casing (40a) of the fluid machine of the second invention, the compression mechanism (20) as the drive target and the movable part (50) of the power recovery mechanism (40) are mutually connected via the output shaft (42). Connected. When the movable part (50) is rotationally driven by the energy of oil separated from the high-pressure refrigerant, the output shaft (42) is also rotationally driven, and the compression mechanism (20) is further driven. As described above, in the fluid machine of the present invention, the energy of oil separated from the high-pressure refrigerant is recovered as the compression power of the refrigerant by the compression mechanism (20).

  According to a third invention, in the fluid machine according to the second invention, the casing (40a) is rotationally driven by the refrigerant of the refrigerant circuit (11) and is output to the output shaft (42) of the power recovery mechanism (40). Further, an expansion mechanism (30) connected to the valve is accommodated.

  In the casing (40a) of the fluid machine of the third invention, the movable part (50) of the power recovery mechanism (40) and the movable part of the expansion mechanism (30) are connected to each other via the output shaft (42). . The movable part (50) of the power recovery mechanism (40) is rotationally driven by the oil, whereby the output shaft (42) is also rotationally driven. In addition, the movable part of the expansion mechanism (30) is also rotationally driven by the power of the refrigerant expanding in the expansion mechanism (30). That is, the movable part of the expansion mechanism (30) is driven by power obtained by expansion of the refrigerant (that is, expansion power). The output shaft (42) of the present invention is rotationally driven by both the movable part (50) of the power recovery mechanism (40) and the movable part of the expansion mechanism (30). As a result, in the present invention, the compression power recovered by the compression mechanism (20) increases.

  According to a fourth aspect of the present invention, in the fluid machine according to any one of the first to third aspects, the casing (40a) includes an electric motor (25) that rotationally drives the output shaft (42) of the power recovery mechanism (40). Furthermore, it is accommodated.

  An electric motor (25) is also accommodated in the casing (40a) of the fluid machine of the fourth invention, and the electric motor (25) rotationally drives the output shaft (42). That is, in the present invention, when only the power recovered by the power recovery mechanism (40) or the expansion mechanism (30) is insufficient for the drive power of the drive target (20, 45), this shortage is caused by the electric motor (25). Power can be supplemented. As a result, a desired operation can be performed on the drive target (20, 45).

  According to a fifth aspect of the invention, in the fluid machine according to the first aspect of the invention, the drive target is constituted by a generator (45).

  In the casing (40a) of the fluid machine of the fifth invention, the generator (45) as the drive target and the movable part (50) of the power recovery mechanism (40) are mutually connected via the output shaft (42). Connected. When the movable part (50) is rotationally driven by the power of the oil separated from the high-pressure refrigerant, that is, the energy of the oil, the output shaft (42) is also rotationally driven, and the generator (45) is further driven. As described above, in the fluid machine of the present invention, the energy of the oil separated from the high-pressure refrigerant is recovered as driving power for the generator (45), and electric power is generated in the generator (45).

  According to a sixth invention, in the fluid machine according to the fifth invention, the casing (40a) is rotationally driven by the refrigerant of the refrigerant circuit (11) and is output to the output shaft (42) of the power recovery mechanism (40). And an expansion mechanism (30) having a movable portion connected to the housing.

  In the casing (40a) of the fluid machine of the sixth aspect of the invention, the movable part (50) of the power recovery mechanism (40) and the movable part of the expansion mechanism (30) are connected to each other via the output shaft (42). . The movable part (50) of the power recovery mechanism (40) is rotationally driven by the oil, whereby the output shaft (42) is also rotationally driven. In addition, the movable part of the expansion mechanism (30) is also rotationally driven by the power of the refrigerant expanding in the expansion mechanism (30). That is, the movable part of the expansion mechanism (30) is driven by power obtained by expansion of the refrigerant (that is, expansion power). The output shaft (42) of the present invention is rotationally driven by both the movable part (50) of the power recovery mechanism (40) and the movable part of the expansion mechanism (30). As a result, in the present invention, the driving power recovered by the generator (45) increases, and the electric power generated by the generator (45) also increases.

  In the present invention, the power of the oil separated from the high-pressure refrigerant, that is, the energy of the oil is used to rotate the movable part (50) of the power recovery mechanism (40) to rotate it through the output shaft (42). The target (20, 45) is driven. That is, in the case of the conventional one, the energy of the oil after the pressure increase is wasted by a pressure reducing mechanism such as a capillary tube. In the present invention, such energy of the oil is given to a predetermined driving object (20, 20 45) can be recovered as drive power. Therefore, it is possible to improve the energy saving performance of the system of the refrigerant circuit (11) to which the fluid machine is applied. Further, according to the present invention, the power recovery mechanism (40) and the predetermined drive target (20, 45) are integrally accommodated in the casing (40a), so that the fluid machine can be configured compactly, In addition, the installation of the fluid machine on site is also simplified.

  According to the second invention, the compression mechanism (20) can be driven by the energy of the oil recovered by the power recovery mechanism (40), and the compression power of the compression mechanism (20) can be reduced. Moreover, this fluid machine can be comprised compactly by accommodating a power recovery mechanism (40) and a compression mechanism (20) integrally in a casing (40a).

  Further, according to the third invention, the compression mechanism (20) is driven by the energy of the oil recovered by the power recovery mechanism (40) and the energy of the refrigerant recovered by the expansion mechanism (30) (ie, expansion power). Therefore, the compression power of the compression mechanism (20) can be further reduced. Further, the fluid recovery mechanism (40), the expansion mechanism (30), and the compression mechanism (20) are integrally housed in the casing (40a), whereby the fluid machine can be configured compactly.

  In the fourth invention, by accommodating the electric motor (25) in the casing (40a), the fluid machine can be made more compact, and the shortage of the compression power of the compression mechanism (20) can be reduced by the electric motor (25). Can be supplemented by.

  According to the fifth aspect of the invention, the generator (45) can be driven by the energy of the oil recovered by the power recovery mechanism (40), and the refrigerant generated using the electric power generated by the generator (45). The energy saving property of the circuit (11) can be improved. Moreover, this fluid machine can be comprised compactly by accommodating a power collection | recovery mechanism (40) and a generator (45) integrally in a casing (40a).

  Further, according to the sixth aspect of the invention, the generator (45) can be driven by the oil energy recovered by the power recovery mechanism (40) and the refrigerant energy recovered by the expansion mechanism (30). The energy saving performance of the system of (11) can be further improved. Moreover, the fluid machine can be made compact by housing the power recovery mechanism (40), the expansion mechanism (30), and the generator (45) integrally in the casing (40a).

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

Embodiment 1 of the Invention
Embodiment 1 of the present invention will be described. The fluid machine according to the present invention is applied to an air conditioner (10) constituting a refrigeration apparatus. The air conditioner (10) is configured to switch between a cooling operation and a heating operation.

<Overall configuration of air conditioner>
As shown in FIG. 1, the air conditioner (10) includes a refrigerant circuit (11). In the refrigerant circuit (11), a refrigeration cycle is performed by circulating the refrigerant. The refrigerant circuit (11) is filled with carbon dioxide (CO ₂ ) as a refrigerant. In the refrigerant circuit (11), a refrigeration cycle (so-called supercritical cycle) in which the refrigerant is compressed to a critical pressure or higher is performed. Furthermore, the refrigerant circuit (11) contains oil (refrigerating machine oil) made of polyalkylene glycol (PAG).

  The refrigerant circuit (11) includes an oil power recovery type compression unit (C / O), an expansion unit (E), an outdoor heat exchanger (12), an indoor heat exchanger (13), and a first four-way switching. A valve (14) and a second four-way switching valve (15) are provided. The refrigerant circuit (11) is provided with an oil separator (60), an oil introduction path (70), and an oil cooler (80).

  The oil power recovery type compression unit (C / O) has a vertically long sealed casing (40a). The oil power recovery type compression unit (C / O) includes a compression mechanism (20), a power recovery mechanism (40), and an electric motor (25) inside the casing (40a) to constitute a fluid machine. Yes. In the casing (40a), the main body (41), the electric motor (25), and the compression mechanism (20) of the power recovery mechanism (40) are arranged in this order from the upper part to the lower part. An oil sump (40b) for storing the oil is formed at the bottom of the casing (40a).

  The compression mechanism (20) is a driving target of the oil power recovery type compression unit (C / O), and constitutes a rotary positive displacement compressor. In the compression mechanism (20), the refrigerant is compressed to a critical pressure or higher in the compression chamber. The compression mechanism (20) is formed with a discharge port (27) for discharging the refrigerant compressed in the compression chamber into the casing (40a). Thereby, the inside of the casing (40a) is filled with the high-pressure refrigerant (discharge refrigerant) of the refrigerant circuit (11) to form a high-pressure atmosphere (Hp). That is, the oil power recovery type compression unit (C / O) of this embodiment is configured as a so-called high pressure dome type.

  The power recovery mechanism (40) has a main body (41) and an output shaft (42). The main body (41) of the power recovery mechanism (40) constitutes a rotary positive displacement fluid machine (details will be described later). The output shaft (42) extends in the casing (40a) in the axial direction, and connects the compression mechanism (20) and the main body (41) of the power recovery mechanism (40). An oil pump (42c) for pumping up the oil stored in the oil reservoir (40b) is provided at the lower end of the output shaft (42). The oil pumped up by the oil pump (42c) is appropriately supplied to a sliding portion such as a bearing of the compression mechanism (20) through an oil passage (not shown) formed in the output shaft (42).

  The electric motor (25) is interposed between the main body (41) of the power recovery mechanism (40) and the compression mechanism (20) and is connected to the output shaft (42). The electric motor (25) constitutes a motor that rotationally drives the output shaft (42), and is configured as an inverter type in which the output frequency (that is, the rotational speed of the output shaft) is variable.

  A suction pipe (22), a discharge pipe (23), an oil inflow pipe (43), and an oil outflow pipe (44) are connected to the oil power recovery type compression unit (C / O). The suction pipe (22) causes the refrigerant to be sucked into the compression mechanism (20). The suction pipe (22) passes through the body of the casing (40a) and is directly connected to the suction port of the compression mechanism (20). The discharge pipe (23) allows the refrigerant compressed by the compression mechanism (20) to flow out of the casing (40a). The discharge pipe (23) passes through the body of the casing (40a), and the start end thereof opens into the casing (40a). The oil inflow pipe (43) allows oil to flow into the main body (41) of the power recovery mechanism (40). The oil inflow pipe (43) penetrates the trunk part of the casing (40a) and is directly connected to the main body part (41). The oil outflow pipe (44) allows oil in the main body (41) of the power recovery mechanism (40) to flow out of the casing (40a). The oil spill pipe (44) passes through the body of the casing (40a) and is directly connected to the main body (41).

  The expansion unit (E) has a vertically long cylindrical expansion casing (30a). In the expansion unit (E), the expansion mechanism (30), the expansion side output shaft (31), and the expansion side generator (35) are accommodated in the expansion casing (30a) to form a fluid machine. . In the expansion casing (30a), the expansion mechanism (30) and the expansion-side generator (35) are arranged in this order from the top to the bottom. An oil sump (30b) for storing the oil is formed at the bottom of the expansion casing (30a).

  The expansion mechanism (30) constitutes a rotary positive displacement expansion mechanism. In the expansion mechanism (30), the refrigerant expands and decompresses in the expansion chamber. In the expansion mechanism (30), a piston (not shown) as a movable portion is rotationally driven by the refrigerant expanding in the expansion chamber, and the expansion-side output shaft (31) connected to the piston is further rotationally driven. Thereby, an expansion side generator (35) is driven and electric power generation is performed. The electric power generated by the expansion unit (E) is used as power for the oil power recovery type compression unit (C / O) and other element machines.

  An oil pump (31c) that pumps up the oil stored in the oil reservoir (30b) is provided at the lower end of the expansion side output shaft (31). The oil pumped up by the oil pump (31c) is appropriately supplied to a sliding portion such as a bearing of the expansion mechanism (30) through an oil passage (not shown) formed in the expansion side output shaft (31). The expansion unit (E) is provided with an inflow pipe (33) for allowing the refrigerant to flow into the expansion mechanism (30) and an outflow pipe (34) for allowing the refrigerant to flow out from the expansion mechanism (30). ing.

  The outdoor heat exchanger (12) is an air heat exchanger for exchanging heat between the refrigerant and outdoor air. The indoor heat exchanger (13) is an air heat exchanger for exchanging heat between the refrigerant and room air.

  The first four-way switching valve (14) and the second four-way switching valve (15) have first to fourth ports, respectively. In the first four-way switching valve (14), a first port is connected to the discharge pipe (23) via a discharge line (18), and a second port is connected to the suction pipe (17) via a suction line (17). 22) is connected. In the first four-way switching valve (14), the third port is connected to one end of the outdoor heat exchanger (12), and the fourth port is connected to one end of the indoor heat exchanger (13). In the second four-way switching valve (15), the first port is connected to the inflow pipe (33), and the second port is connected to the outflow pipe (34). In the second four-way switching valve (15), the third port is connected to the other end of the outdoor heat exchanger (12), and the fourth port is connected to the other end of the indoor heat exchanger (13). Yes.

  The first four-way switching valve (14) and the second four-way switching valve (15) are respectively a first port and a third port that communicate with each other and a second port and a fourth port that communicate with each other. 1 state (state indicated by a solid line in FIG. 1), and 2nd state (state indicated by a broken line in FIG. 1) in which the first port and the fourth port communicate with each other and the second port and the third port communicate with each other. It is comprised so that it may switch to.

  The oil separator (60) is provided in the middle of the discharge line (18). The oil separator (60) is composed of a vertically long, substantially cylindrical sealed container, and constitutes an oil separating means for separating oil from the high-pressure refrigerant. The oil separator (60) is connected with a refrigerant / oil inflow pipe (61) at its body, with a refrigerant discharge pipe (62) at its top and with an oil discharge pipe (63) at its bottom. ing. In the oil separator (60), oil is separated from the refrigerant flowing in from the refrigerant / oil inflow pipe (61). In addition, as an oil separation method in the oil separator (60), there are a method of centrifugal separation of oil using a swirl flow, a method of sedimentation separation of oil using a specific gravity difference between refrigerant and oil, and the like. Can be mentioned. In the oil separator (60), the refrigerant after the oil is separated flows out of the refrigerant discharge pipe (62), and the oil after the separation flows out of the oil discharge pipe (63).

  The oil introduction path (70) supplies the oil separated by the oil separator (60) to the compression mechanism (20). The oil introduction path (70) includes a first oil guide pipe (71) and a second oil guide pipe (72).

  The first oil guide pipe (71) has a start end connected to the oil discharge pipe (63) of the oil separator (60) and a terminal end connected to the oil inflow pipe (43). The second oil guiding pipe (72) has a start end connected to the oil outflow pipe (44) and a terminal end connected to the suction line (17). That is, the oil introduction path (70) of the present embodiment is configured to supply the oil separated by the oil separator (60) to the suction side of the compression mechanism (20).

  The second oil guide pipe (72) is provided with the oil cooler (80). The oil cooler (80) is a cooling means for cooling the oil separated by the oil separator (60), and is constituted by, for example, an air-cooled heat exchanger.

<Configuration of power recovery mechanism>
The configuration of the power recovery mechanism (40) will be further described with reference to FIGS.
The power recovery mechanism (40) recovers the power of the oil (that is, the energy of the oil). In other words, the oil separated from the high-pressure refrigerant has the power used to pressurize the oil in the compression mechanism (20) as energy such as kinetic energy, potential energy, and pressure energy. Therefore, the power recovery mechanism (40) recovers such oil energy as power. The main body (41) of the power recovery mechanism (40) is constituted by a so-called oscillating piston type rotary fluid machine. The output shaft (42) has one end connected to the main body (41) and the other end connected to the movable part (piston) of the compression mechanism (20). That is, the compression mechanism (20) constitutes a drive target that is driven in connection with the output shaft (42) of the power recovery mechanism (40). The output shaft (42) is formed with a main shaft portion (42a) and an eccentric portion (42b). The eccentric part (42b) is eccentric by a predetermined amount with respect to the main shaft part (42a) and is configured to have a larger diameter than the main shaft part (42a).

  The main body (41) of the power recovery mechanism (40) is provided with a front head (46), a cylinder (47), and a rear head (48) in order from bottom to top. The cylinder (47) is formed in a cylindrical shape through which the output shaft (42) passes vertically. The cylinder (47) has a lower end closed by the front head (46) and an upper end closed by the rear head (48).

  As shown also in FIG. 3, the piston (50) as a movable part is accommodated in the inside (cylinder chamber) of the cylinder (47). The piston (50) is formed in an annular shape or a cylindrical shape. The eccentric part (42b) of the output shaft (42) is engaged with the inside of the piston (50). The piston (50) has its outer peripheral surface in sliding contact with the inner peripheral surface of the cylinder (47), one end surface in sliding contact with the front head (46), and the other end surface in contact with the rear head (48). An oil chamber (49) is formed in the cylinder (47) between its inner peripheral surface and the outer peripheral surface of the piston (50). The oil inflow pipe (43) and the oil outflow pipe (44) communicate with the oil chamber (49).

  The piston (50) is integrally provided with a blade (51). The blade (51) is formed in a plate shape extending in the radial direction of the piston (50), and projects outward from the outer peripheral surface of the piston (50). The blade (51) is inserted into the blade groove (52) of the cylinder (47). The blade groove (52) of the cylinder (47) penetrates the cylinder (47) in the thickness direction, and opens to the inner peripheral surface of the cylinder (47).

  The cylinder (47) is provided with a pair of bushes (53). Each bush (53) is a small piece formed such that the inner surface is a flat surface and the outer surface is a circular arc surface. In the cylinder (47), the pair of bushes (53) are inserted into the bush holes (54) and sandwich the blade (51). The inner surface of the bush (53) is in sliding contact with the blade (51), and the outer surface of the bush (53) is slid with the cylinder (47). The blade (51) integrated with the piston (50) is supported by the cylinder (47) via the bush (53), and can rotate and advance and retract with respect to the cylinder (47).

  The oil chamber (49) in the cylinder (47) is partitioned by the piston (50) and the blade (51). The left chamber of the blade (51) in FIG. 3 communicates with the oil inflow pipe (43), and the right chamber communicates with the oil outflow pipe (44).

-Driving action-
The operation of the air conditioner (10) according to Embodiment 1 will be described. The air conditioner (10) can perform a cooling operation and a heating operation according to the settings of the first four-way switching valve (14) and the second four-way switching valve (15). First, the basic operation during the cooling operation of the air conditioner (10) will be described.

  During the cooling operation, the first four-way switching valve (14) and the second four-way switching valve (15) are set to the first state (the state indicated by the solid line in FIG. 1), and the refrigerant circulates in the refrigerant circuit (11). A compression refrigeration cycle is performed. As a result, during the cooling operation, a refrigeration cycle in which the outdoor heat exchanger (12) serves as a radiator (condenser) and the indoor heat exchanger (13) serves as an evaporator is performed. In the refrigerant circuit (11), the high pressure is set to a value higher than the critical pressure of carbon dioxide, which is a refrigerant, and a so-called supercritical cycle is performed.

  In the oil power recovery type compression unit (C / O), the compression mechanism (20) is rotationally driven by the electric motor (25). In the compression mechanism (20), the refrigerant sucked into the compression chamber from the suction pipe (22) is compressed, and the compressed refrigerant is discharged into the casing (40a). The high-pressure refrigerant in the casing (40a) passes around the electric motor (25) and flows out of the casing (40a) from the discharge pipe (23). The refrigerant that has flowed into the discharge pipe (23) flows through the discharge line (18) and flows into the oil separator (60) through the refrigerant / oil inflow pipe (61).

  In the oil separator (60), the oil is separated from the refrigerant, the refrigerant from which the oil has been separated accumulates at the top, and the separated oil accumulates at the bottom. The separated refrigerant flows out of the refrigerant discharge pipe (62) and flows through the outdoor heat exchanger (12). In the outdoor heat exchanger (12), the high-pressure refrigerant radiates heat to the outdoor air. The refrigerant that has flowed out of the outdoor heat exchanger (12) flows into the expansion mechanism (30) of the expansion unit (E) through the inflow pipe (33).

  In the expansion mechanism (30), the high-pressure refrigerant expands in the expansion chamber, whereby the expansion-side output shaft (31) is rotationally driven. As a result, the expansion-side generator (35) is driven and electric power is generated from the expansion-side generator (35). This electric power is supplied to the compression mechanism (20) and other element machines. The refrigerant expanded by the expansion mechanism (30) is sent out from the expansion unit (E) through the outflow pipe (34).

  The refrigerant that has flowed out of the expansion unit (E) flows through the indoor heat exchanger (13). In the indoor heat exchanger (13), the refrigerant absorbs heat from the indoor air and evaporates. As a result, the room air is cooled and cooling is performed. The refrigerant flowing out of the indoor heat exchanger (13) is sucked into the compression mechanism (20) through the suction pipe (22) and compressed again.

  During such cooling operation, the following oil injection operation is performed in order to improve the coefficient of performance (COP) of the air conditioner (10). Specifically, the oil separated by the oil separator (60) flows through the first oil guide pipe (71) through the oil discharge pipe (63) and flows into the main body (41) of the power recovery mechanism (40). .

  In the power recovery mechanism (40), the piston (50) is rotationally driven by the oil flowing through the oil chamber (49), and the piston (50) moves inside the cylinder (47) in (A) → (B) → ( Eccentric rotation in the order of C) → (D) → (A) →. With the eccentric rotation of the piston (50), the eccentric portion (42b) and further the main shaft portion (42a) are rotationally driven. As a result, this rotational power is used as driving power for driving the compression mechanism (20). As described above, in the oil power recovery type compression unit (C / O), the oil energy recovered by the power recovery mechanism (40) is recovered as driving power of the compression mechanism (20), and the compression mechanism (20) The power of is reduced.

  The oil whose energy has been recovered in the oil chamber (49) is depressurized to a predetermined pressure, and then flows out from the main body (41) through the oil outflow pipe (44). The refrigerant is cooled to a predetermined temperature by the oil cooler (80) when flowing through the second oil guide pipe (72). The cooled oil flows into the suction line (17) on the suction side of the compression mechanism (20) and is mixed with the refrigerant. Accordingly, the compression mechanism (20) is appropriately supplied with low-temperature oil together with the refrigerant, and an oil injection operation is performed.

  By this oil injection operation, in the compression mechanism (20) during the cooling operation, the refrigerant is compressed so as to approach the isotherm on the Ph diagram, and so-called isothermal compression is performed. This point will be described with reference to FIGS. 4 (A) and 4 (B). Here, FIG. 4 (A) is a Ph diagram showing a refrigeration cycle in ideal isothermal compression, and FIG. 4 (B) is a P-V diagram corresponding to the refrigeration cycle in FIG. 4 (A). FIG.

  In the refrigerant circuit (11) during the cooling operation, the refrigerant evaporated in the indoor heat exchanger (13) is mixed with oil to be overheated to a predetermined temperature and then sucked into the compression mechanism (20). The suction refrigerant is compressed by the compression mechanism (20) from the point A in FIG. 4 and is cooled by low-temperature oil. That is, in the compression stroke of the compression mechanism (20), the refrigerant is further compressed while being cooled by the oil. As a result, the refrigerant is compressed along an isotherm (for example, about 40 ° C.) shown in FIG. 4A and reaches a target high pressure (point C). In this way, by compressing the refrigerant in the behavior from point A to point C, the power required to compress the refrigerant by the compression mechanism (20) is effectively reduced.

  That is, for example, when a general adiabatic compression is performed in the compression stroke, the refrigerant is compressed with a behavior from point A to point C ′ shown in FIG. As a result, in this refrigeration cycle, the compression power of the refrigerant increases. On the other hand, when the refrigerant is cooled during the compression stroke by the oil injection operation as in the present embodiment, the area surrounded by A-C-C ′ in FIG. 4B as compared with general adiabatic compression. The compression power of the refrigerant in the compression mechanism (20) can be reduced by ΔS.

  Further, as in this embodiment, the supercritical cycle is performed using carbon dioxide as a refrigerant. When the oil injection operation is performed, the compression power reduction effect of the compression mechanism (20) is improved. This will be described below.

  First, in the refrigerant circuit (11) of the present embodiment, as described above, the refrigerant is compressed in the compression stroke so that the carbon dioxide becomes equal to or higher than the critical pressure (pressure indicated by the point cP in FIG. 4A). Yes. For this reason, it is possible to avoid the refrigerant reaching the gas-liquid two-phase region (condensation region) when compressing while cooling the refrigerant from the point A to the point C in the compression stroke. That is, in the supercritical cycle, it is possible to avoid the cold oil from being used for the condensation of the refrigerant, so that the refrigerant can be effectively lowered in temperature and the behavior of the refrigerant can be brought close to an isotherm.

  In contrast, in the compression stroke of a normal vapor compression refrigeration cycle (here, the refrigerant is R410A) shown in FIG. 5, for example, the refrigerant is compressed in a range smaller than the critical pressure. For this reason, when the oil injection operation is applied to this refrigeration cycle, the refrigerant reaches the gas-liquid two-phase region (condensation region). As a result, in this refrigeration cycle, for example, isothermal compression can be performed only in the range of point B1 to point C1.

  For the reasons described above, when the oil injection operation is applied to the refrigeration cycle of FIG. 5, the reduction amount of the compression power of the compression mechanism is ΔS ′ surrounded by B1-C1-C1 ′ of FIG. turn into. On the other hand, when the oil injection operation is applied to the supercritical cycle of the present embodiment, the reduction amount of the compression power of the compression mechanism (20) becomes ΔS, and the reduction effect of the compression power becomes high.

  Furthermore, in this embodiment, as described above, the energy of the oil is recovered by the power recovery mechanism (40). Thereby, while the effect of reducing the compression power of the refrigerant by the oil injection operation is achieved, the compression power required for boosting the oil is also reduced. This point will be described with reference to FIG.

  When the oil injection operation is performed, in the compression mechanism (20), in addition to the compression power of the refrigerant (Wr in FIG. 6), the power required to pressurize the oil (Wo in FIG. 6) is consumed. Here, as described above, the compression power Wr of the refrigerant is reduced by the effect of isothermal compression by the oil injection operation. Accordingly, the compression power Wr of the refrigerant decreases as the amount of low-temperature oil (oil injection amount Goil) supplied to the compression mechanism (20) increases. On the other hand, when the oil injection amount Goil increases as described above, the compression power Wo required for pressurizing the oil increases in the compression mechanism (20). Accordingly, in the compression mechanism (20), the relationship between the overall power Wt (that is, Wr + Wo) and the oil injection amount Goil is as shown in FIG. 6, and the oil injection amount Goil is a predetermined value (Gb). If it is larger than the range, the overall power Wt of the compression mechanism (20) may increase.

  Therefore, in the present embodiment, the power recovery mechanism (40) is used to recover the compression power Wo required for boosting the oil. Specifically, for example, when the oil injection operation is performed by setting the oil injection amount Goil to Gb larger than a predetermined value, the compression power Wo required for boosting the oil also increases, but in the oil power recovery type compression unit (C / O), The energy of the oil after the pressure increase is recovered as drive power for the compression mechanism (20). As a result, in this embodiment, even if the oil injection amount Goil is increased, a relatively high COP improvement rate (effect by isothermal compression) can be obtained with this air conditioner (10).

  That is, for example, as shown in FIG. 7, in the case where the power recovery mechanism (40) does not recover the oil power, that is, the oil energy (broken line L-0 in FIG. 7), the oil injection amount is larger than the predetermined value Gb. Then, the power Wo required for boosting the oil becomes larger than the reduction amount of the compression power Wr of the refrigerant due to the effect of isothermal compression, and the COP improvement rate is rather lowered. However, when the power of the oil is recovered by the power recovery mechanism (40), the power of the oil recovered to the compression mechanism (20) increases as the power Wo required for boosting the oil increases. As a result, for example, when the power recovery rate of the power recovery mechanism (40) is 50% (solid line L-50 in FIG. 7), a high COP improvement rate can be obtained even if the amount of oil injection is increased. The higher the power recovery rate of the power recovery mechanism (40), the higher the COP improvement rate (for example, solid line L-80 (power recovery rate 80%) and solid line L-100 (power recovery rate 100% in FIG. 7)). )), And particularly increases under conditions where the oil injection amount Goil is large.

-Effect of Embodiment 1-
In the first embodiment, oil is separated from the high-pressure refrigerant by the oil separator (60), and the energy of this oil is recovered by the power recovery mechanism (40) and used as drive power for the compression mechanism (20). ing. For this reason, the power required for pressurizing the oil by the compression mechanism (20) can be recovered by the power recovery mechanism (40), and the energy saving performance of the air conditioner (10) can be improved.

  In the first embodiment, the compression mechanism (20), the power recovery mechanism (40), and the electric motor (25) are integrally accommodated in the casing (40a), and the oil power recovery type compression unit (C / O). Therefore, the fluid machine having both the function of compressing the refrigerant and the function of recovering the energy of the oil can be configured in a compact manner, and the installation space can be reduced and the installation work at the site can be simplified.

  In the first embodiment, the oil separated by the oil separator (60) is cooled by the oil cooler (80), and the low temperature oil is supplied to the compression mechanism (20). For this reason, in the compression mechanism (20), the refrigerant can be compressed so as to approach the behavior of isothermal compression as shown in FIG. 4 (that is, the point A → the point C), and the compression power of the refrigerant is greatly reduced. it can. In addition, by increasing the oil injection amount Goil, the cooling effect of the refrigerant is improved and the compression power of the refrigerant is further reduced, while the energy of the oil recovered by the power recovery mechanism (40) is also increased. As a result, the COP improvement rate of the air conditioner (10) can be greatly improved, and the energy saving performance can be further improved. Here, the oil injection amount (mass flow rate) for effectively improving the COP improvement rate of the air conditioner (10) is approximately the amount of refrigerant sucked into the compression mechanism (20) (mass flow rate). The range is preferably 1.0 times or more and about 6.0 times or less.

  In addition, by increasing the amount of oil injection and actively introducing low-temperature oil into the compression mechanism (20), the following secondary effects can be obtained. Specifically, first, the temperature rise of the refrigerant discharged from the compression mechanism (20) can be prevented, and system abnormality of the air conditioner (10) and mechanical damage to the compression mechanism (20) can be avoided. Further, in the compression mechanism (20), the sliding portions such as pistons and bearings are sufficiently lubricated, and the heat dissipation effect of the sliding portions is improved. As a result, increase in mechanical loss and seizure at these sliding portions can be prevented. Furthermore, in the compression mechanism (20), since the oil can be suppressed to a relatively low temperature, it is possible to avoid deterioration due to excessive oil temperature. In addition, in the compression mechanism (20), the ambient temperature can be suppressed to a relatively low temperature. As a result, in the oil power recovery type compression unit (C / O), the temperature in the casing is also relatively low. Thereby, since the ambient temperature of the generator (45) also becomes low, the motor efficiency of the generator (45) is improved, and the input of the compression mechanism (20) is further reduced.

  In the first embodiment, the low-temperature oil is introduced into the compression mechanism (20) while performing a supercritical cycle in which the high-pressure refrigerant is compressed to a critical pressure or higher. Thus, in the compression stroke of the compression mechanism (20), the refrigerant can be compressed so as to approach the isotherm without condensing the refrigerant (see, for example, FIG. 4), and compared with a normal refrigeration cycle (see, for example, FIG. 5). The compression power can be effectively reduced.

<Modification 1 of Embodiment 1>
The air conditioner (10) according to the first modification of the first embodiment is different from the first embodiment in the configuration of the oil power recovery type compression unit (C / O) and the peripheral refrigerant circuit (11). is there. Hereinafter, differences from the first embodiment will be described.

  As shown in FIG. 8, in the oil power recovery type compression unit (C / O) of this modification, the suction pipe (22) is not directly connected to the compression mechanism (20), and penetrates the casing (40a). And opened in the casing (40a). On the other hand, in the compression mechanism (20), the suction port (28) opens into the casing (40a), and the discharge pipe (23) is directly connected to the compression mechanism (20). Thereby, the inside of the casing (40a) is filled with the low-pressure refrigerant (suction refrigerant) of the refrigerant circuit (11) to form a low-pressure atmosphere (Lp). That is, the oil power recovery type compression unit (C / O) of this modification is configured as a so-called low pressure dome type.

  An oil supply pipe (65) is connected to the oil power recovery type compression unit (C / O). The oil supply pipe (65) passes through a portion of the casing (40a) closer to the lower side of the trunk portion, and its terminal end opens into the oil reservoir (40b) of the casing (40a). In this modification, the end of the second oil guide pipe (72) is connected to the oil supply pipe (65). That is, in this modification, the oil cooled by the oil cooler (80) of the second oil guide pipe (72) is supplied to the compression mechanism (20) via the oil supply pipe (65) and the oil reservoir (40b). Is done. That is, the oil introduction path (70) of this modification is configured to include the first oil guide pipe (71), the second oil guide pipe (72), the oil supply pipe (65), and the oil reservoir (40b). .

  During the cooling operation of the air conditioner (10) of this modification, the oil separated by the oil separator (60) flows into the main body (41) of the power recovery mechanism (40) through the first oil guide pipe (71). To do. In the power recovery mechanism (40), the power of the oil, that is, the energy of the oil is recovered as the driving power of the compression mechanism (20). The oil flowing out of the power recovery mechanism (40) is cooled by the oil cooler (80), and then flows into the oil reservoir (40b) of the casing (40a) through the oil supply pipe (65). The refrigerant evaporated in the indoor heat exchanger (13) passes through the suction line (17) and the suction pipe (22) and flows into the casing (40a).

  The low temperature oil in the oil sump (40b) is pumped upward by the oil pump (42c) and used for lubrication of each sliding portion of the compression mechanism (20). In the compression mechanism (20), the refrigerant is compressed while being cooled by low-temperature oil leaking into the refrigerant being compressed. As a result, the compression power of the refrigerant in the compression mechanism (20) is reduced by the effect of the isothermal compression described above.

<Modification 2 of Embodiment 1>
The air conditioner (10) according to the second modification of the first embodiment is different from the first embodiment in the configuration of the oil power recovery type compression unit (C / O) and the surrounding refrigerant circuit (11). It is. Hereinafter, differences from the first embodiment will be described.

  As shown in FIG. 9, in the oil power recovery type compression unit (C / O) of this modification, the suction pipe (22) is not directly connected to the compression mechanism (20), and penetrates the casing (40a). And opened in the casing (40a). On the other hand, a suction pipe (22) and a discharge pipe (23) are directly connected to the compression mechanism (20). Furthermore, a relay pipe (24) is connected to the body of the casing (40a). The relay pipe (24) has a start end opened in the casing (40a) and a terminal end connected to the downstream side of the oil cooler (80) in the second oil guide pipe (72). As described above, also in this modification, the inside of the casing (40a) is filled with the low-pressure refrigerant (intake refrigerant) of the refrigerant circuit (11) to form a low-pressure atmosphere (Lp). That is, the oil power recovery type compression unit (C / O) of this modification is configured as a so-called low pressure dome type.

  During the cooling operation of the air conditioner (10) of this modification, the oil separated by the oil separator (60) flows into the main body (41) of the power recovery mechanism (40) through the first oil guide pipe (71). To do. In the power recovery mechanism (40), the power of the oil, that is, the energy of the oil is recovered as the driving power of the compression mechanism (20). The oil that has flowed out of the power recovery mechanism (40) is cooled by the oil cooler (80).

  On the other hand, the refrigerant evaporated in the indoor heat exchanger (13) passes through the suction line (17) and the suction pipe (22) and flows into the casing (40a). The low-pressure refrigerant in the casing (40a) once flows out of the casing (40a) from the relay pipe (24) and joins with the oil flowing through the second oil guide pipe (72). The oil mixed with the refrigerant is sucked into the compression mechanism (20) through the suction pipe (22). By the oil injection operation as described above, in the compression mechanism (20), the refrigerant is compressed while being cooled to low-temperature oil. As a result, the compression power in the compression mechanism (20) is reduced by the effect of the isothermal compression described above.

<< Embodiment 2 of the Invention >>
A second embodiment of the present invention will be described. The refrigerant circuit (11) of Embodiment 2 is provided with a compression unit (C) and an oil power recovery type expansion unit (E / O).

  As shown in FIG. 10, the compression unit (C) is configured such that a compression mechanism (20), an electric motor (25), and a drive shaft (21) are accommodated in a compression casing (20a). An oil sump (20b) for storing oil is formed at the bottom of the compression casing (20a).

  The compression mechanism (20) is connected to the electric motor (25) via the drive shaft (21). When the electric motor (25) is energized, the drive shaft (21) is rotationally driven, thereby driving the compression mechanism (20). Furthermore, an oil pump (21c) that pumps up the oil accumulated in the oil reservoir (20b) is provided at the lower end of the drive shaft (21).

  In the compression unit (C), the suction pipe (22) is directly connected to the compression mechanism (20), while the discharge pipe (23) opens into the compression casing (20a). Further, the discharge port (27) of the compression mechanism (20) is also opened in the compression casing (20a). As described above, the casing (40a) is filled with the high-pressure refrigerant (discharge refrigerant) of the refrigerant circuit (11) to form a high-pressure atmosphere (Hp). That is, the compression unit (C) of Embodiment 2 is configured as a so-called high-pressure dome type.

  In addition, one end of the pressure equalizing pipe (90) is connected to the compression casing (20a) at a position closer to the upper side of the body portion, and the one end opens to the inside of the compression casing (20a). Further, one end of an oil equalizing pipe (91) is connected to the bottom of the compression casing (20a), and the one end opens to an oil reservoir (20b) in the compression casing (20a).

  The oil power recovery type expansion unit (E / O) constitutes a fluid machine by housing the power recovery mechanism (40), the expansion mechanism (30), and the generator (45) in the casing (40a). . In the casing (40a), the expansion mechanism (30), the generator (45), and the power recovery mechanism (40) are arranged in this order from the top to the bottom. An oil sump (40b) is formed at the bottom of the casing (40a).

  The expansion mechanism (30) is configured in the same manner as in the first embodiment. The power recovery mechanism (40) has a main body (41) and an output shaft (42). The output shaft (42) extends in the casing (40a) in the axial direction, and connects the movable part (piston) of the expansion mechanism (30) and the piston (50) of the main body part (41). Yes. Moreover, the oil pump (42c) is provided in the lower end part of the output shaft (42) like the said Embodiment 1. FIG. The oil pumped up by the oil pump (42c) is appropriately supplied to a sliding portion such as a bearing of the expansion mechanism (30) through an oil passage (not shown) formed in the output shaft (42).

  The generator (45) is interposed between the main body (41) of the power recovery mechanism (40) and the expansion mechanism (30), and is connected to the output shaft (42). The generator (45) constitutes a drive target of the oil power recovery type expansion unit (E / O). Specifically, in the oil power recovery type expansion unit (E / O), the piston of the expansion mechanism (30) is rotationally driven by the power of the refrigerant expanding in the expansion chamber of the expansion mechanism (30), that is, the energy of the refrigerant. Along with this, the output shaft (42) rotates. In addition, in the oil power recovery type expansion unit (E / O), the piston (50) is rotationally driven by the energy of the oil flowing through the oil chamber (49) of the power recovery mechanism (40), and the output shaft ( 42) rotates. That is, the output shaft (42) is rotationally driven by both the refrigerant energy (expansion power) and the oil energy. As a result, the generator (45) is driven by the output shaft (42), and electric power is generated by the generator (45). The electric power generated by the generator (45) is used as power for the compression unit (C) and other element machines, for example.

  In the oil power recovery type expansion unit (E / O), the inflow pipe (33) and the outflow pipe (34) penetrate the casing (40a) and are directly connected to the expansion mechanism (30). The oil inflow pipe (43) and the oil outflow pipe (44) also pass through the casing (40a) and are directly connected to the main body (41) of the power recovery mechanism (40).

  Further, the other end of the pressure equalizing pipe (90) is connected to a portion of the casing (40a) closer to the upper side of the body portion, and the other end opens to the inside of the casing (40a). Further, the other end of the oil equalizing pipe (91) is connected to the bottom of the casing (40a), and the other end opens to an oil reservoir (40b) in the casing (40a).

  As described above, the inside of the casing (40a) of the oil power recovery type expansion unit (E / O) communicates with the inside of the compression casing (20a) via the pressure equalizing pipe (90) and the oil equalizing pipe (91). is doing. Thereby, the inside of the casing (40a) of the oil power recovery type expansion unit (E / O) is a high-pressure atmosphere (Hp), like the inside of the compression casing (20a). That is, the oil power recovery type expansion unit (E / O) of Embodiment 2 is configured as a so-called high pressure dome type.

  The oil introduction path (70) of the second embodiment is basically the same as that of the first embodiment. On the other hand, in Embodiment 2, the oil cooler (80) is provided in the first oil guide pipe (71). That is, the oil cooler (80) is disposed upstream of the power recovery mechanism (40) in the oil introduction path (70).

  Even during the cooling operation of the second embodiment, the first four-way switching valve (14) and the second four-way switching valve (15) are set to the first state (the state indicated by the solid line in FIG. 1), and the refrigerant circuit (11) A so-called supercritical cycle is performed.

  In the compression unit (C), the compression mechanism (20) is rotationally driven by the electric motor (25), and the refrigerant is compressed by the compression mechanism (20). After the oil is separated by the oil separator (60), the refrigerant radiates heat in the outdoor heat exchanger (12) and flows into the expansion mechanism (30) of the oil power recovery type expansion unit (E / O). In the expansion mechanism (30), the high-pressure refrigerant expands in the expansion chamber, thereby rotating the output shaft (42). The refrigerant expanded by the expansion mechanism (30) is evaporated by the indoor heat exchanger (13). As a result, the room air is cooled and cooling is performed. The refrigerant evaporated in the indoor heat exchanger (13) is sucked into the compression mechanism (20) and compressed again.

  In the cooling operation of the second embodiment, the oil separated by the oil separator (60) is cooled by the oil cooler (80) when flowing through the first oil guide pipe (71). The cooled oil flows into the main body (41) of the power recovery mechanism (40) of the oil power recovery type expansion unit (E / O). In the power recovery mechanism (40), the piston (50) is rotationally driven by the oil flowing through the oil chamber (49), and the output shaft (42) is rotationally driven accordingly. As described above, in the oil power recovery type expansion unit (E / O), power is recovered by both the expansion mechanism (30) and the power recovery mechanism (40), and this power is used for power generation by the generator (45). Used.

  The oil whose power is recovered in the oil chamber (49) and decompressed flows into the suction line (17), mixes with the refrigerant, and is sucked into the compression mechanism (20). By the oil injection operation as described above, in the compression mechanism (20), the refrigerant is compressed while being cooled to low-temperature oil. As a result, the compression power of the refrigerant in the compression mechanism (20) is reduced by the effect of the isothermal compression described above.

-Effect of Embodiment 2-
In Embodiment 2 above, oil is separated from the high-pressure refrigerant by the oil separator (60), and the energy of this oil is recovered by the power recovery mechanism (40) and used as driving power for the generator (45). ing. For this reason, the motive power required for pressurizing the oil by the compression mechanism (20) can be recovered as electric power, and the energy saving performance of the air conditioner (10) can be improved. In the second embodiment, the expansion power of the refrigerant recovered by the expansion mechanism (30) is also used for power generation by the generator (45). Therefore, the energy-saving property of the air conditioner (10) can be further improved.

  In the second embodiment, the expansion mechanism (30), the power recovery mechanism (40), and the generator (45) are integrally accommodated in the casing (40a), and the oil power recovery type expansion unit (E / O). Therefore, the fluid machine having the function of expanding the refrigerant, the function of recovering the power of the oil, and the function of power generation can be configured in a compact manner, and the installation space can be reduced and the installation work at the site can be simplified. .

  Also in the second embodiment, by actively sending low temperature oil to the compression mechanism (20), the compression power of the refrigerant can be greatly reduced by the isothermal compression effect, and further, recovered by the power recovery mechanism (40). Also, the power of the oil can be increased, and the power consumption of the entire system of the air conditioner (10) can be effectively reduced.

<Modification 1 of Embodiment 2>
In the air conditioner (10) according to the first modification of the second embodiment, the configuration of the compression unit (C), the oil power recovery type expansion unit (E / O), and the surrounding refrigerant circuit (11) are the same as those described above. This is different from Form 2. Hereinafter, differences from the second embodiment will be described.

  As shown in FIG. 11, in the compression unit (C) of this modification, the suction pipe (22) and the discharge pipe (23) are directly connected to the compression mechanism (20). On the other hand, the refrigerant return pipe (92), the refrigerant feed pipe (93), the oil return pipe (94), and the oil feed pipe (95) are connected to the compression casing (20a) of the compression unit (C).

  The refrigerant return pipe (92) has a start end connected to the refrigerant discharge pipe (62) of the oil separator (60) and an end opened to the inside of the compression casing (20a). The refrigerant feed pipe (93) has a start end that opens into the compression casing (20a) and a terminal end that is connected to the first port of the first four-way switching valve (14). The oil return pipe (94) has a start end connected to the oil discharge pipe (63) of the oil separator (60) and an end opened to the oil reservoir (20b) in the compression casing (20a). The oil feed pipe (95) has a start end opened to an oil reservoir (20b) in the compression casing (20a), and a terminal end connected to the oil inflow pipe (43).

  As described above, the high-pressure refrigerant separated by the oil separator (60) is introduced through the refrigerant return pipe (94) into the compression casing (20a) of the compression unit (C) of this modification. Thereby, the inside of the compression casing (20a) is filled with the high-pressure refrigerant (discharge refrigerant) of the refrigerant circuit (11) to form a high-pressure atmosphere (Hp). That is, the compression unit (C) of this modification is configured as a so-called high-pressure dome type.

  In the oil power recovery type expansion unit (E / O) of this modification, the oil outflow port (44a) is formed in the main body (41) of the power recovery mechanism (40), while the oil outflow pipe (44) is omitted. Has been. The oil outflow port (44a) is opened inside the casing (40a) and allows oil in the oil chamber (49) of the main body (41) to flow out. In addition, a low pressure refrigerant oil guide pipe (96), a low pressure refrigerant return pipe (97), and an oil drain pipe (98) are connected to the casing (40a) of the oil power recovery type expansion unit (E / O).

  The low-pressure refrigerant oil guide pipe (96) has a start end connected to the suction line (17) and a terminal end opened inside the casing (40a). The starting end of the low pressure refrigerant return pipe (97) opens into the casing (40a), and the end thereof is connected to the suction line (17). The oil drain pipe (98) has a starting end opened to an oil sump (40b) in the casing (40a) and an end connected to the suction line (17). In this modification, the pressure equalizing pipe (90) and the oil equalizing pipe (91) of the second embodiment are omitted.

  As described above, in the casing (40a) of the oil power recovery type expansion unit (E / O) of this modification, a part of the refrigerant flowing through the suction line (17) passes through the low pressure refrigerant oil guide pipe (96). be introduced. Thereby, the inside of the casing (40a) is filled with the low-pressure refrigerant (suction refrigerant) of the refrigerant circuit (11) to form a low-pressure atmosphere (Lp). That is, the oil power recovery type expansion unit (E / O) of this modification is configured as a so-called low pressure dome type.

  Moreover, the oil introduction path (70) of this modification is comprised including the 1st oil guide pipe (71), the 2nd oil guide pipe (72), and the 3rd oil guide pipe (73). The first oil guide pipe (71) is connected between the oil discharge pipe (63) and the oil return pipe (94), and the second oil guide pipe (72) is an oil feed pipe (95) and an oil inflow pipe (43). The third oil guide pipe (73) is connected between the oil drain pipe (98) and the suction line (17). Moreover, the oil cooler (80) of this modification is provided in the said 2nd oil guide pipe (72).

  During the cooling operation of the air conditioner (10) of this modification, the oil separated by the oil separator (60) flows into the oil reservoir (20b) in the compression casing (20a) through the first oil guide pipe (71). To do. The oil in the oil sump (20b) flows out to the second oil guide pipe (72), is cooled by the oil cooler (80), and then flows into the main body (41) of the power recovery mechanism (40). In the power recovery mechanism (40), oil energy is recovered as driving power of the compression mechanism (20). The oil whose power is recovered by the power recovery mechanism (40) and depressurized flows out from the oil outflow port (44a) into the casing (40a). This oil collects in the oil sump (40b) and flows out to the third oil guide pipe (73) through the oil drain pipe (98).

  The low-temperature oil flowing through the third oil guide pipe (73) is mixed with the refrigerant in the suction line (17) and sucked into the compression mechanism (20). By the oil injection operation as described above, in the compression mechanism (20), the refrigerant is compressed while being cooled to low-temperature oil. As a result, the compression power of the refrigerant in the compression mechanism (20) is reduced by the effect of the isothermal compression described above.

<Modification 2 of Embodiment 2>
In the air conditioner (10) according to the second modification of the second embodiment, the configuration of the compression unit (C), the oil power recovery type expansion unit (E / O), and the surrounding refrigerant circuit (11) is the same as that described above. This is different from Form 2. Hereinafter, differences from the second embodiment will be described.

  As shown in FIG. 12, in the compression unit (C) of this modification, the suction pipe (22) and the discharge pipe (23) are directly connected to the compression mechanism (20). On the other hand, the first relay pipe (24a) and the second relay pipe (24b) are connected to the compression casing (20a) of the compression unit (C).

  The first relay pipe (24a) has its start end connected to the suction line (17) and its end opened to the inside of the compression casing (20a). The start end of the second relay pipe (24b) opens into the compression casing (20a), and the end thereof is connected to the suction pipe (22) via the connecting pipe (29).

  As described above, the low-pressure refrigerant that has flowed out of the suction line (17) is introduced into the compression casing (20a) of the compression unit (C) of this modification. Thereby, the inside of the compression casing (20a) is filled with the low-pressure refrigerant (suction refrigerant) of the refrigerant circuit (11) to form a low-pressure atmosphere (Lp). That is, the compression unit (C) of this modification is configured as a so-called low pressure dome type.

  In addition, one end of an oil equalizing pipe (91) is connected to the bottom of the compression casing (20a), and the one end opens to an oil reservoir (20b) in the compression casing (20a). Furthermore, one end of a pressure equalizing pipe (90) is connected to the communication pipe (29).

  On the other hand, the other end of the pressure equalizing pipe (92) is connected to the bottom of the casing (40a) of the oil power recovery type expansion unit (E / O) of this modification, and the other end is connected to the casing (40a). ) In the oil sump (40b). In addition, the other end of the pressure equalizing pipe (90) is connected to the body of the casing (40a), and the other end opens to the inside of the casing (40a). In the oil power recovery type expansion unit (E / O), the terminal end of the second oil guide pipe (72) is connected to the connecting pipe (29).

  As described above, the inside of the casing (40a) of the oil power recovery type expansion unit (E / O) communicates with the inside of the compression casing (20a) via the pressure equalizing pipe (90) and the oil equalizing pipe (91). is doing. As a result, the inside of the casing (40a) of the oil power recovery type expansion unit (E / O) is in a low pressure atmosphere (Lp) like the inside of the compression casing (20a). That is, the oil power recovery type expansion unit (E / O) of Embodiment 2 is configured as a so-called low pressure dome type.

  During the cooling operation of the air conditioner (10) of this modification, the oil separated by the oil separator (60) is cooled by the oil cooler (80) when flowing through the first oil guide pipe (71), and after cooling Oil flows into the main body (41) of the power recovery mechanism (40). The oil whose power is recovered by the power recovery mechanism (40) and depressurized flows out of the second oil guide pipe (72) and flows into the connecting pipe (29).

  On the other hand, the refrigerant flowing out of the suction line (17) flows into the compression casing (20a) from the first relay pipe (24a) and passes around the electric motor (25). This refrigerant flows into the connecting pipe (29) from the second relay pipe (24b).

  The low-temperature oil flowing through the connecting pipe (29) is mixed with the refrigerant that has flowed out through the second relay pipe (24b), and is sucked into the compression mechanism (20). By the oil injection operation as described above, in the compression mechanism (20), the refrigerant is compressed while being cooled to low-temperature oil. As a result, the compression power of the refrigerant in the compression mechanism (20) is reduced by the effect of the isothermal compression described above.

<< Embodiment 3 of the Invention >>
Embodiment 3 of the present invention will be described. The refrigerant circuit (11) of the third embodiment is provided with an oil power recovery type expansion / compression unit (C / E / O).

  As shown in FIG. 13, the oil power recovery type expansion / compression unit (C / E / O) includes a compression mechanism (20), an electric motor (25), an expansion mechanism (30), and a power recovery mechanism in a casing (40a). (40) is housed to constitute a fluid machine. In the casing (40a), an expansion mechanism (30), a power recovery mechanism (40), an electric motor (25), and a compression mechanism (20) are arranged in this order from the top to the bottom. An oil sump (40b) is formed at the bottom of the casing (40a).

  The expansion mechanism (30) and the compression mechanism (20) are configured in the same manner as in the above embodiments. The power recovery mechanism (40) has a main body (41) and an output shaft (42). The output shaft (42) is formed so as to extend in the axial direction in the casing (40a), and the movable portion of the piston (50) of the main body (41), the movable portion of the expansion mechanism (30), and the compression mechanism (20). Are connected to each other. Moreover, the oil pump (42c) is provided in the lower end part of the output shaft (42) like the said Embodiment 1. FIG. The oil pumped up by the oil pump (42c) is appropriately supplied to sliding parts such as bearings of the expansion mechanism (30) and the compression mechanism (20) through an oil passage formed in the output shaft (42).

  The electric motor (25) is interposed between the main body (41) of the power recovery mechanism (40) and the expansion mechanism (30), and is connected to the output shaft (42). In the oil power recovery type expansion / compression unit (C / E / O), the output shaft (42) is rotationally driven by the electric motor (25). Further, the piston of the expansion mechanism (30) is rotationally driven by the power of the refrigerant expanding in the expansion chamber of the expansion mechanism (30), and the output shaft (42) rotates accordingly. In addition, in the oil power recovery type expansion / compression unit (C / E / O), the piston (50) is rotationally driven by the oil flowing through the oil chamber (49) of the power recovery mechanism (40), and as a result, the output shaft (42) rotates. The rotational power of the output shaft (42) as described above is used as the compression power of the compression mechanism (20).

  In the oil power recovery type expansion / compression unit (C / E / O), the inflow pipe (33) and the outflow pipe (34) penetrate the casing (40a) and are directly connected to the expansion mechanism (30). The oil inflow pipe (43) and the oil outflow pipe (44) also pass through the casing (40a) and are directly connected to the main body (41) of the power recovery mechanism (40). The suction pipe (22) is directly connected to the compression mechanism (20), while the discharge pipe (23) is opened in the compression casing (20a). And as for the compression mechanism (20), the discharge port (27) has opened in the compression casing (20a). As described above, the inside of the casing (40a) is filled with the high-pressure refrigerant (discharge refrigerant) of the refrigerant circuit (11) to form a high-pressure atmosphere (Hp). That is, the compression unit (C) of Embodiment 3 is configured as a so-called high-pressure dome type. The oil introduction path (70) of the third embodiment is basically the same as that of the first embodiment.

  Even during the cooling operation of the third embodiment, the first four-way switching valve (14) and the second four-way switching valve (15) are set to the first state (the state indicated by the solid line in FIG. 1), and the refrigerant circuit (11) A so-called supercritical cycle is performed.

  In the oil power recovery type expansion / compression unit (C / E / O), the compression mechanism (20) is rotationally driven by the electric motor (25), and the refrigerant is compressed by the compression mechanism (20). This refrigerant, after the oil is separated by the oil separator (60), dissipates heat in the outdoor heat exchanger (12), and to the expansion mechanism (30) of the oil power recovery type expansion / compression unit (C / E / O) Inflow. In the expansion mechanism (30), the high-pressure refrigerant expands in the expansion chamber, thereby rotating the output shaft (42). The refrigerant expanded by the expansion mechanism (30) is evaporated by the indoor heat exchanger (13). As a result, the room air is cooled and cooling is performed. The refrigerant evaporated in the indoor heat exchanger (13) is sucked into the compression mechanism (20) and compressed again.

  In the cooling operation of the third embodiment, the oil separated by the oil separator (60) flows through the first oil guide pipe (71) and the main body (C / E / O) of the oil power recovery type expansion / compression unit (C / E / O) 41). In the power recovery mechanism (40), the piston (50) is rotationally driven by the energy of the oil flowing through the oil chamber (49), and the output shaft (42) is rotationally driven accordingly. As described above, in the oil power recovery type expansion / compression unit (C / E / O), energy (power) is recovered by both the expansion mechanism (30) and the power recovery mechanism (40), and this power is compressed by the compression mechanism. Used as compression power for (20).

  The oil whose power is recovered in the oil chamber (49) and decompressed flows into the suction line (17), mixes with the refrigerant, and is sucked into the compression mechanism (20). By the oil injection operation as described above, in the compression mechanism (20), the refrigerant is compressed while being cooled to low-temperature oil. As a result, the compression power of the refrigerant in the compression mechanism (20) is reduced by the effect of the isothermal compression described above.

-Effect of Embodiment 3-
In the third embodiment, the compression mechanism (oil power recovered by the power recovery mechanism (40), that is, the energy of the oil and the refrigerant energy (expansion power) recovered by the expansion mechanism (30) are utilized. 20) is driven, the load on the electric motor (25) of the compression mechanism (20) can be greatly reduced, and the energy saving performance of the air conditioner (10) can be improved.

  In the third embodiment, the compression mechanism (20), the expansion mechanism (30), the power recovery mechanism (40), and the electric motor (25) are integrally accommodated in the casing (40a) to recover the oil power. This constitutes the mold expansion / compression unit (C / E / O). Therefore, a fluid machine having a function of compressing a refrigerant, a function of expanding a refrigerant, and a function of recovering oil energy can be configured in a compact manner, and the installation space can be reduced and the installation work on site can be simplified. Can do.

  Also in the third embodiment, by actively sending low-temperature oil to the compression mechanism (20), the compression power of the refrigerant can be greatly reduced by the isothermal compression effect, and further recovered by the power recovery mechanism (40). Power of the air conditioning apparatus (10) as a whole system can be effectively reduced.

<Modification 1 of Embodiment 3>
In the air conditioner (10) according to the first modification of the third embodiment, the configuration of the oil power recovery type expansion / compression unit (C / E / O) and the surrounding refrigerant circuit (11) are the same as those of the third embodiment. Is different. Hereinafter, differences from the third embodiment will be described.

  As shown in FIG. 14, in the oil power recovery type expansion / compression unit (C / E / O) of this modification, the suction pipe (22) and the discharge pipe (23) are directly connected to the compression mechanism (20). Yes. In addition, a refrigerant return pipe (92), a refrigerant feed pipe (93), an oil return pipe (94), and an oil feed pipe (95) are connected to the casing (40a).

  The refrigerant return pipe (92) has a start end connected to the refrigerant discharge pipe (62) of the oil separator (60) and an end opened to the inside of the casing (40a). The refrigerant feed pipe (93) has a start end opened inside the casing (40a) and a terminal end connected to the first port of the first four-way switching valve (14). The oil return pipe (94) has a start end connected to the oil discharge pipe (63) of the oil separator (60), and an end thereof opened to an oil reservoir (40b) in the casing (40a). The oil feed pipe (95) has a start end opened to an oil reservoir (20b) in the compression casing (20a), and a terminal end connected to the oil inflow pipe (43).

  As described above, inside the casing (40a) of the oil power recovery type expansion / compression unit (C / E / O) of this variation, the high-pressure refrigerant separated by the oil separator (60) is supplied to the refrigerant return pipe. Introduced through (94). Thereby, the inside of the casing (40a) is filled with the high-pressure refrigerant (discharge refrigerant) of the refrigerant circuit (11) to form a high-pressure atmosphere (Hp). That is, the oil power recovery type expansion / compression unit (C / E / O) of this modification is configured as a so-called high pressure dome type.

  The oil introduction path (70) of the present modification includes a first oil guide pipe (71), a second oil guide pipe (72), and a third oil guide pipe (73). The first oil guide pipe (71) is connected between the oil discharge pipe (63) and the oil return pipe (94), and the second oil guide pipe (72) is an oil feed pipe (95) and an oil inflow pipe (43). The third oil guide pipe (73) is connected between the oil outflow pipe (44) and the suction line (17). Moreover, the oil cooler (80) of this modification is provided in the 3rd oil guide pipe (73).

  During the cooling operation of the air conditioner (10) of this modification, the oil separated by the oil separator (60) flows into the oil reservoir (40b) in the casing (40a) through the first oil guide pipe (71). . The oil in the oil sump (40b) flows out to the second oil guide pipe (72) and flows into the main body (41) of the power recovery mechanism (40). In the power recovery mechanism (40), oil energy is recovered as driving power of the compression mechanism (20). The oil whose power is recovered by the power recovery mechanism (40) and depressurized is cooled by the oil cooler (80) when flowing through the third oil guide pipe (73), and flows out to the suction line (17).

  The low temperature oil mixed with the refrigerant in the suction line (17) is sucked into the compression mechanism (20). By the oil injection operation as described above, in the compression mechanism (20), the refrigerant is compressed while being cooled to low-temperature oil. As a result, the compression power of the refrigerant in the compression mechanism (20) is reduced by the effect of the isothermal compression described above.

<Modification 2 of Embodiment 3>
In the air conditioner (10) according to the second modification of the third embodiment, the configuration of the oil power recovery type expansion / compression unit (C / E / O) and the refrigerant circuit (11) therearound is the same as that of the third embodiment. Is different. Hereinafter, differences from the third embodiment will be described.

  As shown in FIG. 15, an oil separation mechanism (110) is provided on the discharge side of the compression mechanism (20) inside the oil power recovery type expansion / compression unit (C / E / O) of this modification. . The oil separation mechanism (110) constitutes an oil separation means that separates oil from the high-pressure refrigerant by, for example, centrifugal force. In the oil separation mechanism (110), the separated oil flows out from the oil discharge port (111), and this oil is collected in the oil reservoir (40b). In the oil separation mechanism (110), the refrigerant from which the oil has been separated flows out from the refrigerant discharge port (112) into the casing (40a). Thereby, the inside of the casing (40a) is filled with the high-pressure refrigerant (discharge refrigerant) of the refrigerant circuit (11) to form a high-pressure atmosphere (Hp). That is, the oil power recovery type expansion / compression unit (C / E / O) of this modification is configured as a so-called high pressure dome type.

  In addition, an oil feed pipe (95) is connected to the casing (40a) of the present modification so that the starting end opens to the oil reservoir (40a). Further, in the oil introduction path (70) of the present modification, the first oil guide pipe (71) is connected between the oil feed pipe (95) and the oil inflow pipe (43).

  During the cooling operation of the air conditioner (10) of this modification, the refrigerant discharged from the compression mechanism (20) is directly sent to the oil separation mechanism (110). The refrigerant from which the oil has been separated by the oil separation mechanism (110) passes around the electric motor (25) and flows out of the casing (40a) through the discharge pipe (23). On the other hand, the oil separated by the oil separation mechanism (110) is collected in the oil sump (40b), and then flows out to the first oil guide pipe (71) through the oil feed pipe (95), and the power collection mechanism (40) Into the main body (41). In the power recovery mechanism (40), oil energy is recovered as driving power of the compression mechanism (20). The oil whose energy is recovered by the power recovery mechanism (40) and depressurized is cooled by the oil cooler (80) when flowing through the second oil guide pipe (72), and flows out to the suction line (17).

  The low temperature oil mixed with the refrigerant in the suction line (17) is sucked into the compression mechanism (20). By the oil injection operation as described above, in the compression mechanism (20), the refrigerant is compressed while being cooled to low-temperature oil. As a result, the compression power of the refrigerant in the compression mechanism (20) is reduced by the effect of the isothermal compression described above.

<< Other Embodiments >>
About each said embodiment, it is good also as following structures.

  In each of the above-described embodiments (including modifications), the oil separated from the refrigerant by the oil separator (60) is not the suction side (that is, the low pressure side) of the compression mechanism (20), but the compression mechanism (20). You may make it supply in the middle of the compression stroke (namely, intermediate pressure side).

  For example, FIG. 16 shows that the air after cooling is supplied to the compression mechanism (20) during the compression of the air conditioner (10) of the first embodiment. In this example, the intermediate port (99) is connected to the compression mechanism (20). The intermediate port (99) has a start end facing the outside of the casing (40a), and an end thereof opened to a compression midway position of the compression chamber of the compression mechanism (20). Moreover, in this example, the terminal end of the second oil guide pipe (72) of the oil introduction path (70) is connected to the intermediate port (99).

  Then, during the cooling operation of the air conditioner (10) of the example of the figure, the oil cooled by the oil cooler (80) is compressed through the second oil guide pipe (72) and the intermediate port (99). 20) is supplied in the middle of compression. By performing such an oil injection operation, the compression mechanism (20) performs a refrigeration cycle as shown in FIG. That is, the low-pressure refrigerant sucked into the compression mechanism (20) from the suction line (17) is compressed from the point A in FIG. And a refrigerant | coolant mixes with the oil introduce | transduced from the intermediate | middle port (99) in B point. Here, the refrigerant at point B is already compressed (adiabatic compression) from point A and heated up. Therefore, it is possible to avoid the refrigerant from becoming cooler than the oil by introducing the low-temperature oil into this portion. Thereby, in a subsequent compression stroke (B point-> C point), it can avoid that a refrigerant | coolant is heated with oil and it becomes overheat compression. Accordingly, it is possible to avoid the effect of reducing the compression power of the refrigerant due to such overheat compression, and to sufficiently obtain the effect of reducing the compression power of the refrigerant by so-called isothermal compression (ΔS shown in FIG. 17). Can do.

  Further, the power recovery mechanism (40) and the generator (45) may be accommodated in the casing (40a) to constitute an oil power recovery unit. That is, with respect to the oil power recovery type expansion unit (E / O) described above, the oil power recovery unit may be configured by omitting the expansion mechanism (30).

  Moreover, in each embodiment mentioned above, about the thing which supplies the oil isolate | separated with the oil separator (60) to a compression mechanism (20) positively, and performs what is called isothermal compression, the power recovery mechanism (40) of this invention is used. I am trying to apply it. However, for example, a refrigerant circuit that returns oil that has flowed out of the compression mechanism (20) to the suction side of the compression mechanism (20) via an oil return pipe to prevent poor lubrication of the compression mechanism (20). The power recovery mechanism (40) of the present invention may be applied to the oil return pipe. Even in this case, the kinetic energy of the high-pressure oil can be recovered by the power recovery mechanism (40), and the COP of the refrigeration apparatus can be improved.

  Moreover, the main-body part (41) of the power recovery mechanism (40) of each embodiment mentioned above is comprised with the rotary positive displacement fluid machine. However, the main body (41) may be configured by, for example, a scroll-type positive displacement fluid machine, or may be configured by, for example, a non-positive displacement fluid machine (for example, a turbine-type non- positive displacement fluid machine). good. Needless to say, the compression mechanism (20) and the expansion mechanism (30) may be formed of other types of fluid machines.

  Moreover, in each embodiment mentioned above, you may make it use another refrigerant | coolant as a refrigerant | coolant with which a refrigerant circuit (11) is filled. Moreover, you may make it use other oil as oil (refrigeration machine oil) mixed in the refrigerant | coolant of a refrigerant circuit (11).

  Moreover, in each embodiment mentioned above, although this invention is applied about the air conditioning apparatus (10) which air-conditions a room | chamber interior, this invention is applied to the freezing apparatus which cools the inside of a refrigerator or a freezer, for example, and another freezing apparatus. It may be applied.

  In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

  As described above, the present invention is useful for a refrigeration apparatus including a refrigerant circuit that performs a refrigeration cycle by circulating refrigerant.

FIG. 1 is a piping diagram illustrating a schematic configuration of an air-conditioning apparatus according to Embodiment 1. FIG. 2 is an enlarged longitudinal sectional view of the power recovery mechanism. FIG. 3 is a cross-sectional view showing the inside of the power recovery mechanism, and shows the operation of the piston. FIG. 4 shows an ideal refrigeration cycle of the present embodiment. FIG. 4 (A) shows a Ph diagram and FIG. 4 (B) shows a PV diagram. . FIG. 5 shows a general refrigeration cycle. FIG. 5 (A) shows a Ph diagram and FIG. 5 (B) shows a PV diagram. FIG. 6 is a graph showing the relationship between the oil injection amount and the power of the compression mechanism. FIG. 7 is a graph showing the relationship between the oil injection amount and the COP improvement rate. FIG. 8 is a piping system diagram illustrating a schematic configuration of an air-conditioning apparatus according to Modification 1 of Embodiment 1. FIG. 9 is a piping diagram illustrating a schematic configuration of an air-conditioning apparatus according to Modification 2 of Embodiment 1. FIG. 10 is a piping diagram illustrating a schematic configuration of the air-conditioning apparatus according to the second embodiment. FIG. 11 is a piping diagram illustrating a schematic configuration of an air-conditioning apparatus according to Modification 1 of Embodiment 2. FIG. 12 is a piping diagram illustrating a schematic configuration of an air-conditioning apparatus according to Modification 2 of Embodiment 2. FIG. 13 is a piping diagram illustrating a schematic configuration of an air-conditioning apparatus according to Embodiment 3. FIG. 14 is a piping diagram illustrating a schematic configuration of an air-conditioning apparatus according to Modification 1 of Embodiment 3. FIG. 15 is a piping diagram illustrating a schematic configuration of an air-conditioning apparatus according to Modification 2 of Embodiment 3. FIG. 16 is a piping system diagram illustrating a schematic configuration of an air-conditioning apparatus according to another embodiment. FIG. 17 shows an ideal refrigeration cycle according to another embodiment. FIG. 17A shows a Ph diagram and FIG. 17B shows a PV diagram. is there.

Explanation of symbols

10 Air conditioning equipment (refrigeration equipment)
11 Refrigerant circuit
20 Compression mechanism (drive target)
25 Electric motor
30 Expansion mechanism
40 Power recovery mechanism
40a casing
42 Output shaft
45 Generator (Drive target)
50 piston (movable part)

Claims (6)

A movable part (50) that is rotationally driven by oil separated from the high-pressure refrigerant compressed by the compression mechanism (20) of the refrigerant circuit (11) in which the refrigerant circulates and performs the refrigeration cycle, and the movable part (50) A power recovery mechanism (40) having an output shaft (42) to be coupled;
A predetermined drive object (20, 45) that is connected to and driven by the output shaft (42) of the power recovery mechanism (40);
A fluid machine comprising a casing (40a) for accommodating the power recovery mechanism (40) and the drive target (20, 45) therein. In claim 1,
The fluid machine is characterized in that the driven object is constituted by the compression mechanism (20). In claim 2,
The casing (40a) further accommodates an expansion mechanism (30) having a movable part that is rotationally driven by the refrigerant of the refrigerant circuit (11) and is connected to the output shaft (42) of the power recovery mechanism (40). A fluid machine characterized by being made. In claims 1 to 3,
The fluid machine, wherein the casing (40a) further houses an electric motor (25) that rotationally drives the output shaft (42) of the power recovery mechanism (40). In claim 1,
The fluid machine is characterized in that the driven object is constituted by a generator (45). In claim 5,
The casing (40a) further accommodates an expansion mechanism (30) having a movable part that is rotationally driven by the refrigerant of the refrigerant circuit (11) and is connected to the output shaft (42) of the power recovery mechanism (40). A fluid machine characterized by being made.

Images