The present disclosure relates to a compressor that compresses working gas.
In the past, scroll compressors for use in refrigeration, air conditioning, or other uses have been known as compressors that compress a working gas. In such a scroll compressor, a compression unit that is a combination of a fixed scroll and an orbiting scroll that include respective scroll laps compresses a working gas such as refrigerant when the orbiting scroll is revolved, In the compressor, in order that the orbiting scroll be smoothly revolved, a shaft supported by a main bearing and a sub bearing is rotated by a motor.
Patent Literature 1 discloses a scroll compressor including a pump unit that is a positive-displacement pump whose volume is constant, such as a trochoid pump. In Patent Literature 1, oil is drawn up by the pump unit, from an oil storage space provided at lower part of a shell and is supplied to bearings, a compression unit, and other part. With the above feature, the technique of Patent Literature 1 is intended to protect the bearings and the compression unit from abrasion.
Patent Literature 1: Japanese Unexamined Patent Application Publication No. 4-350383
However, the positive-displacement pump whose volume is constant is used in the scrod compressor disclosed in Patent Literature 1. The amount of oil drawn up by the positive-displacement pump per unit time depends on the rotation speed of the compression unit because of the structure of the positive-displacement pump. In Patent Literature 1, since the positive-displacement pump whose volume is constant is used, the amount of supply of oil is increased in a high-speed operation in which the rotation speed of the compression unit is high. This may increase the amount of oil loss.
The present disclosure is applied to solve the above problem, and relates to a compressor that reduces an increase in the amount of oil loss in a high-speed operation of a compression unit.
A compressor according to an embodiment of the present disclosure includes: a shell forming an outer portion of the compressor and having lower part in which an oil pan is formed, the oil pan being configured to store oil; a motor provided in the shell; a compression unit provided in the shell and configured to compress a working gas when being driven by the motor; a frame fixed to the shell and supporting the compression unit; a shaft supported by the frame and connecting the motor and the compression unit, the shaft being configured to transmit a turning force of the motor to the compression unit, and including an oil passage through which oil flows; and an oil pump provided at lower part of the shaft, and configured to draw oil from the oil pan and supply the oil into the oil passage. The pump includes a bypass valve configured to be opened, when a pressure of oil flowing in the oil passage is higher than a threshold pressure, to return part of the oil to the oil pan.
According to the embodiment of the present disclosure, the oil pump includes the bypass valve that is opened, when the pressure of oil flowing in the oil passage is higher than a threshold pressure, to return part of the oil to the oil pan. The bypass valve of the oil pump is opened when the pressure of oil flowing in the oil passage in a high-speed operation in which the rotation speed of the compression unit is high is raised. Thus, part of the oil is returned to the oil pan. Therefore, it is possible to reduce an increase in the amount of oil supply in the high-speed operation of the compression unit. Accordingly, the compressor is capable of reducing an increase in oil loss in the high-speed operation of the compression unit.
Compressors according to embodiments of the present disclosure will be described with reference to the drawings. The present disclosure is not limited to the embodiments as described below. The relationships in size between components and structural elements in figures including
The compressor 1, the flow switching device 72, the outdoor heat exchanger 73, the expansion unit 75, and the indoor heat exchanger 76 are connected by refrigerant pipes 70a, whereby a refrigerant circuit 70 is formed, In the refrigerant circuit 70, refrigerant that is a working gas flows. The compressor 1 sucks low-temperature and low-pressure refrigerant, compresses the sucked refrigerant into high-temperature and high-pressure refrigerant to change it into high-temperature and high-pressure refrigerant, and discharges the high-temperature and high-pressure refrigerant. The flow switching device 72 changes the flow direction of refrigerant in the refrigerant circuit 70 in a switching manner. The flow switching device 72 is, for example, a four-way valve. For example, the outdoor heat exchanger 73 causes heat exchange to be performed, for example, between outdoor air and refrigerant. The outdoor heat exchanger 73 operates as a condenser in a cooling operation and operates as an evaporator in a heating operation.
The outdoor fan 74 is a device that sends outdoor air to the outdoor heat exchanger 73. The expansion unit 75 is a pressure reducing valve or an expansion valve that decompresses and expands refrigerant. The expansion unit 75 is, for example, an electronic expansion valve whose opening degree is adjusted. The indoor heat exchanger 76 causes heat exchange to be performed, for example, between indoor air and refrigerant, The indoor heat exchanger 76 operates as an evaporator in the cooling operation and operates as a condenser in the heating operation. The indoor fan 77 is a device that sends indoor air to the indoor heat exchanger 76.
Next, the operation modes of the air-conditioning apparatus 100 will be described. First of all, the cooling operation will be described. In the cooling operation, the compressor 1 compresses refrigerant sucked into the compressor 1 to change it into high-temperature and high-pressure gas refrigerant and discharges the high-temperature and high-pressure gas refrigerant. The high-temperature and high-pressure gas refrigerant discharged from the compressor 1 passes through the flow switching device 72, flows into the outdoor heat exchanger 73 operating as a condenser, and is condensed by heat exchange with outdoor air sent by the outdoor fan 74 in the outdoor heat exchanger 73 to change into liquid refrigerant. The condensed liquid refrigerant flows into the expansion unit 75 and is expanded and decompressed in the expansion unit 75 to change into low-temperature and low-pressure two-phase gas-liquid refrigerant. The two-phase gas-liquid refrigerant then flows into the indoor heat exchanger 76 operating as an evaporator and is evaporated by heat exchange with indoor air sent by the indoor fan 77 in the indoor heat exchanger 76 to change into low-temperature and low-pressure gas refrigerant. At this time, the indoor air is cooled, and cooling is performed in the indoor space. The evaporated low-temperature and low-pressure gas refrigerant passes through the flow switching device 72 and is sucked into the compressor 1.
Next, the heating operation will be described. In the heating operation, the compressor 1 compresses refrigerant sucked into the compressor 1 into high-temperature and high-pressure gas refrigerant and discharges the high-temperature and high-pressure gas refrigerant. The high-temperature and high-pressure gas refrigerant discharged from the compressor 1 passes through the flow switching device 72, flows into the indoor heat exchanger 76 operating a condenser, and is condensed by heat exchange with indoor air sent by the indoor fan 77 in the indoor heat exchanger 76 to change into liquid refrigerant. At this time, the indoor air is heated, and heating is performed in the indoor space. The condensed liquid refrigerant flows into the expansion unit 75 and is expanded and decompressed in the expansion unit 75 to change into low-temperature and low-pressure two-phase gas-liquid refrigerant. The two-phase gas-liquid refrigerant then flows into the outdoor heat exchanger 73 operating as an evaporator and is evaporated by heat exchange with outdoor air sent by the outdoor fan 74 in the outdoor heat exchanger 73 to change into low-temperature and low-pressure gas refrigerant. The evaporated low-temperature and low-pressure gas refrigerant passes through the flow switching device 72 and is sucked into the compressor 1.
Next, the compressor 1 will be specifically described. For example, the compressor 1 is used in a refrigeration cycle apparatus for refrigeration or air conditioning, such as a refrigerator, a freezer, the air-conditioning apparatus 100, a refrigeration apparatus, and a hot-water supply apparatus. In Embodiment 1, the compressor 1 for use in the air-conditioning apparatus 100 will be described. The compressor 1 sucks a working gas that circulates in a refrigeration cycle, compresses the sucked working gas to change it into a high-temperature and high-pressure gas, and discharges the high-temperature and high-pressure gas. The compressor 1 is, for example, a hermetic scroll compressor.
The shell 2 is a hermetic container that forms an outer portion of the compressor 1, and is formed in the shape of a cylinder having a bottom. The shell 2 is provided on a lower shell 2b. Upper part of the shell 2 is covered with an upper shell 2a, which has a dome shape. The compression unit 5, the motor 4, and other components are housed in the shell 2. The compression unit 5 is provided in an upper region in the shell 2. The motor 4 is provided in a lower region in the shell 2. An oil pan 13 is formed in lower part of the shell 2.
The frame 6 is fixed to the shell 2 and accommodates the compression unit 5. For example, the shaft 7 is rotatably supported by the frame 6, with the main bearing 8a interposed between the shaft 7 and the frame 6. The frame 6 is provided above the motor 4 and located between the motor 4 and the compression unit 5. The frame 6 has Oldham grooves 15a, which accommodate claws of the Oldham ring 15. The frame 6 has a suction port through which a working gas passes to flow into the compression unit 5.
The sub frame 20 is provided below the motor 4 in the shell 2. The shaft 7 is rotatably supported by the sub frame 20, with the sub bearing 8b interposed between the shaft 7 and the sub frame 20. The frame 6 and the sub frame 20 are fixed in the shell 2 and located opposite to each other with respect to the motor 4. The frame 6 and the sub frame 20 are fixed to an inner peripheral surface of the shell 2 by, for example, shrink fitting or welding. The shaft 7 is supported by the frame 6 at the center of the shell 2. The shaft 7 is a rod-shaped crankshaft that extends in an up-down direction, and connects the motor 4 and the compression unit 5. To be more specific, the shaft 7 connects the motor 4 and the compression unit 5 to transmit a rotative force of the motor 4 to the compression unit 5. In the shaft 7, an oil passage 7a is formed to allow oil to pass therethrough. The main bearing 8a is provided at the center of the frame 6, and upper part of the shaft 7 is rotatably supported by the main bearing 8a. The sub bearing 8b is provided at the center of the sub frame 20, and lower part of the shaft 7 is rotatably supported by the sub bearing 8b.
The suction pipe 11 is connected, at a side of the shell 2, with a low-pressure space in the shell 2 that is provided between the motor 4 and the compression unit 5. Through the suction pipe 11, a low-pressure working gas that flows through the refrigerant pipe 70a is sucked into the low-pressure space. The discharge pipe 12 is connected, at the upper part of the shell 2, to a high-pressure space in the shell 2 that is provided above the compression unit 5. Through the discharge pipe 12, a high-pressure working gas compressed by the compression unit 5 is discharged into the refrigerant pipe 70a, which is located outside the compressor 1.
The compression unit 5 compresses a working gas sucked through the suction pipe 11 and discharges the compressed working gas into the high-pressure space provided in the upper part of the shell 2. The compression unit 5 includes a fixed scroll 30, an orbiting scroll 40, and a thrust plate 46. The fixed scroll 30 is fixed, at a position located above the orbiting scroll 40, to the shell 2 via the frame 6 by, for example, a bolt (not illustrated). The fixed scroll 30 includes a panel 30a and a fixed scroll lap 30b. The panel 30a is a plate-like member that forms upper part of the fixed scroll 30. The fixed scroll lap 30b is a scroll lap that extends downward from a lower surface of the panel 30a and that is formed in such a manner as to spiral outward from the center thereof. At the center of the fixed scroll 30, a discharge port 9 is formed as a space into which a compressed high-pressure working gas is discharged.
The orbiting scroll 40 revolves (orbits) relative to the fixed scroll 30. The orbiting scroll 40 includes a boss 44, a base plate 43, and an orbiting scroll lap 41. The boss 44 forms lower part of the orbiting scroll 40 and has a cylindrical shape to accommodate the eccentric portion 45 of the shaft 7. The base plate 43 is a plate-like member that connects the boss 44 and the orbiting scroll lap 41. The orbiting scroll lap 41 is a scroll lap that extends upward from upper part of the boss 44 and that is formed in such a manner as to spiral outward from the center thereof. In lower part of the orbiting scroll 40, Oldham grooves 15a are formed to accommodate claws of the Oldham ring 15.
A lower surface of the orbiting scroll 40 is a thrust surface 40a that serves as a sliding portion. The fixed scroll 30 and the orbiting scroll 40 are provided in the shell 2 such that fixed scroll lap 30b and the orbiting scroll lap 41 are engaged with each other. The fixed scroll lap 30b and the orbiting scroll lap 41 are formed to follow an involute curve. The fixed scroll lap 30b and the orbiting scroll lap 41 are combined in such a manner as to be engaged with each other, thereby forming a plurality of compression chambers 5a between the fixed scroll lap 30b and the orbiting scroll lap 41.
The first hole 50a is a hole that extends laterally from upper end part of the oil passage 7a, which is formed in the shaft 7 accommodated in the boss 44, It should be noted that an outlet of the first hole 50a is covered with a set screw 51. The second hole 50b is a hole that extends downward from the first hole 50a and that connects the first hole 50a and the thrust surface 40a. In Embodiment 1, the second hole 50b is formed in such a manner as to be inclined outward, but may be formed to extend linearly downward without being inclined.
The thrust plate 46 is a plate-like member that is provided between the frame 6 and the thrust surface 40a of the orbiting scroll 40. The thrust plate 46 improves the sliding characteristic of the thrust surface 40a when the orbiting scroll 40 revolves relative to the frame 6. Thus, the orbiting scroll 40 is supported in the axial direction by the frame 6 via the thrust plate 46.
Between the orbiting scroll 40 and the slider 16, an orbiting bearing 8c is provided. The orbiting bearing 8c covers the shaft 7 and the eccentric portion 45, and supports the shaft 7 such that the shaft 7 is rotatable. The eccentric portion 45 is provided at an upper end of the shaft 7 and eccentrically revolves the orbiting scroll 40. The Oldham ring 15 is provided on the thrust surface 40a, which is located on the opposite side of a surface of the orbiting scroll 40 on which the orbiting scroll lap 41 is formed. The Oldham ring 15 prevents the orbiting scroll 40 from rotating on its own axis while the orbiting scroll 40 is eccentrically revolving, and enables the orbiting scroll 40 to revolve. It should be noted that on an upper surface and a lower surface of the Oldham ring 15, claws (not illustrated) are provided in such a manner as to project orthogonal to each other. The claws of the Oldham ring 15 are inserted into the Oldham grooves 15a formed in the orbiting scroll 40 and the frame 6.
The slider 16 is a cylindrical member attached to an outer peripheral surface of the upper part of the shaft 7 and is located on an inner surface of the lower part of the orbiting scroll 40. That is, the orbiting scroll 40 is attached to the shaft 7 via the slider 16 and revolves as the shaft 7 rotates. The sleeve 17 is a cylindrical member provided between the frame 6 and the main bearing 8a and compensates for the inclination of the frame 6 and the shaft 7.
The first balancer 18 is attached to the shaft 7 and located between the frame 6 and a rotor 4a. The first balancer 18 offsets an imbalance caused by the orbiting scroll 40 and the slider 16. The first balancer 18 is accommodated in a balancer cover 18a. The second balancer 19 is attached to the shaft 7 and a lower surface of the rotor 4a and is located between the rotor 4a and the sub frame 20. The second balancer 19 offsets an imbalance caused by the orbiting scroll 40 and the slider 16.
The discharge valve 10 is a component that is made of a plate spring and covers the discharge port 9 to prevent backflow of a working gas. In the compression chambers 5a, when being compressed to a predetermined pressure, a working gas raises the discharge valve 10 against an elastic force of the discharge valve 10. Then, the compressed working gas is discharged into the high-pressure space through the discharge port 9, and discharged to the outside of the compressor 1 through the discharge pipe 12. The muffler 14 covers the discharge valve 10 and reduces pulsation of the working gas discharged through the discharge port 9.
The oil pump 3 is accommodated in the lower part of the shell 2 and draws up oil from the oil pan 13. The oil pump 3 is fixed to the lower part of the shaft 7. The oil pump 3 is, for example, a positive-displacement pump. The oil pump 3 draws oil through a pump suction port 60 that is provided in the oil pan 13, and discharges oil through a pump discharge port 61. As the shaft 7 is rotated, oil stored in the oil pan 13 is drawn up into the oil passage 7a formed in the shaft 7 and is supplied to the sub bearing 8b, the main bearing 8a, and the orbiting bearing 8c through the oil passage 7a. Oil with which the orbiting bearing 8c is lubricated passes through the first hole 50a of the supply hole 50 and is taken into the compression chambers 5a.
At normal times, the bypass passage 63 is closed by the bypass valve 62. When the pressure of oil in the oil passage 7a is higher than the threshold pressure, the bypass valve 62 is pushed against an urging force of the spring 64 to open the bypass passage 63. As a result, oil returns to the oil pan 13 through the bypass passage 63. In the case where the bypass valve 62 is in the closed state, the volume ratio of the oil pump 3 is two or more times higher than that in the case where the bypass valve 62 is in the opened state. It is therefore possible to ensure that a sufficient amount of oil is returned to the oil pan 13 when the bypass valve 62 is in the opened state.
The oil discharge pipe 21 is a pipe through which the space between the frame 6 and the orbiting scroll 40 communicates with the space between the frame 6 and the sub frame 20, Of oil that flows in the space between the frame 6 and the orbiting scroll 40, surplus oil flows, through the oil discharge pipe 21, into the space between the frame 6 and the sub frame 20. The oil that has flowed out into the space between the frame 6 and the sub frame 20 returns to the oil pan 13 through the sub frame 20.
For example, in the shell 2, for example, between the frame 6 and the sub frame 20, the motor 4 is provided in a low-pressure space into which a working gas is sucked and that is located at the low-pressure side, The motor 4 drives the orbiting scroll 40, which is included in the compression unit 5. To be more specific, when the motor 4 drives the orbiting scroll 40 to revolve the orbiting scroll 40 via the shaft 7, a working gas is compressed in the compression unit 5. The motor 4 includes the rotor 4a and a stator 4b. The rotor 4a is provided close to the inner periphery of the stator 4b. The rotor 4a is driven to rotate when the stator 4b is supplied with electricity from an inverter (not illustrated), and the rotor 4a is driven to rotate, and the shaft 7 is rotated. The rotor 4a is fixed to an outer periphery of the shaft 7, and is held apart from the stator 4b by a slight distance.
Next, the operation of the compressor 1 will be described. When electricity is supplied to the stator 4b, the rotor 4a produces torque, thereby rotating the shaft 7 supported by the main bearing 8a provided at the frame 6 and the sub bearing 8b provided at the sub frame 20. The orbiting scroll 40 including the boss 44, which is attached to the eccentric portion 45 provided at the shaft 7 and which is configured to revolve, is revolved, and prevented by the Oldham ring 15 from rotating on its own axis.
That is, the boss 44 of the orbiting scroll 40 is eccentrically moved by the eccentric portion 45 of the shaft 7 while being prevented from rotating on its own axis by the Oldham ring 15, which is configured to reciprocate in a direction along the Oldham grooves 15a formed in the frame 6. When the boss 44 is eccentrically moved in the above state, an orbiting school makes an orbital motion, thereby changing the volumes of the compression chambers 5a formed between the fixed scroll lap 30b of the fixed scroll 30 and the scroll lap of the orbiting scroll 40. The first balancer 18 attached to the shaft 7 and the second balancer 19 attached to the rotor 4a perform control to compensate for an imbalance caused by movement of the orbiting scroll 40 and the Oldham ring 15.
Next, the flow of a working gas in the compressor 1 will be described. A fluid working gas is sucked from the outside of the compressor 1 into the shell 2 through the suction pipe 11. First, the working gas flows into the space between the frame 6 and the motor 4. Then, the working gas that has flowed into the space between the frame 6 and the motor 4 flows into the compression unit 5 through the suction port formed in the frame 6. The working gas that has flowed into the compression unit 5 is compressed in the compression chambers 5a of the compression unit 5. The compressed working gas is discharged from the fixed scroll 30 and is made to flow into a discharge space. Subsequently, after flowing out from the discharge space, the working gas passes through the muffler 14 and is discharged, through the discharge pipe 12, to the outside of the compressor 1, that is, into the refrigerant pipes 70a of the refrigerant circuit 70.
Next, the flow of oil in the compressor 1 will be described. Oil drawn from an oil pan 3a by the oil pump 3 flows into the oil passage 7a formed in the shaft 7. Part of the oil that has flowed into the oil passage 7a passes through a passage formed in the radial direction, and lubricates the sub bearing 8b. Then, the oil that has lubricated the sub bearing 8b returns to the oil pan 3a through the sub frame 20.
In addition, other part of the oil that has flowed into the oil passage 7a passes through a passage formed in the radial direction, and lubricates the main bearing 8a. The oil that has lubricated the main bearing 8a flows into the space between the frame 6 and the motor 4. The oil that has flowed into the space between the frame 6 and the motor 4 flows into the space between the frame 6 and the motor 4 through the space between the rotor 4a and the stator 4b, and returns to the oil pan 3a through the sub frame 20.
Furthermore, part of the oil that has flowed into the oil passage 7a reaches upper end part of the shaft 7, and lubricates the orbiting bearing 8c. The oil that has lubricated the orbiting bearing 8c flows into the space between the frame 6 and the orbiting scroll 40. Then, the oil that has flowed t into the space between the frame 6 and the orbiting scroll 40 lubricates the Oldham ring 15. Then, the oil that has lubricated the Oldham ring 15 and the oil that flows into the space between the frame 6 and the orbiting scroll 40 flow into the oil discharge pipe 21. The oil that has flowed into the oil discharge pipe 21 flows into the space between the frame 6 and the sub frame 20 and returns to the oil pan 3a through the sub frame 20.
It should be noted that part of the oil that has flowed into the oil passage 7a and has reached the upper end portion of the shaft 7 flows into the first hole 50a of the supply hole 50, then reaches the thrust surface 40a through the second hole 50b, and lubricates the thrust surface 40a. While the orbiting scroll 40 is orbiting, when the second hole 50b and the oil supply hole 52 do not communicate with each other, oil remains in the second hole 50b. By contrast, while the orbiting scroll 40 is orbiting, when the second hole 50b and the oil supply hole 52 communicate with each other, oil reaches the oil discharge pipe 21 through the oil supply hole 52 and is let out from the oil discharge pipe 21.
In addition, when the pressure of oil that flows in the oil passage 7a is higher than the threshold pressure, the bypass valve 62 of the oil pump 3 is opened, and part of the oil returns to the oil pan 13 through the bypass passage 63.
According to Embodiment 1, the oil pump 3 includes the bypass valve 62, which is opened to return part of the oil to the oil pan 13 when the pressure of oil that flows in the oil passage 7a is higher than the threshold pressure. The bypass valve 62 of the oil pump 3 is opened when the pressure of oil that flows in the oil passage 7a in a high-speed operation in which the rotation speed of the compression unit 5 is high is raised to a high value. As a result, part of the oil is returned to the oil pan 13. It is therefore possible to reduce an increase in the amount of oil supply in the high-speed operation of the compression unit 5. Accordingly, the compressor 1 is capable of reducing an increase in oil loss.
In existing scroll compressors using a positive-displacement pump whose volume is constant, bearings and a compression unit may be worn because of reduction in the amount of oil supply in a low-speed operation in which the rotation speed is low. Thus, in the existing scroll compressors, it is hard to ensure reliability. By contrast, in Embodiment 1, since the oil pump 3 includes the bypass valve 62, it is possible to reduce an increase in the amount of oil supply in the high-speed operation of the compression unit 5. Therefore, it is possible to use the oil pump 3, which has a larger volume than an existing oil pump, and thus to increase the amount of oil supply in the low-speed operation.
The compression unit 5 includes the fixed scroll 30, which is fixed in the shell 2, and the compression chambers 5a, which are connected to the upper end part of the shaft 7 and which are configured to compress a working gas in conjunction with the fixed scroll 30. The compression unit 5 further includes the orbiting scroll 40, which has the thrust surface 40a as its lower surface, and the thrust plate 46, which is provided at the thrust surface 40a of the orbiting scroll 40. The orbiting scroll 40 has the supply hole 50, through which the oil passage 7a and the thrust surface 40a communicate with each other, and through which oil flowing in the oil passage 7a is supplied to the thrust surface 40a. The thrust plate 46 has the oil supply hole 52, which communicates with the supply hole 50 when the orbiting scroll 40 orbits. Part of the oil that has flowed into the oil passage 7a and that has reached the upper end part of the shaft 7 enters the first hole 50a of the supply hole 50, then reaches the thrust surface 40a through the second hole 50b, and lubricates the thrust surface 40a.
While the orbiting scroll 40 is orbiting, when the second hole 50b and the oil supply hole 52 do not communicate with each other, oil remains in the second hole 50b. Therefore, the amount of oil that flows in the oil passage 7a is not reduced, and the pressure of oil that flows in the oil passage 7a is raised to a high value. As a result, the bypass valve 62 of the oil pump 3 is opened, and part of the oil is returned to the oil pan 13. By contrast, while the orbiting scroll 40 is orbiting, when the second hole 50b and the oil supply hole 52 communicate with each other, oil flows to the compression unit 5 through the oil supply hole 52 or reaches the oil discharge pipe 21 and is discharged therethrough. In this case, the pressure of oil that flows in the oil passage 7a is not increased, and the bypass valve 62 of the oil pump 3 is closed. When the bypass valve 62 is closed, the amount of oil drawn by the oil pump 3 is constant regardless of the rotation speed of the compression unit 5.
It should be noted the time during which the second hole 50b and the oil supply hole 52 communicates with each other while the orbiting scroll 40 is making one revolution in the high-speed operation in which the rotation speed of the compression unit 5 is high is shorter than that in the low-speed operation. Thus, in the high-speed operation, oil is hard to discharge, as compared with the low-speed operation. Therefore, the pressure of oil that flows in the oil passage 7a is raised to a high value, and the bypass valve 62 of the oil pump 3 is opened. Thus, part of the oil is returned to the oil pan 13. Accordingly, it is possible to reduce an increase in the amount of oil supply in the high-speed operation of the compression unit 5. Therefore, the compressor 1 is capable of reducing an increase in oil loss.
The orbiting scroll 40 includes the orbiting scroll lap 41, which is formed in such a manner as to spiral outward from the center of the orbiting scroll 40. The second hole 50b is formed such that the second hole 50b and the outer end 80 of the orbiting scroll lap 41 are located symmetrical with respect to the center point of the orbiting scroll 40. In the case where a bending stress acts on the base plate 43 of the orbiting scroll 40 during the operation of the compressor 1, the outer end 80 of the orbiting scroll lap 41 is most unlikely to be deformed because the outer end 80 is located at the outermost periphery of the base plate 43. By contrast, in the case where part of the orbiting scroll 40 and the outer end 80 are located symmetrical with respect to the center point, the part of the orbiting scroll 40 is most likely deformed. This may cause seizure between the orbiting scroll 40 and the thrust plate 46. In Embodiment 1, the second hole 50b is formed such that the second hole 50b and the outer end 80 are located symmetrical with respect to the center point, and oil is thus sequentially discharged from the position of the outer end 80. As a result, it is possible to improve the sliding characteristic of the part that is most likely deformed.
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In Embodiment 4, since the two supply holes 50 and the two oil supply holes 52 are formed, the total area of oil discharge passages is increased, thereby increasing the amount of oil that reaches the compression unit 5 after being discharged through the oil supply holes 52 in the low-speed operation, in which the time during which the second holes 50b and the oil supply holes 52 communicate with each other while the orbiting scroll 340 makes one revolution is long. By contrast, in the high-speed operation, in which the time during which the second holes 50b and the oil supply holes 52 communicate with each other while the orbiting scroll 340 makes one revolution is short, oil is not discharged through the oil supply holes 52 and the pressure of oil in the oil passage 7a is raised to a high value. Thus, the bypass valve 62 of the oil pump 3 is opened, and part of the oil is returned to the oil pan 13. In such a manner, compared with Embodiment 4, the amount of oil that is supplied in the low-speed operation of the compressor 1 is increased, and the amount of oil that is supplied in the high-speed operation of the compressor 1 is decreased. It should be noted that since the amount of oil discharged from the orbiting scroll 340 is increased, the sliding characteristic of each of sliding portions is improved.
The configurations described above regarding Embodiments 1 to 4 can be changed as appropriate.
1: compressor, 2: shell, 2a: upper shell, 2b: lower shell, 3: oil pump, 13: oil pan, 4: motor, 4a: rotor, 4b: stator, 5: compression unit, 5a: compression chamber, 6: frame, 7: shaft, 7a: oil passage, 8a: main bearing, 8b: sub bearing, 8c: orbiting bearing, 9: discharge port, 10: discharge valve, 11: suction pipe; 12: discharge pipe, 14: muffler, 15: Oldham ring, 15a: Oldham groove, 16: slider, 17: sleeve, 18: first balancer, 18a: balancer cover, 19: second balancer, 20: sub frame, 21: oil discharge pipe, 30: fixed scroll, 30a: panel, 30b: fixed scroll lap, 40: orbiting scroll, 40a: thrust surface, 41: orbiting scroll lap, 43: base plate, 44: boss, 45: eccentric portion, 46: thrust plate, 50: supply hole, 50a: first hole, 50b: second hole, 51: set screw, 52: oil supply hole, 60: pump suction port, 61: pump discharge port, 62: bypass valve, 63: bypass passage, 64: spring, 70: refrigerant circuit, 70a: refrigerant pipe, 72: flow switching device, 73: outdoor heat exchanger, 74: outdoor fan, 75: expansion unit, 76: indoor heat exchanger, 77: indoor fan, 80: outer end, 100: air-conditioning apparatus, 101: outdoor unit, 102: indoor unit, 103: oil pump, 165: valve seat, 166: valve retainer, 203: oil pump, 265: valve seat, 340: orbiting scroll, 346: thrust plate
Filing Document | Filing Date | Country | Kind |
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PCT/JP2020/002072 | 1/22/2020 | WO |