Rotary compressor and refrigeration cycle apparatus

TECHNICAL FIELD

The present invention relates to a rotary compressor and a refrigeration cycle apparatus.

BACKGROUND ART

It is known that the efficiency of a refrigeration cycle apparatus is increased by injecting a gas phase refrigerant having an intermediate pressure into a compressor (see Patent Literature 1). With this technique, since the work of the compressor and the pressure loss of the refrigerant in an evaporator can be reduced, the coefficient of performance (COP) of the refrigeration cycle is improved.

As a compressor that can be applied to the injection technique, a rolling piston compressor provided with a plurality of vanes (blades) so as to form a first compression chamber and a second compression chamber within a cylinder has been proposed (see Patent Literature 2).

FIG. 15 is a configuration diagram of a heat pump type heating apparatus described in FIG. 3 of Patent Literature 2. A heat pump type heating apparatus 500 includes a rolling piston compressor 501, a condenser 503, an expansion mechanism 504, a gas-liquid separator 507, and an evaporator 509, and is configured to compress a gas phase refrigerant from the evaporator 509 and an intermediate pressure gas phase refrigerant separated in the gas-liquid separator 507, respectively, in the compressor 501. Vanes 525 and 535 attached to a cylinder 522 of the compressor 501 divide the space between the cylinder 522 and a rotor 523 into a main compression chamber 526 and an auxiliary compression chamber 527. The main compression chamber 526 has a suction port 526a and a discharge port 526b. The auxiliary compression chamber 527 has a suction port 527a and a discharge port 527b. The suction port 526a is connected to the evaporator 509, and the suction port 527a is connected to the gas-liquid separator 507. The discharge port 526b and the discharge port 527b are merged together and connected to the condenser 503.

CITATION LIST
Patent Literature

Patent Literature 1 JP 2006-112753 A

Patent Literature 2 JP 03(1991)-53532 B

SUMMARY OF INVENTION
Technical Problem

The present inventors have studied in detail the heat pump type heating apparatus 500 described in Patent Literature 2 to determine whether it can be practically used. As a result, they have ascertained that the compressor 501 has the following technical problems.

First, as shown in FIG. 16, in a conventional rolling piston compressor having only one vane, a force to press a vane 540 against a piston 543 is generated mainly due to a difference between a pressure applied to a front surface 541 of the vane 540 and a pressure applied to a rear surface 542 thereof. If the compressor is a high-pressure shell type compressor, a pressure equal to a discharge pressure (high pressure) is applied to the rear surface 542 of the vane 540. The vane 540 has the front surface 541 having an arc shape in plan view, and is in contact with the piston 543 at the front surface 541. When only one vane 540 is provided in one cylinder, the right side of the front surface 541 with respect to the point of contact between the vane 540 and the piston 543 is always exposed to a suction pressure (low pressure) from a suction port 544. The left side of the front surface 541 is exposed to a pressure that varies between the suction pressure (low pressure) and the discharge pressure (high pressure). Even when the left side of the front surface 541 is exposed to the discharge pressure (high pressure), the right side of the front surface 541 is always exposed to the suction pressure (low pressure), and thus a sufficient pressure difference is maintained between the front surface 541 and the rear surface 542. Therefore, a force great enough to press the vane 540 against the piston 543 is always applied to the vane 540.

On the other hand, in a rolling piston compressor 501 described in Patent Literature 2, two vanes are provided in one cylinder. Pressing forces applied to the two vanes are discussed based on the same logic applied to a rolling piston compressor having only one vane. As shown in FIG. 15, one side of the front surface of the vane 525 is always exposed to a suction pressure (low pressure) from the suction port 526a. The other side of the front surface of the vane 525 is exposed to a pressure in the auxiliary compression chamber 527. The pressure in the auxiliary compression chamber 527 varies between a pressure (intermediate pressure) of a gas phase refrigerant separated in the gas-liquid separator 507 and a discharge pressure (high pressure). Therefore, if it is assumed that the rolling piston compressor 501 is a high-pressure shell type compressor, a force great enough to press the vane 525 against the piston 523 is applied to the vane 525.

Next, one side of the front surface of the vane 535 is always exposed to a suction pressure from the suction port 527a, that is, the pressure (intermediate pressure) of the gas phase refrigerant separated in the gas-liquid separator 507. The other side of the front surface of the vane 535 is exposed to a pressure in the main compression chamber 526. The pressure in the main compression chamber 526 varies between the suction pressure (low pressure) and the discharge pressure (high pressure). Therefore, the pressing force applied to the vane 535 (minimum pressing force) is less than the pressing force applied to the vane 525 and that applied to the vane 540 of the conventional rolling piston compressor.

If the pressing force applied to the vane is small, a malfunction called “vane jumping” may occur. As stated herein, “vane jumping” means a phenomenon in which the tip of the vane loses contact with the piston. Vane jumping may cause a significant decrease in the compressor efficiency.

It is an object of the present invention to prevent vane jumping in a rotary compressor that can be applied to the injection technique.

Solution to Problem

The present invention provides a rotary compressor including: a cylinder; a piston disposed within the cylinder so as to form a space between the piston itself and the cylinder; a shaft to which the piston is fitted; a first vane for dividing the space along a circumferential direction of the piston, the first vane being attached to the cylinder at a first angular position along a rotation direction of the shaft; and a second vane for further dividing the space divided by the first vane along the circumferential direction of the piston so that a first compression chamber and a second compression chamber having a smaller volume than the first compression chamber are formed within the cylinder, the second vane being attached to the cylinder at a second angular position along the rotation direction of the shaft. The piston and the second vane are integrated together or the piston and the second vane are coupled together.

In a preferred embodiment, the rotary compressor of the present invention further includes: a first suction port for introducing a working fluid to be compressed in the first compression chamber into the first compression chamber; a first discharge port for discharging the working fluid compressed in the first compression chamber outside the first compression chamber from the first compression chamber; a second suction port for introducing the working fluid to be compressed in the second compression chamber into the second compression chamber; a second discharge port for discharging the working fluid compressed in the second compression chamber outside the second compression chamber from the second compression chamber; and a suction check valve provided in the second suction port.

In another aspect, the present invention provides a refrigeration cycle apparatus including: the rotary compressor according to the preferred embodiment; a radiator for cooling the working fluid compressed in the rotary compressor; an expansion mechanism for expanding the working fluid cooled in the radiator; a gas-liquid separator for separating the working fluid expanded in the expansion mechanism into a gas phase working fluid and a liquid phase working fluid; an evaporator for evaporating the liquid phase working fluid separated in the gas-liquid separator; a suction flow path for introducing the working fluid that has flowed out of the evaporator into the first suction port of the rotary compressor; and an injection flow path for introducing the gas phase working fluid separated in the gas-liquid separator into the second suction port of the rotary compressor.

Advantageous Effects of Invention

In the rotary compressor of the present invention, the piston and the second vane are integrated together, or the piston and the second vane are coupled together. In this case, there is essentially no problem of vane jumping. Therefore, the present invention can provide a rotary compressor with a high compressor efficiency, in which vane jumping could never occur. A refrigeration cycle apparatus using the rotary compressor of the present invention can enjoy the benefit of a high injection effect.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a configuration diagram of a refrigeration cycle apparatus according to a first embodiment of the present invention.

FIG. 2 is a longitudinal cross-sectional view of a rotary compressor used in the refrigeration cycle apparatus shown in FIG. 1.

FIG. 3 is a transverse cross-sectional view of the rotary compressor shown in FIG. 2, taken along the line A-A.

FIG. 4A is a schematic plan view showing a structure for preventing vane jumping.

FIG. 4B is a schematic plan view showing another structure for preventing vane jumping.

FIG. 4C is a schematic plan view showing still another structure for preventing vane jumping.

FIG. 4D is a schematic plan view showing still another structure for preventing vane jumping.

FIG. 4E is a schematic plan view showing still another structure for preventing vane jumping.

FIG. 4F is a schematic plan view showing still another structure for preventing vane jumping.

FIG. 5 is an enlarged cross-sectional view of a suction check valve.

FIG. 6A shows side and plan views of a valve body.

FIG. 6B shows side and plan views of a valve stopper.

FIG. 7 is a perspective view of a compression mechanism.

FIG. 8 is a schematic diagram showing the operation of the rotary compressor with the rotation angle of a shaft.

FIG. 9A is a PV diagram of a first compression chamber.

FIG. 9B is a PV diagram of a second compression chamber.

FIG. 10 is a PV diagram of the second compression chamber showing the compression work that can be reduced by injection.

FIG. 11A is a schematic diagram showing the operation of a rotary compressor provided with no suction check valve.

FIG. 11B is a PV diagram of a second compression chamber shown in FIG. 11A.

FIG. 12 is a schematic diagram showing a modification designed to have an obtuse angle between a first vane and a second vane.

FIG. 13 is a longitudinal cross-sectional view of a rotary compressor according to a modification.

FIG. 14 is a transverse cross-sectional view of the rotary compressor shown in FIG. 13, taken along the line B-B.

FIG. 15 is a configuration diagram of a conventional heat pump type heating apparatus.

FIG. 16 is a transverse cross-sectional view of a conventional rolling piston compressor having only one vane.

FIG. 17 is a schematic diagram showing a problem that may occur when a second vane is not coupled with a piston.

DESCRIPTION OF EMBODIMENTS

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. The present invention is not limited by the embodiments described below. The embodiments and modifications can be combined with one another, without departing from the spirit and scope of the invention.

First Embodiment

FIG. 1 is a configuration diagram of a refrigeration cycle apparatus according to the present embodiment. A refrigeration cycle apparatus 100 includes a rotary compressor 102, a first heat exchanger 104, a first expansion mechanism 106, a gas-liquid separator 108, a second expansion mechanism 110, and a second heat exchanger 112. These components are connected in a loop in this order by flow paths 10a to 10d so as to form a refrigerant circuit 10. The flow paths 10a to 10d are typically constituted by refrigerant pipes. The refrigerant circuit 10 is filled with a refrigerant, such as hydrofluorocarbon or carbon dioxide, as a working fluid.

The refrigeration cycle apparatus 100 further includes an injection flow path 10j. The injection flow path 10j has one end connected to the gas-liquid separator 108 and the other end connected to the rotary compressor 102, and introduces a gas phase refrigerant separated in the gas-liquid separator 108 directly into the rotary compressor 102. The injection flow path 10j is typically constituted by a refrigerant pipe. A pressure reducing valve may be provided in the injection flow path 10j. An accumulator may be provided in the injection flow path 10j.

A four-way valve 116, as a switching mechanism capable of switching the flow direction of the refrigerant, is provided in the refrigerant circuit 10. When the four-way valve 116 is controlled as indicated by solid lines in FIG. 1, the refrigerant compressed in the rotary compressor 102 is supplied to the first heat exchanger 104. In this case, the first heat exchanger 104 functions as a radiator (condenser) for cooling the refrigerant compressed in the rotary compressor 102. The second heat exchanger 112 functions as an evaporator for evaporating a liquid phase refrigerant separated in the gas-liquid separator 108. On the other hand, when the four-way valve 116 is controlled as indicated by dashed lines in FIG. 1, the refrigerant compressed in the rotary compressor 102 is supplied to the second heat exchanger 112. In this case, the first heat exchanger 104 functions as an evaporator and the second heat exchanger 112 functions as a radiator. The four-way valve 116 allows, for example, an air conditioner using the refrigeration cycle apparatus 100 to have both cooling and heating functions.

The rotary compressor 102 is a device for compressing the refrigerant to a high temperature and high pressure state. The rotary compressor 102 has a first suction port 19 (main suction port) and a second suction port 20 (injection suction port). The flow path 10d is connected to the first suction port 19 so that the refrigerant that has flowed out of the first heat exchanger 104 or the second heat exchanger 112 is introduced into the rotary compressor 102. The injection path 10j is connected to the second suction port 20 so that the gas refrigerant separated in the gas-liquid separator 108 is introduced into the rotary compressor 102.

The first heat exchanger 104 is typically constituted by an air-refrigerant heat exchanger or a water-refrigerant heat exchanger. The second heat exchanger 112 also is typically constituted by an air-refrigerant heat exchanger or a water-refrigerant heat exchanger. When the refrigeration cycle apparatus 100 is used for an air conditioner, both the first heat exchanger 104 and the second heat exchanger 112 are constituted by air-refrigerant heat exchangers. When the refrigeration cycle apparatus 100 is used for a water heater or a hot water heater, the first heat exchanger 104 is constituted by a water-refrigerant heat exchanger, and the second heat exchanger 112 is constituted by an air-refrigerant heat exchanger.

The first expansion mechanism 106 and the second expansion mechanism 110 are devices for expanding the refrigerant cooled in the first heat exchanger 104 (or the second heat exchanger 112) as a radiator or the liquid phase refrigerant separated in the gas-liquid separator 108. The first expansion mechanism 106 and the second expansion mechanism 110 are typically constituted by expansion valves. A preferred expansion valve is an opening adjustable valve, such as, for example, an electronic expansion valve. The first expansion mechanism 106 is provided in the flow path 10b between the first heat exchanger 104 and the gas-liquid separator 108. The second expansion mechanism 110 is provided in the flow path 10c between the gas-liquid separator 108 and the second heat exchanger 112. The expansion mechanisms 106 and 110 each may be constituted by a positive displacement expander capable of recovering power from the refrigerant.

The gas-liquid separator 108 separates the refrigerant expanded in the first expansion mechanism 106 or the second expansion mechanism 110 into a gas phase refrigerant and a liquid phase refrigerant. The gas-liquid separator 108 is provided with an inlet for the refrigerant expanded in the first expansion mechanism 106 or the second expansion mechanism 110, an outlet for the liquid phase refrigerant, and an outlet for the gas phase refrigerant. One end of the injection flow path 10j is connected to the outlet for the gas phase refrigerant.

Other devices such as an accumulator and an internal heat exchanger may be provided in the refrigerant circuit 10.

FIG. 2 is a longitudinal cross-sectional view of the rotary compressor 102 used in the refrigeration cycle apparatus 100 shown in FIG. 1. FIG. 3 is a transverse cross-sectional view of the rotary compressor 102 shown in FIG. 2, taken along the line A-A. The rotary compressor 102 includes a closed casing 1, a motor 2, a compression mechanism 3, and a shaft 4. The compression mechanism 3 is disposed in the lower part of the closed casing 1. The motor 2 is disposed above the compression mechanism 3 in the closed casing 1. The compression mechanism 3 and the motor 2 are coupled by the shaft 4. A terminal 21 for supplying electric power to the motor 2 is provided on the top of the closed casing 1. An oil reservoir 22 for holding lubricating oil is formed in the bottom of the closed casing 1.

The motor 2 is constituted by a stator 17 and a rotor 18. The stator 17 is fixed to the inner wall of the closed casing 1. The rotor 18 is fixed to the shaft 4 and rotates together with the shaft 4.

A discharge pipe 11 is provided in the top wall of the closed casing 1. The discharge pipe 11 penetrates the top wall of the closed casing 1 and opens into an internal space 13 of the closed casing 1. The discharge pipe 11 serves as a discharge flow path for discharging the refrigerant compressed in the compression mechanism 3 outside the closed casing 1. That is, the discharge pipe 11 constitutes a part of the flow path 10a shown in FIG. 1. During the operation of the rotary compressor 102, the internal space 13 of the closed casing 1 is filled with the compressed refrigerant. That is, the rotary compressor 102 is a high-pressure shell type compressor. In the high-pressure shell type rotary compressor 102, since the motor 2 can be cooled by the refrigerant, an increase in the motor efficiency can be expected. When the refrigerant is heated by the motor 2, the heating capability of the refrigeration cycle apparatus 100 also is increased.

The compression mechanism 3 is driven by the motor 2 to compress the refrigerant. As shown in FIG. 2 and FIG. 3, the compression mechanism 3 has a cylinder 5, a main bearing 6, an auxiliary bearing 7, a piston 8, a muffler 9, a first vane 32, a second vane 33, a first discharge valve 43, a second discharge valve 44, and a suction check valve 50. In the present embodiment, only the second suction port 20 of the first and second suction ports 19 and 20 is provided with the suction check valve 50.

The shaft 4 has an eccentric portion 4a projecting outwardly in a radial direction. The piston 8 is disposed within the cylinder 5. Within the cylinder 5, the piston 8 is fitted to the eccentric portion 4a of the shaft 4. A first vane groove 34 and a second vane groove 35 are formed in the cylinder 5. The first vane groove 34 is formed at a first angular position along the rotation direction of the shaft 4. The second vane groove 35 is formed at a second angular position along the rotation direction of the shaft 4.

A first vane 32 (blade) having a tip in contact with the outer peripheral surface of the piston 8 is slidably fitted in the first vane groove 34. The first vane 32 divides the space between the cylinder 5 and the piston 8 along the circumferential direction of the piston 8. A second vane 33 (blade) is slidably fitted in the second vane groove 35. The second vane 33 further divides the space between the cylinder 5 and the piston 8 along the circumferential direction of the piston 8. Thereby, a first compression chamber 25 (main compression chamber) and a second compression chamber 26 (injection compression chamber) having a smaller volume than the first compression chamber 25 are formed within the cylinder 5.

A first spring 36 pressing the first vane 32 toward the center of the shaft 4 is disposed behind the first vane 32. The rear end of the first vane groove 34 is in communication with the internal space 13 of the closed casing 1. Therefore, the pressure in the internal space 13 of the closed casing 1 is applied to the rear surface of the first vane 32. The second vane 33 is coupled to the piston 8. Therefore, no spring is disposed behind the second vane 33. However, a spring may be disposed behind the second vane 33. The second vane groove 35 also is in communication with the internal space 13 of the closed casing 1. Lubricating oil stored in the oil reservoir 22 is supplied to the first vane groove 34 and the second vane groove 35.

In the present description, the position of the first vane 32 and the first vane groove 34 is defined as a position of “0 degrees (a first angle)” along the rotation direction of the shaft 4. In other words, the rotation angle of the shaft 4 at the moment when the first vane 32 is pushed all the way into the first vane groove 34 by the piston 8 is defined as “0 degrees”. The rotation angle of the shaft 4 at the moment when the second vane 33 is pushed all the way into the second vane groove 35 by the piston 8 corresponds to “a second angle”. In the present embodiment, the angle θ (degrees) from the first angular position where the first vane 32 is disposed to the second angular position where the second vane 33 is disposed is, for example, in the range of 270 to 350 degrees in the rotation direction of the shaft 4. In other words, the angle (360-θ) between the first vane 32 and the second vane 33 is in the range of 10 to 90 degrees. When the angle θ is 270 degrees or more, the amount of refrigerant flowing back into the first suction pipe 14 from the first compression chamber 25 through the first suction port 19 is small enough for the suction process of the first compression chamber 25. Therefore, there is no need to provide a check valve in the first suction port 19.

In the present embodiment, the piston 8 is provided with a recessed portion 8s, and the second vane 33 is provided with a projecting portion 33t. The projecting portion 33t of the second vane 33 is fitted in the recessed portion 8s of the piston 8 so that the piston 8 and the second vane 33 are coupled together. Since the piston 8 and the second vane 33 are coupled together, the second vane 33 always follows the movement of the piston 8. Therefore, there is substantially no problem of vane jumping of the second vane 33.

As shown in FIG. 4A, the second vane 33 includes a sliding portion 33a fitted in the second vane groove 35 and the projecting portion 33t located at the tip of the sliding portion 33a. The projecting portion 33t has a circular shape in plan view. The recessed portion 8s of the piston 8 in which the projecting portion 33t is fitted also has a circular shape in plan view. The projecting portion 33t and the recessed portion 8s can rotate relatively to each other while maintaining the coupling of the second vane 33 and the piston 8. When the piston 8 rotates, the second vane 33 slides in the second vane groove 35. In addition, the projecting portion 33t of the second vane 33 rotates in the recessed portion 8s of the piston 8.

The width₁of the projecting portion 33t of the second vane 33 is smaller than the width W₂of the sliding portion 33a in the width direction of the second vane 33. Since such a configuration facilitates the final polishing of the sliding portion 33a, the production cost of the second vane 33 can be reduced. The “width of the vane” means the dimension of the vane in the direction perpendicular to the axial direction of the shaft 4 and to the longitudinal direction of the vane.

The structure capable of preventing vane jumping is not limited to the structure shown in FIG. 4A. Some specific examples are described below.

In an example shown in FIG. 4B, the piston 8 is provided with a projecting portion 8t, and the second vane 33 is provided with a recessed portion 33s. The projecting portion 8t of the piston 8 is fitted in the recessed portion 33s of the second vane 33 so that the piston 8 and the second vane 33 are coupled together. That is, there is no particular limitation on the structure for coupling the vane to the piston.

Next, in an example shown in FIG. 4C, the piston 8 and the first vane 32 are constituted by an integrally formed swing piston 56. That is, the first vane 32 is integrated with the piston 8. A bush 57 (first bush) is disposed in the first vane groove 34 (bush groove). The bush 57 is composed of two members each having an approximately semicircular column shape. The outer peripheral surface of the semicircular columnar member includes a flat surface and a circular arc surface. The flat surface of the semicircular columnar member faces the side surface of the first vane 32, and the circular arc surface thereof faces the circular arc surface of the first vane groove 34. That is, the bush 57 slidably holds the first vane 32, and the bush 57 itself can slide relative to the cylinder 5. As the piston 8 rotates, the first vane 32 moves back and force in the first vane groove 34 while changing its posture little by little. As just described, the first vane 32 is swingably disposed in the first vane groove 34 of the cylinder 5 by means of the bush 57. The bush 57 also can rotate (swing) in the first vane groove 34.

On the other hand, the second vane 33 is coupled to the piston 8. Specifically, as described with reference to FIG. 4A, the projecting portion 33t of the second vane 33 is fitted in the recessed portion 8s of the piston 8. A bush 58 (second bush) holding the second vane 33 is provided at the second angular position so that the second vane 33 can swing as the piston 8 rotates. The movement of the bush 58 disposed in the second vane groove 35 is the same as that of the bush 57 disposed in the first vane groove 34. The projecting portion 33t of the second vane 33 and the recessed portion 8s of the piston 8 can rotate relatively to each other while maintaining the coupling of the second vane 33 and the piston 8. The second vane 33 moves in the same way as the first vane 32, except that the former is coupled to the piston 8 while the latter is integrated with the piston 8.

With a configuration shown in FIG. 4C, not only the second vane 33 but also the first vane 32 can be prevented from jumping. Since the first vane 32 and the second vane 33 swing in the vane groove 34 and the vane groove 35 respectively, the piston 8 can rotate smoothly. As described with reference to FIG. 4B, the projecting portion 8t of the piston 8 may be fitted in the recessed portion 33s of the second vane 33.

Next, in an example shown in FIG. 4D, the same structure as the structure described with reference to FIG. 4A is employed for the second vane 33. In addition to this structure, the piston 8 is further provided with an other recessed portion 8c, and the first vane 32 is provided with a projecting portion 32t. The projecting portion 32t of the first vane 32 is fitted in the other recessed portion 8c of the piston 8. A bush 57 (first bush) holding the first vane 32 is provided at the first angular position so that the first vane 32 can swing as the piston 8 rotates. More specifically, the bush 57 is disposed in the first vane groove 34.

In the fitting structure, there is no limitation on the positional relationship between the projecting portion and the recessed portion. That is, as described with reference to FIG. 4B, the piston 8 may be provided with a projecting portion and the second vane 33 may be provided with a recessed portion. Furthermore, the piston 8 may be provided with an other projecting portion and the first vane 32 may be provided with a recessed portion. In this case, the other projecting portion of the piston 8 can be fitted in the recessed portion of the first vane 32.

Instead of the first vane 32, the second vane 33 may be configured to swing. Both the first vane 32 and the second vane 33 may be configured to swing. That is, a first bush 57 holding the first vane 32 may be provided at the first angular position and/or a second bush 58 (see FIG. 4C) holding the second vane 33 may be provided at the second angular position so that at least one selected from the first vane 32 and the second vane 33 can swing as the piston 8 rotates.

Next, in an example shown in FIG. 4E, the piston 8 and the second vane 33 are constituted by an integrally formed swing piston 59. The structure of the first vane 32 is not particularly limited. In the example shown in FIG. 4E, the first vane 32 has the same structure as a vane used in a typical rolling piston compressor. That is, the first vane 32 is not coupled to the piston 8, nor is it integrated with the piston 8.

Also in an example shown in FIG. 4F, the piston 8 and the second vane 33 are constituted by a swing piston 59. In addition, the swing piston 59 is provided with a recessed portion 8c, and the first vane 32 is provided with a projecting portion 32t. The projecting portion 32t of the first vane 32 is fitted in the recessed portion 8c of the swing piston 59 so that the swing piston 59 and the first vane 32 are coupled together. A bush 57 holding the first vane 32 is provided at the first angular position so that the first vane 32 can swing as the piston 8 rotates. In the example shown in FIG. 4F, the swing piston 59 may be provided with a projecting portion and the first vane 32 may be provided with a recessed portion. In this case, the projecting portion of the swing piston 59 can be fitted in the recessed portion of the first vane 32.

With the structures described with reference to FIG. 4A to FIG. 4F, it is possible to reliably prevent the second vane 33 from separating from the piston 8. Furthermore, in the structures described with reference to FIG. 4A to FIG. 4F, the axial rotation of the piston 8 is inhibited. The “axial rotation of the piston 8” means that the piston 8 can rotate freely with respect to the eccentric portion 4a of the shaft 4, the first vane 32, and the second vane 33. When the axial rotation of the piston 8 is inhibited, a specific part of the piston 8 always faces the second compression chamber 26 and the other part thereof always faces the first compression chamber 25. The temperature of the refrigerant compressed in the second compression chamber 26 is slightly lower (for example, by about 10° C.) than that of the refrigerant compressed in the first compression chamber 25. Therefore, during the operation of the rotary compressor 102, the temperature of the specific part of the piston 8 is slightly lower than that of the other part thereof. If the temperature of the specific part is lower than that of the other part, the refrigerant drawn into the second compression chamber 26 is less likely to receive heat from the piston 8. Since the refrigerant drawn into the second compression chamber 26 is less likely to receive heat from the piston 8, a decrease in the volumetric efficiency of the second compression chamber 26 caused by the expansion of the refrigerant drawn thereinto can be suppressed.

Referring back to FIG. 2 and FIG. 3, the other components are described.

As shown in FIG. 2, the main bearing 6 and the auxiliary bearing 7 are disposed on and beneath the cylinder 5 to close the cylinder 5. The muffler 9 is provided on the main bearing 6 and covers the first discharge valve 43 and the second discharge valve 44. A discharge port 9a for discharging the compressed refrigerant to the internal space 13 of the closed casing 1 is formed in the muffler 9. The shaft 4 penetrates the central portion of the muffler 9 and is rotatably supported by the main bearing 6 and the auxiliary bearing 7.

As shown in FIG. 2 and FIG. 3, in the present embodiment, the first suction port 19 and the second suction port 20 are formed in the cylinder 5. The first suction port 19 introduces the refrigerant to be compressed in the first compression chamber 25 into the first compression chamber 25. The second suction port 20 introduces the refrigerant to be compressed in the second compression chamber 26 into the second compression chamber 26. The first suction port 19 and the second suction port 20 may each be formed in the main bearing 6 or the auxiliary bearing 7.

In the present embodiment, the second suction port 20 has a smaller opening area than the first suction port 19. The smaller the opening area of the second suction port 20 is, the smaller the sizes of the parts of the suction check valve 50 are. This is important in suppressing an increase in dead volume caused by the suction check valve 50 and in providing a design margin. When the opening area of the first suction port 19 is S₁and the opening area of the second suction port 20 is S₂, the opening areas S₁and S₂satisfy, for example, 1.1≦(S₁/S₂)≦30. The “dead volume” refers to the volume that does not serve as a working chamber. Generally, a large dead volume is not preferable for a positive displacement fluid machine.

As shown in FIG. 3, the first suction pipe 14 (main suction pipe) and the second suction pipe 16 (injection suction pipe) are connected to the compression mechanism 3. The first suction pipe 14 is fitted in the cylinder 5 through the barrel portion of the closed casing 1 so as to supply the refrigerant to the first suction port 19. The first suction pipe 14 constitutes a part of the flow path 10d shown in FIG. 1. The second suction pipe 16 is fitted in the cylinder 5 through the barrel portion of the closed casing 1 so as to supply the refrigerant to the second suction port 20. The second suction pipe 16 constitutes a part of the injection flow path 10j shown in FIG. 1.

The compression mechanism 3 further is provided with a first discharge port 40 (main discharge port) and a second discharge port 41 (injection discharge port). The first discharge port 40 and the second discharge port 41 are each formed in the main bearing 6 in a manner as to penetrate the main bearing 6 in the axial direction of the shaft 4. The first discharge port 40 discharges the refrigerant compressed in the first compression chamber 25 outside the first compression chamber 25 (into the internal space of the muffler 9 in the present embodiment) from the first compression chamber 25. The second discharge port 41 discharges the refrigerant compressed in the second compression chamber 26 outside the second compression chamber 26 (into the internal space of the muffler 9 in the present embodiment) from the second compression chamber 26. The first discharge port 40 and the second discharge port 41 are provided with a first discharge valve 43 and a second discharge valve 44 respectively. When the pressure in the first compression chamber 25 exceeds the pressure in the internal space 13 of the closed casing 1 (high pressure of the refrigeration cycle), the first discharge valve 43 opens. When the pressure in the second compression chamber 26 exceeds the pressure in the internal space 13 of the closed casing 1, the second discharge valve 44 opens.

The muffler 9 serves as a discharge flow path connecting the internal space 13 of the closed casing 1 and each of the first discharge port 40 and the second discharge port 41. The refrigerant discharged outside the first compression chamber 25 through the first discharge port 40 and the refrigerant discharged outside the second compression chamber 26 through the second discharge port 41 are merged together in the muffler 9. The merged refrigerant flows into the discharge pipe 11 through the internal space 13 of the closed casing 1. The motor 2 is disposed in the closed casing 1 to be located in the flow path of the refrigerant from the muffler 9 to the discharge pipe 11. With such a configuration, efficient cooling of the motor 2 by the refrigerant and efficient heating of the refrigerant by the heat of the motor 2 can be achieved.

In the present embodiment, the second discharge port 41 has a smaller opening area than the first discharge port 40. The smaller the opening area of the second discharge port 41 is, the more the dead volume caused by the second discharge port 41 can be reduced. When the opening area of the first discharge port 40 is S₃and the opening area of the second discharge port 41 is S₄, the opening areas S₃and S₄satisfy, for example, 1.1≦(S₃/S₄)≦15.

The opening area S₂of the second suction port 20 may be equal to the opening area S₁of the first suction port 19 in some cases. Furthermore, the opening area S₄of the second discharge port 41 may be equal to the opening area S₃of the first discharge port 40 in some cases. The size of each of the suction ports and the discharge ports should be determined appropriately in view of the flow rate of the refrigerant at that port. More specifically, the size should be determined in view of the balance between the dead volume and the pressure loss.

For the reason described below, the rotary compressor 102 of the present embodiment includes not only the discharge valves 43 and 44 but also a suction check valve 50 provided in the second suction port 20. In the compressor 501 described in Patent Literature 2, when it shifts from a suction process to a compression process, a large amount of refrigerant may flow back into the suction port 527a from the auxiliary compression chamber 527. This causes a decrease in compressor efficiency. Therefore, even if the compressor 501 described in Patent Literature 2 is used to construct a refrigeration cycle apparatus, an increase in the COP of the refrigeration cycle cannot be expected. The suction check valve 50 can solve this problem.

As shown in FIG. 5, the suction check valve 50 includes a valve body 51 and a valve stopper 52. A shallow groove 5g having a strip shape in plan view is formed on the top surface 5p of the cylinder 5, and the valve body 51 and the valve stopper 52 are fitted in the groove 5g. The groove 5g extends outwardly in a radial direction of the cylinder 5 and is in communication with the second compression chamber 26. The second suction port 20 opens into the bottom of the groove 5g. Specifically, the second suction port 20 is constituted by a closed-end hole formed in the cylinder 5, and the other end of the hole opens into the bottom of the groove 5g. In the cylinder 5, a suction flow path 5f extending from the outer peripheral surface of the cylinder 5 to the center thereof is formed so as to supply the refrigerant to the second suction port 20. The suction pipe 16 is connected to the suction flow path 5f.

As shown in FIG. 6A, the valve body 51 has a back surface 51q for closing the second suction port 20 and a front surface 51p to be exposed to the atmosphere in the second compression chamber 26 when the second suction port 20 is closed. The range of movement of the valve body 51 of the suction check valve 50 is determined in the second compression chamber 26. The valve body 51 has a thin plate shape as a whole. Typically, the valve body 51 is constituted by a thin metal plate (reed valve).

As shown in FIG. 6B, the valve stopper 52 has a supporting surface 52q for limiting the amount of displacement of the valve body 51 in the thickness direction thereof when the second suction port 20 is opened. The supporting surface 52q forms a slightly curved surface so that the thickness of the valve stopper 52 decreases as it approaches the second compression chamber 26. That is, the valve stopper 52 has a shoetree-like shape as a whole. The front end surface 52t of the valve stopper 52 has a shape of a circular arc having the same radius of curvature as the inner radius of the cylinder 5.

The valve body 51 is disposed in the groove 5g so as to open and close the second suction port 20. The valve stopper 52 is disposed in the groove 5g so that the supporting surface 52q is exposed to the atmosphere in the second compression chamber 26 when the valve body 51 closes the second suction port 20. The valve body 51 and the valve stopper 52 are fixed to the cylinder 5 by a fastening member 54 such as a bolt. The rear end of the valve body 51 cannot move between the valve stopper 52 and the groove 5g, but the front end of the valve body 51 is not fixed and can swing. In a plan view of the valve stopper 52 and the second suction port 20, the second suction port 20 and the supporting surface 52q of the valve stopper 52 lie on top of each other.

The total thickness of the valve body 51 and the valve stopper 52 near the rear end of the valve stopper 52 is almost equal to the depth of the groove 5g. When the valve body 51 and the valve stopper 52 are fitted into the groove 5g, the level of the top surface 52p of the valve stopper 52 coincides with that of the cylinder 5 in the thickness direction of the cylinder 5.

As shown in FIG. 6A, the valve body 51 has a widened portion 55 for opening and closing the second suction port 20. The maximum width W₁of the widened portion 55 is greater than the width W₂of the front end of the valve stopper 52, in other words, greater than the width of the groove 5g at a position where it faces the cylinder 5. With the widened portion 55, an increase in the dead volume can be suppressed while the seal width for closing the second suction port 20 is secured.

As shown in FIG. 5 and FIG. 7, the depth of the groove 5g is, for example, smaller than a half of the thickness of the cylinder 5. The valve stopper 52 occupies a large part of the groove 5g. Only a small part of the groove 5g remains as the range of movement of the valve body 51.

The suction check valve 50 operates in the following manner as the shaft 5 rotates. When the pressure in the second compression chamber 26 falls below the pressure in the suction flow path 5f and the second suction pipe 16, the valve body 51 is displaced to conform to the shape of the supporting surface 52q of the valve stopper 52. In other words, the valve body 51 is pushed up. Thereby, the second suction port 20 is brought into communication with the second compression chamber 26, so that the refrigerant is supplied to the second compression chamber 26 through the second suction port 20. On the other hand, when the pressure in the second compression chamber 26 exceeds the pressure in the suction flow path 5f and the second suction pipe 16, the valve body 51 returns to its original flat shape. Thereby, the second suction port 20 is closed. Therefore, it is possible to prevent the refrigerant drawn into the second compression chamber 26 from flowing back to the suction flow path 5f and the second suction pipe 16 through the second suction port 20.

With the structural features of the suction check valve 50 of the present embodiment described above, it is possible to suppress an increase in dead volume caused by the presence of a check valve in the suction port. That is, the suction check valve 50 contributes to a high compressor efficiency. Accordingly, the refrigeration cycle apparatus 100 using the rotary compressor 102 of the present embodiment has a high COP.

The second suction port 20 may be formed in the main bearing 6 or the auxiliary bearing 7. In this case, the suction check valve 50 having the structure described with reference to FIG. 5, etc. can be provided in the main bearing 6 or the auxiliary bearing 7. A member (closing member) for closing the cylinder 5 may be provided between the main bearing 6 (or the auxiliary bearing 7) and the cylinder 5. The suction check valve 50 may be provided in that member.

Next, the operation of the rotary compressor 102 is described in time series with reference to FIG. 8. The angles in FIG. 8 represent the rotation angles of the shaft 4. The angles shown in FIG. 8 are merely examples, and each process does not always start or end at the angle shown in FIG. 8. A suction process of drawing the refrigerant into the first compression chamber 25 starts when the shaft 4 has a rotation angle of 0 degrees and takes place until the shaft 4 has a rotation angle of approximately 360 degrees. The refrigerant drawn into the first compression chamber 25 is compressed as the shaft 4 rotates. The compression process continues until the pressure in the first compression chamber 25 exceeds the pressure in the internal space 13 of the closed casing 1. In FIG. 8, the compression process starts when the shaft 4 has a rotation angle of 360 degrees and takes place until the shaft 4 has a rotation angle of 540 degrees. A process of discharging the compressed refrigerant outside the first compression chamber 25 takes place until the point of contact between the cylinder 5 and the piston 8 passes the first discharge port 40. In FIG. 8, the discharge process starts when the shaft 4 has a rotation angle of 540 degrees and takes place until the shaft 4 has a rotation angle of (630+α) degrees. “α” denotes an angle between the angular position of 270 degrees and the second angular position where the second vane 33 is disposed.

On the other hand, a suction process of drawing the refrigerant into the second compression chamber 26 starts when the shaft 4 has a rotation angle of (270+α) degrees and takes place until the shaft 4 has a rotation angle of (495+α/2) degrees. (495+α/2) is a rotation angle of the shaft 4 at which the second compression chamber 26 has a maximum volume. The refrigerant drawn into the second compression chamber 26 is compressed as the shaft 4 rotates. The compression process continues until the pressure in the second compression chamber 26 exceeds the pressure in the internal space 13 of the closed casing 1. In FIG. 8, the compression process starts when the shaft 4 has a rotation angle of (495+α/2) degrees and takes place until the shaft 4 has a rotation angle of 630 degrees. A process of discharging the compressed refrigerant outside the second compression chamber 26 takes place until the point of contact between the cylinder 5 and the piston 8 passes the second discharge port 41. In FIG. 8, the discharge process starts when the shaft 4 has a rotation angle of 630 degrees and takes place until the shaft 4 has a rotation angle of 720 degrees.

FIG. 9A and FIG. 9B show the PV diagrams of the first compression chamber 25 and the second compression chamber 26 respectively. As shown in FIG. 9A, the suction process in the first compression chamber 25 is represented by a change from Point A to Point B. The volume of the first compression chamber 25 becomes maximum at Point B. However, since the first compression chamber 25 is not provided with a check valve, a small amount of refrigerant flows back into the first suction port 19 from the first compression chamber 25 between Point B and Point C. Therefore, the actual suction volume (confined volume) of the first compression chamber 25 is identified as the volume at Point C. The compression process is represented by a change from Point C to Point D. The discharge process is represented by a change from Point D to Point E.

As shown in FIG. 9B, the suction process in the second compression chamber 26 is represented by a change from Point F to Point G. The backflow amount of the refrigerant from the second compression chamber 26 into the second suction port 20 is nearly zero owing to the function of the suction check valve 50. Therefore, the maximum volume of the second compression chamber 26 is equal to the actual suction volume. The compression process is represented by a change from Point G to Point H. The discharge process is represented by a change from Point H to Point I. Since the second compression chamber 26 draws and compresses a gaseous refrigerant having an intermediate pressure, the compression work corresponding to the area of a shaded region can be reduced, as shown in FIG. 10. Thereby, the efficiency of the refrigeration cycle apparatus 100 is increased. It should be noted that FIG. 9B and FIG. 10 are PV diagrams obtained by assuming that the dead volume caused by the suction check valve 50 is zero.

For information, FIG. 11A is a schematic diagram showing the operation of a rotary compressor without a suction check valve. The angle between two vanes is 90 degrees. A compression chamber 536 and a suction port 537 correspond to the second compression chamber 26 and the second suction port 20, respectively, of the present embodiment. In the state shown in the left side of FIG. 11A, the compression chamber 536 has a maximum volume. However, during the rotation of the shaft 534 from the state shown in the left side to the state shown in the right side, a refrigerant flows from the compression chamber 536 back into the suction port 537 (backflow process).

In fact, as shown in FIG. 11B, when the maximum volume is represented as a volume at Point J, the volume at the moment when the compression actually starts (actual suction volume) is represented as a volume at Point G. That is, a considerable percentage of the refrigerant (corresponding to a volume obtained by subtracting the volume at Point G from the volume at Point J) is pushed out of the compression chamber 536 in the backflow process. Therefore, a very large loss occurs. A shaded region in FIG. 11B represents the sum of a loss that occurs when the compression chamber 536 draws the refrigerant from Point F to Point J and a loss that occurs due to the backflow of the refrigerant when the volume of the compression chamber 536 decreases from Point J to Point G (the sum is an unnecessary compression work). Furthermore, there is a concern that the backflow of the refrigerant causes pulsation, which may increase noise and vibration. The rotary compressor 102 of the present embodiment can solve these problems.

In each of FIG. 9A, FIG. 9B, FIG. 10 and FIG. 11B, the vertical axis (pressure axis) and the horizontal axis (volume axis) are drawn on the same scale. FIG. 11A and FIG. 11B are diagrams for explaining the problems that may occur without a suction check valve, and are not the prior art of the present invention.

Next, the positional relationship between the first vane 32 and the second vane 33 is described. The positional relationship between them is also closely related to the timing of opening and closing the suction check valve 50. The open/close timing of the suction check valve 50 also depends on the type of the refrigerant, the intended use of the refrigeration cycle apparatus 100, etc.

According to the present embodiment, the angle θ between the first angular position (0 degrees) where the first vane 32 is disposed and the second angular position where the second vane 33 is disposed is set to 270 degrees or more in the rotation direction of the shaft 4. The angle θ should be set appropriately depending on the flow rate of the refrigerant to be compressed in the first compression chamber 25 and the flow rate of the refrigerant to be compressed in the second compression chamber 26.

However, the amount of the refrigerant flowing from the first compression chamber 25 back into the first suction port 19 increases as the angle θ decreases. An appropriate range of angles θ is, for example, 270≦θ≦350.

Of course, the optimum angle θ varies depending on the intended use of the refrigeration cycle apparatus 100. It is conceivable to set the angle θ to less than 270 degrees, as shown in FIG. 12. The amount of the refrigerant flowing from the first compression chamber 25 back into the first suction port 19 increases as the angle θ decreases. In order to prevent the refrigerant from flowing from the first compression chamber 25 back into the first suction port 19, a suction check valve can be provided also in the first suction port 19.

The above findings indicate that the suction check valve 50 prevents the refrigerant drawn into the second compression chamber 26 from flowing back outside the second compression chamber 26 through the second suction port 20 during the period defined as (i), (ii) or (iii): (i) during a period from a point of time when the second compression chamber 26 reaches a maximum volume to a point of time when the second compression chamber 26 reaches a minimum volume (almost equal to 0); (ii) during a period from the point of time when the second compression chamber 26 reaches the maximum volume to a point of time when the compressed refrigerant begins to be discharged outside the second compression chamber 26 through the second discharge port 41; and (iii) during a period from the point of time when the second compression chamber 26 reaches the maximum volume to a point of time when the point of contact between the cylinder 5 and the piston 8 passes the second suction port 20 as the shaft 4 rotates. When the angle θ is relatively large, the suction check valve 50 prevents the backflow during the period (i). When the angle θ is relatively small, the suction check valve 50 prevents the backflow during the period (ii) or (iii).

The suction check valve 50 contributes significantly to an increase in compressor efficiency. However, from the viewpoint of preventing vane jumping, the suction check valve 50 has an adverse effect. First, the case where a suction check valve is not provided is considered with reference to FIG. 15. In the case where a suction check valve is not provided, one side of the front surface of the vane 535 is exposed to a discharge pressure (high pressure) in the compression chamber 526 at the moment when the piston 523 pushes the vane 535 into the vane groove in the state shown in FIG. 15. The other side of the front surface of the vane 535 is exposed to a suction pressure (intermediate pressure) in the suction port 527a. Therefore, if it is assumed that the rolling piston compressor 501 is a high-pressure shell type compressor, a certain pressing force is always applied to the vane 535 based on the difference between the pressure applied to the front surface and the pressure applied to the rear surface.

Next, the case where a suction check valve is provided in the second suction port but the second vane is not coupled to the piston is considered with reference to FIG. 17. One side of the front surface of the second vane 552 is exposed to a discharge pressure (high pressure) in the first compression chamber 554 at the moment when the piston 558 pushes the second vane 552 in the state shown in FIG. 17. The other side of the front surface of the second vane 552 is exposed to a pressure in the second compression chamber 556. In the state shown in FIG. 17, the pressure in the second compression chamber 556 is equal or close to the discharge pressure (high pressure), although it cannot be definitely determined because it depends also on design conditions such as the angle θ. That is, in the state shown in FIG. 17, a pressing force applied to the second vane 552 based on the difference between the pressure applied to the front surface and the pressure applied to the rear surface is almost zero, and only a pressing force of the spring 553 is applied to the second vane 552. If the piston 558 passes the top dead center of the second vane 552 in this state, the second vane 552 cannot follow the movement of the piston 558 because an outward inertial force is applied to the second vane 552. As a result, vane jumping may occur.

As described above, the suction check valve 50 is closely related to the problem of vane jumping. Therefore, in the case where the suction check valve 50 is provided to prevent the backflow of the refrigerant, it is desirable to actively adopt the structures described with reference to FIG. 4A to FIG. 4F in order to prevent vane jumping. A combination of the suction check valve 50 and the structure for preventing vane jumping can provide the rotary compressor 102 with a very high compressor efficiency. FIG. 17 is a diagram for explaining the problems that may occur when the second vane is not coupled to the piston, and is not the prior art of the present invention.

Modification

FIG. 13 is a longitudinal cross-sectional view of a rotary compressor according to a modification. A rotary compressor 202 has a structure in which components such as a cylinder is added to the rotary compressor 102 shown in FIG. 2. In the present modification, the compression mechanism 3, the cylinder 5, the piston 8 and the eccentric portion 4a shown in FIG. 2 are defined as a first compression mechanism 3, a first cylinder 5, a first piston 8, and a first eccentric portion 4a, respectively. The detailed structure of the first compression mechanism 3 is as described with reference to FIG. 2 to FIG. 7.

As shown in FIG. 13 and FIG. 14, the rotary compressor 202 includes a second compression mechanism 30 in addition to the first compression mechanism 3. The second compression mechanism 30 has a second cylinder 65, an intermediate plate 66, a second piston 68, an auxiliary bearing 67, a muffler 70, a third vane 72, a third suction port 69, and a third discharge port 73. The second cylinder 65 is disposed concentrically with the first cylinder 5, and separated from the first cylinder 5 by the intermediate plate 66.

The shaft 4 has a second eccentric portion 4b projecting outwardly in a radial direction. The second piston 68 is disposed within the second cylinder 65. Within the second cylinder 65, the second piston 68 is fitted to the second eccentric portion 4b of the shaft 4. The intermediate plate 66 is disposed between the first cylinder 5 and the second cylinder 65. A vane groove 74 is formed in the second cylinder 65. A third vane 72 (blade) having a tip in contact with the outer peripheral surface of the second piston 68 is slidably fitted in the vane groove 74. The third vane 72 divides the space between the second cylinder 65 and the second piston 68 along the circumferential direction of the second piston 68. Thereby, a third compression chamber 71 is formed within the second cylinder 65. The second piston 68 and the third vane 72 may be constituted by a single component, i.e., a so-called swing piston. The third vane 72 may be coupled to the second piston 68. A third spring 76 pressing the third vane 72 toward the center of the shaft 4 is disposed behind the third vane 72.

A third suction port 69 introduces the refrigerant to be compressed in the third compression chamber 71 into the third compression chamber 71. A third suction pipe 64 is connected to the third suction port 69. The third discharge port 73 penetrates the auxiliary bearing 67 and opens into the internal space of the muffler 70. The refrigerant compressed in the third compression chamber 71 is discharged outside the third compression chamber 71, specifically, to the internal space of the muffler 70, from the third compression chamber 71 through the third discharge port 73. The refrigerant is introduced from the internal space of the muffler 70 into the internal space 13 of the closed casing 1 through the flow path 63 passing through the main bearing 6, the first cylinder 5, the intermediate plate 66, the second cylinder 65 and the auxiliary bearing 67 in the axial direction of the shaft 4. The flow path 63 may open into the internal space 13 of the closed casing 1, or into the internal space of the muffler 9.

As described above, the second compression mechanism 30 has the same structure as a compression mechanism of a typical rolling piston compressor having only one vane.

The second piston 68 and the third vane 72 may be integrated together. Alternatively, the second piston 68 and the third vane 72 may be coupled together. That is, the structures described with reference to FIG. 4A to FIG. 4F can be applied to the second piston 68 and the third vane 72. The problem of vane jumping is less likely to occur for the third vane 72. However, it can be expected that the shared use of the components between the first compression mechanism 3 and the second compression mechanism 30 can lead to a cost reduction effect.

In the rotary compressor 202, the height, inner diameter and outer diameter of the second cylinder 65 are equal to the height, inner diameter and outer diameter of the first cylinder 5, respectively. The outer diameter of the first piston 8 is equal to that of the second piston 68. Since only the third compression chamber 71 is formed within the second cylinder 65, the first compression chamber 25 has a smaller volume than the third compression chamber 71. This means that the shared use of the components between the first compression mechanism 3 and the second compression mechanism 30 can lead to a cost reduction and increased ease of assembling.

In the present modification, the first compression mechanism 3 and the second compression mechanism 30 are disposed on the upper side and the lower side of the axial direction of the shaft 4, respectively. The refrigerant compressed in the first compression mechanism 3 is introduced into the internal space of the muffler 9 through the discharge ports 40 and 41 provided in the main bearing 6. The first compression mechanism 3 has two discharge ports 40 and 41. Therefore, it is desirable to reduce the distance between the discharge ports 40 and 41 and the internal space 13 of the closed casing 1 as much as possible so as to reduce the pressure loss of the refrigerant in the discharge ports 40 and 41 as much as possible. From this viewpoint, it is preferable to dispose the first compression mechanism 3 on the upper side of the axial direction.

However, from another viewpoint, the first compression mechanism 3 may be disposed on the lower side of the axial direction. The reason for this is as follows. The nearer the motor 2 is, the higher the temperature in the closed casing 1 is. This means that the main bearing 6 has a higher temperature than the auxiliary bearing 67 and the muffler 70 during the operation of the rotary compressor 202. Therefore, when the first compression mechanism 3 is disposed on the upper side and the second compression mechanism 30 is disposed on the lower side, the refrigerant to be introduced into the second compression chamber 26 is likely to be heated. Then, the mass flow rate of the refrigerant to be compressed in the second compression chamber 26 decreases, which also reduces the injection effect. In order to obtain a higher injection effect, the second compression mechanism 30 may be disposed on the upper side and the first compression mechanism 3 having the second compression chamber 26 may be disposed on the lower side.

As shown in FIG. 13, the angular difference between the direction in which the first eccentric portion 4a projects and the direction in which the second eccentric portion 4b projects is 180 degrees in the rotation direction of the shaft 4. In other words, the phase difference between the first piston 8 and the second piston 68 is 180 degrees in the rotation direction of the shaft 4. In still other words, the timing of the top dead center of the first piston 8 is shifted from the timing of the top dead center of the second piston 68 by 180 degrees. With such a configuration, the vibration generated by the rotation of the first piston 8 can be cancelled by the rotation of the second piston 68. Furthermore, the compression process in the first compression chamber 25 and the compression process in the third compression chamber 71 are performed almost alternately, and the discharge process in the first compression chamber 25 and the discharge process in the third compression chamber 71 are performed almost alternately. Therefore, the torque variation of the shaft 4 can be reduced, which is advantageous in reducing the motor loss and mechanical loss. The vibration and noise of the rotary compressor 202 also can be reduced. The “timing of the top dead center of the piston” means the timing when the vane is pushed all the way into the vane groove by the piston.

When the rotary compressor 202 is used in the refrigeration cycle apparatus 100 shown in FIG. 1, the following configuration can be adopted. The refrigeration cycle apparatus 100 has the suction flow path 10d for introducing the refrigerant that has flowed out of the first heat exchanger 104 or the second heat exchanger 112 as an evaporator into the first suction port 19 of the rotary compressor 202. As shown in FIG. 13, the suction flow path 10d includes a branch portion 14 extending toward the first suction port 19 and a branch portion 64 extending toward the third suction port 69 so that the refrigerant that has flowed out of the first heat exchanger 104 or the second heat exchanger 112 is introduced into both the first suction port 19 and the third suction port 69 of the rotary compressor 202. In the present embodiment, the first suction pipe 14 constitutes the branch portion 14 and the third suction pipe 64 constitutes the branch portion 64. With such a configuration, the refrigerant can be introduced smoothly into the first compression chamber 25 and the third compression chamber 71. The suction flow path 10d may branch in the closed casing 1.

INDUSTRIAL APPLICABILITY

The refrigeration cycle apparatus of the present invention can be used for water heaters, hot water heating apparatuses, air conditioners, etc.

Number	Name	Date	Kind
3568712	Rinehart	Mar 1971	A
3797975	Keller	Mar 1974	A
4459090	Maruyama et al.	Jul 1984	A
5069607	Da Costa	Dec 1991	A
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7048525	Brick et al.	May 2006	B2
7316120	Aoki et al.	Jan 2008	B2
7736134	Schneider	Jun 2010	B2
20040005236	Lee	Jan 2004	A1
20060210418	Bae et al.	Sep 2006	A1
20070280843	Bae et al.	Dec 2007	A1
20080031756	Hwang et al.	Feb 2008	A1
20090241581	Hasegawa et al.	Oct 2009	A1
20100119396	Guo	May 2010	A1

Number	Date	Country
1904369	Jan 2007	CN
101560977	Oct 2009	CN
55-177090	Dec 1980	JP
59-066663	Apr 1984	JP
62-056781	Apr 1987	JP
3-053532	Aug 1991	JP
10-299680	Nov 1998	JP
2000-120572	Apr 2000	JP
2006-112753	Apr 2006	JP
2006-152950	Jun 2006	JP

Rotary compressor and refrigeration cycle apparatus

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