The present invention relates to a control valve of a compressor and, particularly, to a control valve for use in a clutch type variable displacement compressor.
Generally, a variable displacement compressor (hereinafter referred to merely as “compressor”), which can variably control its displacement, is known as a compressor for use in a vehicle air-conditioner. Such a compressor includes a cylinder block defining therein cylinder bores, a front housing joined to the front end of the cylinder block, and a rear housing defining therein a suction chamber and a discharge chamber. A control-pressure chamber (or crank chamber) is defined in the front housing, in which a drive shaft is rotatably supported. The drive shaft is connected to an external drive source such as an engine or the like such that the drive shaft is driven thereby to rotate. In a clutch type compressor, a clutch mechanism is engaged to transmit the drive force from the external drive source to the compressor or disengaged to shut off the transmission.
A swash plate is accommodated in the control-pressure chamber. The swash plate is inclinable relative to the drive shaft while being rotated synchronously with the drive shaft, thereby causing a piston in each cylinder bore to reciprocate for a distance of its piston stroke according to the inclination of the swash plate. The piston stroke depends on the pressure difference between the pressure in the control-pressure chamber and a suction pressure. As the pressure in the control-pressure chamber is raised, the swash plate is inclined toward its vertical position with respect to the axis of the drive shaft (or the inclination angle of the swash plate is decreased). As the pressure in the control-pressure chamber is lowered, on the other hand, the swash plate is inclined approaching the axis of the drive shaft or moving away from its vertical position (or the inclination angle of the swash plate is increased). When the pressure in the control-pressure chamber is high and the inclination angle of the swash plate is small, the piston reciprocates for a short distance of stroke thereby to provide a small displacement of the compressor. On the other hand, when the pressure in the control-pressure chamber is low and the inclination angle of the swash plate is large, the piston reciprocates for a long distance of stroke thereby to provide a large displacement of the compressor.
The displacement of the compressor is controlled by a control valve. Some control valves has a valve body whose movement is controlled according to the urging force of a pressure-sensing member of a pressure-sensing mechanism and the suction pressure thereby to open or close a refrigerant passage connecting the discharge-pressure region to the control-pressure chamber, thus controlling the pressure in the control-pressure chamber. For example, when cooling load is small and the suction pressure is low, the refrigerant passage is opened to increase the pressure in the control-pressure chamber, with the result that the displacement is decreased. Such a control valve is disclosed in Japanese Paten Application Publication No. 2002-48058.
In a clutch type compressor having the control valve, the drive force from the external drive source is shut off by the clutch mechanism if cooling is not needed. If the compressor is at a stop for a long period of time, the pressure inside the compressor is equalized and a refrigerating circuit including the compressor is gradually cooled by the ambient air. Since the compressor is easy to cool, a refrigerant in the refrigerating circuit tends to flow into the compressor. More specifically, when the refrigerating circuit is cooled and the temperature thereof falls below the temperature at the saturated vapor pressure of the refrigerant, the refrigerant converts into liquid state. This refrigerant of liquid (hereinafter referred to as “liquid refrigerant”) tends to be accumulated in the compressor.
In the prior art, when the compressor having the liquid refrigerant accumulated therein is started from its stop state by the drive force transmitted through the clutch mechanism, the compressor attempts to obtain the displacement according to the current cooling load, but the pressure in the control-pressure chamber cannot be lowered immediately after a start-up of the compressor. This is because liquid refrigerant exists in the control-pressure chamber and, therefore, the pressure of refrigerant in the control-pressure chamber will not be lowered in dependence on the saturated vapor pressure of the refrigerant. In this state of the compressor, the pressure in the control-pressure chamber is not lowered at least unless the liquid refrigerant accumulated in the control-pressure chamber is vaporized or discharged out of the compressor to the refrigerating circuit. Thus, since the liquid refrigerant is accumulated in the control-pressure chamber while the compressor is at a stop, the pressure in the control-pressure chamber is not lowered immediately after a start-up of the compressor and, therefore, the inclination angle of the swash plate is not controlled according to the required displacement. This phenomenon is called “delay of cooling” (or “delay of return”) and deteriorates the start-up response of the compressor.
The present invention is directed to a control valve for a clutch type variable displacement compressor which improves its start-up response.
According to the present invention, a control valve for a clutch type variable displacement compressor having a control-pressure chamber, a discharge-pressure region and a suction-pressure region includes a first port in communication with the discharge-pressure region, a second port in communication with the control-pressure chamber, a third port in communication with the suction-pressure region, a refrigerant-supply passage for connecting the first port to the second port, a valve body operable to open and close the refrigerant-supply passage, a pressure-sensing mechanism operable to control the valve body according to a pressure in the suction-pressure region and including a pressure-sensing member, a rod operable to move the valve body for opening and closing the refrigerant-supply passage, and a liquid-discharge passage for connecting the second port to the third port. Opening and closing the liquid-discharge passage are controlled by movement of the pressure-sensing member. The pressure-sensing member is placed such that the liquid-discharge passage is opened while pressure equalization inside the compressor at a stop of the compressor is maintained in starting the compressor from its stop state. The pressure-sensing member is moved in a direction which causes the liquid-discharge passage to be closed when a pressure in the suction-pressure region is lowered and reaches a predetermined pressure as the compressor is started.
Other aspects and advantages of the invention will become apparent from the following description, taken in conjunction with the accompanying drawings, illustrating by way of example the principles of the invention.
The features of the present invention that are believed to be novel are set forth with particularity in the appended claims. The invention together with objects and advantages thereof, may best be understood by reference to the following description of the presently preferred embodiments together with the accompanying drawings in which:
The following will describe a clutch type variable displacement compressor (hereinafter referred to merely as “compressor”) according to a first preferred embodiment of the present invention with reference to
The front housing 13 and the cylinder block 12 cooperate to define a control-pressure chamber (or a crank chamber) 16 through which a drive shaft 17 extends. The drive shaft 17 is rotatably supported by a radial bearing 18 provided at the front of the front housing 13 and a radial bearing 19 provided at the center of the cylinder block 12. A shaft seal mechanism 20 is provided on the drive shaft 17 forward of the radial bearing 18 in slide contact with the outer circumferential surface of the drive shaft 17. The shaft seal mechanism 20 has a lip seal which functions to prevent a refrigerant in the control-pressure chamber 16 from leaking from between the front housing 13 and the drive shaft 17.
The drive shaft 17 is connected at its front end to an external drive source (not shown) through a clutch mechanism (not shown). The clutch mechanism is engaged to transmit the drive force from the external drive source to the drive shaft 17 or disengaged to shut off the transmission. A lug plate 21 is secured to the drive shaft 17 in the control-pressure chamber 16 for rotation therewith. A swash plate 23 of a displacement-changing mechanism 22 is provided behind the lug plate 21 and supported by the drive shaft 17 so as to be slidable in the axial direction of the drive shaft 17 and inclinable relative to the axis of the drive shaft 17. A hinge mechanism 24 is interposed between the swash plate 23 and the lug plate 21 so that the swash plate 23 and the lug plate 21 are connected therethrough. The hinge mechanism 24 allows the swash plate 23 and lug plate 21 to rotate synchronously with and to be inclined relative to the drive shaft 17.
A coil spring 25 is disposed on the drive shaft 17 between the lug plate 21 and the swash plate 23. A tubular body 26 is slidably disposed on the drive shaft 17 and urged rearward by the coil spring 25. The tubular body 26 urges the swash plate 23 rearward or in the direction which causes the inclination angle of the swash plate 23 to be decreased. It is noted that the inclination angle of the swash plate 23 refer to an angle made between an imaginary plane perpendicular to the axis of the drive shaft 17 and the flat surface of the swash plate 23. The swash plate 23 has a stopper 23a projecting from the front thereof for determining the maximum inclination of the swash plate 23 by contact with the lug plate 21 as shown in
A single-headed piston 29 is reciprocatably disposed in each of the cylinder bores 12a of the cylinder block 12. The piston 29 is engaged at its neck with the outer periphery of the swash plate 23 through a pair of shoes 30. When the swash plate 23 is driven to rotate by the drive shaft 17, each piston 29 reciprocates through the shoes 30. As shown in
The valve plate 32 and each piston 29 cooperate to define the compression chamber 31 in the respective cylinder bore 12a. The valve plate 32 has the suction port 36 which is in communication with the suction chamber 38 and a discharge port 37 which is in communication with the discharge chamber 39. The valve-forming plate 33 is a plate which forms a suction valve (not shown) interposed between each compression chamber 31 and the suction chamber 38, while the valve-forming plate 34 is a plate which forms a discharge valve 34a or a reed valve interposed between each discharge port 37 and the discharge chamber 39. The retainer 35 functions to limit the maximum opening of the discharge valve 34a.
As the piston 29 moves from its top dead center toward its bottom dead center, the refrigerant in the suction chamber 38 is drawn into the compression chamber 31 through the suction port 36 and the suction valve. As the piston 29 moves from its bottom dead center toward its top dead center, the refrigerant drawn in the compression chamber 31 is compressed to a predetermined pressure and discharged into the discharge chamber 39 through the discharge port 37 and the discharge valve 34a. The inclination angle of the swash plate 23 is determined depending on the balance among the rotation moment developed by the centrifugal force of the swash plate 23, the moment of inertia caused by the inertial force of the piston 29, the moment caused by the pressure of the refrigerant and the like. The moment caused by the pressure of the refrigerant is a moment which is determined by the relation between the pressure in the compression chamber 31 and the pressure in the control-pressure chamber 16 acting on the back of the piston 29 and this moment is applied in the direction which causes the swash plate 23 to be increased or decreased depending on the variation of the pressure in the control-pressure chamber 16.
The following will describe an external refrigerant circuit 42 in which the above-described compressor 10 is connected. In this preferred embodiment, the compressor 10 and the external refrigerant circuit 42 comprise a refrigerating circuit through which the refrigerant circulates. The suction chamber 38 is connected to the external refrigerant circuit 42 through an inlet 40 formed in the rear housing 14. Thus, the refrigerant is supplied from the external refrigerant circuit 42 through the inlet 40 into the suction chamber 38. In this preferred embodiment, the suction chamber 38 and the inlet 40 comprise a suction-pressure region of the compressor 10. The discharge chamber 39 is connected to the external refrigerant circuit 42 through an outlet 41 formed in the rear housing 14. Thus, the refrigerant in the discharge chamber 39 is discharged out of the compressor 10 into the external refrigerant circuit 42 through the outlet 41. In this preferred embodiment, the discharge chamber 39 and the outlet 41 comprise a discharge-pressure region of the compressor 10. As shown schematically in
The compressor 10 has a control valve 50 which is operable to adjust the pressure in the control-pressure chamber 16 thereby to appropriately change the moment due to the pressure of the refrigerant, so that the inclination angle of the swash plate 23 is set between the minimum and the maximum inclination angles.
As shown in
As shown in
The valve housing 51 has a third port 57 which is in communication with the pressure-sensing chamber 52, a second port 58 which is in communication with the communication chamber 53 and a first port 59 which is in communication with the valve chamber 54. As shown in
The refrigerant-supply passage is provided in the valve housing 51 passing through the valve chamber 54, the valve hole 56 and the communication chamber 53 thereby connecting the first port 59 to the second port 58. In other words, the refrigerant-supply passage includes the valve chamber 54, the valve hole 56 and the communication chamber 53. A spherical valve body 63 and a coil spring 64 as an urging member are disposed in the valve chamber 54. The valve body 63 has a diameter greater than that of the valve hole 56 for closing the valve hole 56. The valve body 63 is constantly urged by the coil spring 64 in the direction that causes the valve hole 56 to be closed.
The pressure-sensing mechanism 66 is disposed in the pressure-sensing chamber 52. The pressure-sensing mechanism 66 includes a bellows 67 as a pressure-sensing member which divides the pressure-sensing chamber 52 into a variable-pressure chamber 52a and a constant-pressure chamber 52b. The bellows 67 is fixed at its fixed end to an end wall 69 which closes the lower end of the valve housing 51. The constant-pressure chamber 52b inside the bellows 67 is hermitically closed and maintained at a predetermined constant pressure. The variable-pressure chamber 52a is located around the constant-pressure chamber 52b, and the pressure in the variable-pressure chamber 52a varies according to the variation of the pressure in the suction chamber 38. Thus, when the pressure in the variable-pressure chamber 52a is lower than that in the constant-pressure chamber 52b, the bellows 67 expands. On the other hand, when the pressure in the variable-pressure chamber 52a is higher than that in the constant-pressure chamber 52b, the bellows 67 contracts. In other words, the pressure difference between the constant-pressure chamber 52b and the variable-pressure chamber 52a produces a force causing the bellows 67 to move, namely, expand or contract.
A movable member 68 is fixed to the movable end of the bellows 67. The movable member 68 is also fixed to the lower end of the rod 70. The rod 70 has a diameter corresponding to that of the shaft hole 55a. The length of the rod 70 is set such that when the bellows 67 expands to its maximum length, the rod 70 moves the valve body 63 away from the valve hole 56 against the urging force of the coil spring 64. The rod 70 has a recess 70a formed in the lateral surface thereof and extending in the axial direction thereof. The recess 70a is formed in the rod 70 such that when the bellows 67 contracts substantially to its minimum length the pressure-sensing chamber 52 and the communication chamber 53 are made in fluid communication through the recess 70a, as shown in
The following will describe the operation of the control valve 50. In the case where the compressor 10 remains at a stop for a long period of time, the pressure inside the compressor 10 is equalized and the refrigerating circuit including the compressor 10 is gradually cooled by the ambient air. Since the compressor 10 is relatively easy to cool, the refrigerant in the refrigerating circuit tends to flow into the compressor 10. More specifically, the refrigerant converts into liquid state if the refrigerating circuit is cooled so that the temperature thereof falls below the temperature of the saturated vapor pressure of the refrigerant, and the liquid refrigerant tends to be accumulated in the compressor 10. In the case where the compressor 10 remains at a stop for a long period of time, the equalized pressure in the refrigerating circuit is much higher than the pressure that is present in the suction-pressure region during the operation of the compressor 10. In other words, the pressure in the variable-pressure chamber 52a is much higher than that constant-pressure chamber 52b in the in the pressure-sensing chamber 52. Thus, as shown in
Subsequently, if cooling is required, the clutch mechanism is engaged to transmit the drive force from the external drive source to the compressor 10 for starting the compressor 10 which is then at a stop. At the beginning of the start-up, the swash plate 23 of the compressor 10 is inclined at its minimum inclination angle, that is, the compressor 10 operates at its minimum displacement. During this minimum-displacement operation of the compressor 10 at the beginning of the start-up, each of the pistons 29 reciprocates in the respective cylinder bore 12a for its minimum distance of stroke. When the liquid-discharge passage is opened, the reciprocation of the pistons 29 causes the refrigerant to flow from the control-pressure chamber 16 through the suction chamber 38 into the compression chamber 31. Since the liquid-discharge passage is then opened, the liquid refrigerant in the control-pressure chamber 16 is fully discharged into the suction chamber 38 flowing through the passage 61, the control valve 50 (the second port 58, the communication chamber 53, the recess 70a, the variable-pressure chamber 52a and the third port 57) and the passage 60 as the pistons 29 reciprocate in the cylinder bores 12a.
Since the liquid refrigerant in the control-pressure chamber 16 is thus fully discharged into the suction chamber 38, the pressure in the control-pressure chamber 16 can be lowered below the saturated vapor pressure of the refrigerant. As the pressure in the control-pressure chamber 16 is lowered, the inclination angle of the swash plate 23 is increased, thus increasing the displacement of the compressor 10. With an increase in the displacement of the compressor 10, the pressure in the variable-pressure chamber 52a in the control valve 50 is lowered further and the bellows 67 expands, accordingly. For example, during the maximum displacement operation of the compressor 10 when the cooling load is high, the bellows 67 expands to such a degree that the rod 70 approaches close to but is yet to be in contact with the valve body 63 as shown in
For improving the operating efficiency of the compressor 10, the communication between the communication chamber 53 and the variable-pressure chamber 52a should preferably be closed at the moment when the liquid refrigerant in the control-pressure chamber 16 is just fully discharged. The pressure in the suction chamber 38 is gradually lowered from the saturated vapor pressure level when the liquid refrigerant is discharged out of the compressor 10 and the inclination angle of the swash plate 23 is increased. Therefore, it is preferable that the pressure which is slightly below the saturated vapor pressure should be set as a predetermined pressure at which the bellows 67 expands to move the rod 70 so that the liquid-discharge passage is closed. However, since the saturated vapor pressure depends on temperature, the above predetermined pressure cannot be determined readily. In this preferred embodiment, if chlorofluorocarbon (HFC-134a) is used as the refrigerant, the predetermined pressure is set at 0.4 to 0.45 MPa on the basis of a saturated vapor pressure of 0.49 MPa at a temperature of 15° C. Since the suction pressure ranges from 0.2 to 0.4 MPa while the compressor 10 is operating at its maximum or medium displacement, the liquid-discharge passage may be closed after the liquid refrigerant is fully discharged and the displacement of the compressor 10 is increased.
When the cooling load is decreased, the compressor 10 then operates such that its displacement is decreased from the maximum at the maximum displacement operation. More specifically, the compressor 10 attempts to maintain its maximum-displacement operation in spite of the decreased cooling load, but the pressure in the suction-pressure region is lowered further due to the decreased cooling load. Accordingly, the pressure in the variable-pressure chamber 52a is lowered, so that the bellows 67 expands further than that at the maximum displacement operation of the compressor 10 thereby to cause the rod 70 to press the valve body 63 against the coil spring 64 and the valve hole 56 to be opened, as shown in
With the valve hole 56 opened, a part of the high-pressure refrigerant in the discharge chamber 39 is introduced into the control-pressure chamber 16 through the passage 62, the control valve 50 (the first port 59, the valve chamber 54, the valve hole 56, the communication chamber 53 and the second port 58) and the passage 61. Thus, the inclination angle of the swash plate 23 is decreased and the compressor 10 performs its variable-displacement operation in response to the varying cooling load. During the variable-displacement operation of the compressor 10, the liquid-discharge passage is kept closed. It is noted that opening and closing the valve hole 56 by the valve body 63 depend on the balance between the urging force of the coil spring 64 and the urging force of the rod 70 developed by the pressure-sensing mechanism 66.
According to the control valve 50 of the above-described preferred embodiment, the following advantageous effects are achieved.
(1) The refrigerant in the control-pressure chamber 16 is discharged at a start-up of the compressor 10, so that the pressure in the control-pressure chamber 16 is lowered and the swash plate 23 is controlled such that the displacement of the compressor 10 is increased. The liquid-discharge passage is closed when the refrigerant pressure in the suction-pressure region is lowered and reaches the aforementioned predetermined pressure as the compressor 10 is started. Therefore, the liquid refrigerant accumulated in the control-pressure chamber 16 is fully discharged into the suction-pressure region after the start-up of the compressor 10, thus permitting the pressure in the control-pressure chamber 16 to be lowered faster than in the conventional compressor.
(2) The pressure equalization inside the compressor 10 is set by the saturated vapor pressure of the refrigerant with respect to the temperature of the ambient air. The position of the rod 70 is controlled by maintaining the pressure equalization at the start-up of the compressor 10 and canceling the pressure equalization afterward. According to the position of the recess 70a of the rod 70, opening and closing the liquid-discharge passage is controlled.
(3) The wider liquid-discharge passage requires less time for fully discharging the liquid refrigerant from the control-pressure chamber 16 into the suction-pressure region. Thus, return characteristics of the compressor 10 is improved. However, if the liquid-discharge passage is opened to connect the control-pressure chamber 16 to the suction-pressure region after return of or the start-up of the compressor 10, a lot of the refrigerant may flow from the control-pressure chamber 16 into the suction-pressure region. The flow of the refrigerant in the compressor 10 is needed for lubricating the sliding elements in the compressor 10 but it does not contribute to cooling by the refrigerant circulation in the refrigerating circuit. Thus, it deteriorates cooling performance. The cooling performance is prevented from being deteriorated by closing the liquid-discharge passage after the return of the compressor 10.
The following will describe a control valve 80 according to a second preferred embodiment of the present invention with reference to
The rod 87 is reciprocatably slidably disposed in the valve housing 81. The rod 87 has a large-diameter portion 87a located in the communication chamber 84 and the valve chamber 83, a small-diameter portion 87b located in the pressure-sensing chamber 82 and a through hole 88 extending axially through the center of the rod 87. The large-diameter portion 87a has a diameter corresponding to that of the shaft hole 86, and the small-diameter portion 87b has a diameter smaller than that of the valve hole 85. The rod 87 has an end surface 87c provided at the step between the small-diameter portion 87b and the large-diameter portion 87a. The end surface 87c functions as a valve body which is contactable with the first partition 81a, thus providing and shutting off the fluid communication between the pressure-sensing chamber 82 and the valve chamber 83. In this preferred embodiment, the valve chamber 83, the valve hole 85 and the pressure-sensing chamber 82 correspond to the refrigerant-supply passage of the control valve 80, and the end surface 87c of the rod 87 corresponds to a valve body for opening and closing the refrigerant-supply passage. The through hole 88 of the rod 87 provides fluid communication between the pressure-sensing chamber 82 and the communication chamber 84. The rod 87 is urged toward the pressure-sensing chamber 82 by a coil spring 89 disposed in the communication chamber 84.
The communication chamber 84 is located at the upper end of the large-diameter portion 87a, and the valve housing 81 has at its upper end a third port 90 which is in communication with the communication chamber 84. The third port 90 is also in communication with the suction chamber 38 through a passage 93 formed in the rear housing 14. The valve chamber 83 is formed around the large-diameter portion 87a, and the valve housing 81 has a first port 91 formed through its lateral wall which is in communication with the valve chamber 83. The first port 91 is also in communication with the discharge chamber 39 through a passage 94 formed in the rear housing 14. The pressure-sensing chamber 82 is located at the lower end of the small-diameter portion 87b, and the valve housing 81 has at its lower end a second port 92 which is in communication with a variable-pressure chamber 82a. The second port 92 is also in communication with the control-pressure chamber 16 through a passage 95 formed in the rear housing 14, the valve-forming plate 33, the valve plate 32, the valve-forming plate 34 and the retainer 35.
The pressure-sensing mechanism 96 is disposed in the pressure-sensing chamber 82. The pressure-sensing mechanism 96 has a bellows 97 as a pressure-sensing member which divides the pressure-sensing chamber 82 into the variable-pressure chamber 82a and a constant-pressure chamber 82b. The bellows 97 is fixed at its fixed lower end to an end wall 98 which closes the lower end of the valve housing 81. The constant-pressure chamber 82b inside the bellows 97 is hermitically closed and maintained at a predetermined constant pressure. The variable-pressure chamber 82a is located around the constant-pressure chamber 82b, and the pressure in the variable-pressure chamber 82a varies with the pressure in the suction chamber 38. Thus, when the pressure in the variable-pressure chamber 82a is lower than that in the constant-pressure chamber 82b, the bellows 97 expands. On the other hand, when the pressure in the variable-pressure chamber 82a is higher than that in the constant-pressure chamber 82b, the bellows 97 contracts. In other words, the pressure difference between the constant-pressure chamber 82b and the variable-pressure chamber 82a creates a force which causes the bellows 97 to expand or contract.
A movable member 99 is fixed to the movable upper end of the bellows 97, and an annular valve member 100 is fixed to the movable member 99 for selectively providing and shutting off the fluid communication between the pressure-sensing chamber 82 and the through hole 88. The valve member 100 has a tapered surface 100a which is tapered toward the bellows 97. The bellows 97 expands such that the small-diameter portion 87b of the rod 87 comes into contact at the outer periphery of its end with the tapered surface 100a, thereby shutting off the communication between the communication chamber 84 and the pressure-sensing chamber 82. When the bellows 97 contracts, on the other hand, the valve member 100 moves away from the small-diameter portion 87b of the rod 87, providing the communication between the pressure-sensing chamber 82 and the communication chamber 84 via the through hole 88. In this preferred embodiment, the variable-pressure chamber 82a, the through hole 88 and the communication chamber 84 correspond to the liquid-discharge passage of the control valve 80.
The following will describe the operation of the control valve 80 of this preferred embodiment. When the compressor 10 remains at a stop for a long period of time, the liquid refrigerant is accumulated in the compressor 10 and the pressure in the refrigerating circuit is substantially equalized. The equalized pressure in the refrigerating circuit is much higher than the pressure in the suction-pressure region of the compressor 10 during its operation. In other words, the pressure in the variable-pressure chamber 82a is much higher than that in the constant-pressure chamber 82b of the pressure-sensing chamber 82. Thus, as shown in
Subsequently, if cooling is required, the clutch mechanism is engaged to transmit the drive force from the external drive source to the compressor for starting the compressor which is then at a stop. During the minimum-displacement operation of the compressor at the beginning of the start-up, each of the pistons 29 reciprocates in its cylinder bore 12a for its minimum distance of stroke. When the liquid-discharge passage is opened, the reciprocation of the pistons 29 causes the refrigerant in the control-pressure chamber 16 to flow therefrom through the suction chamber 38 into the compression chamber 31. Since the liquid-discharge passage is then opened, the liquid refrigerant in the control-pressure chamber 16 is fully discharged by the reciprocation of the pistons 29 into the suction chamber 38 through the passage 95, the control valve 80 (the second port 92, the variable-pressure chamber 82a, the through hole 88, the communication chamber 84 and the third port 90) and the passage 93.
Since the liquid refrigerant in the control-pressure chamber 16 is fully discharged into the suction chamber 38, the pressure in the control-pressure chamber 16 can be lowered below the saturated vapor pressure of the refrigerant. As the pressure in the control-pressure chamber 16 is thus lowered, the inclination angle of the swash plate 23 is increased, thus increasing the displacement of the compressor. As the displacement of the compressor is increased, the pressure in the variable-pressure chamber 82a in the control valve 80 is lowered further, so that the bellows 97 expands. For example, during the maximum-displacement operation of the compressor when the cooling load is high, the bellows 97 expands to such a degree that the valve member 100 comes into contact with the rod 87 as shown in
When the cooling load is decreased, the compressor then operates such that its displacement is decreased from the maximum at the maximum-displacement operation of the compressor. However, the compressor attempts to maintain its maximum displacement operation in spite of the reduced cooling load but the pressure in the suction-pressure region is lowered further due to the reduced cooling load. Accordingly the pressure in the variable-pressure chamber 82a is lowered further. Thus, the bellows 97 expands further than at the maximum displacement operation of the compressor, causing the valve member 100 to press the rod 70 against the coil spring 89 and the valve hole 85 to be opened, as shown in
With the valve hole 85 thus opened, a part of the high-pressure refrigerant in the discharge chamber 39 is introduced into the control-pressure chamber 16 through the passage 94, the control valve 80 (the first port 91, the valve chamber 83, the valve hole 85, the variable-pressure chamber 82a and the second port 92) and the passage 95. Thus, the inclination angle of the swash plate 23 is decreased and the compressor performs its variable-displacement operation according to the cooling load. During the variable-displacement operation of the compressor, the liquid-discharge passage is kept closed. It is noted that opening and closing the valve hole 85 by the rod 87 depend on the balance between the urging force of the coil spring 89 and the urging force of the valve member 100 created by the pressure-sensing mechanism 96.
According to the control valve 80 of this preferred embodiment, substantially the same advantageous effects as in the first preferred embodiment are achieved. Any liquid refrigerant accumulated in the control-pressure chamber 16 is fully discharged into the suction-pressure region during the start-up operation of the compressor 10, thereby lowering the pressure in the control-pressure chamber 16 faster than in the conventional compressor. Although the pressure-sensing chamber 82 which is in communication with the second port 92 and the communication chamber 84 which is in communication with the third port 90 are not located adjacent to each other in the control valve 80, the through hole 88 extending through the rod 87 forms the liquid-discharge passage providing fluid communication between the above two chambers 82, 84. Thus, the degree of freedom of designing the control valve 80 is improved. The diameter of the through hole 88 is set relatively large so that the flow rate of the liquid refrigerant passing from the control-pressure chamber 16 through the through hole 88 can be increased. Thus, the liquid refrigerant is immediately discharged fully from the control-pressure chamber 16 during the start-up operation of the compressor. The control valve 80 is more advantageous than the control valve 50 of the first preferred embodiment in that the through hole 88 allows a greater flow rate of the liquid refrigerant.
The present invention is not limited to the embodiments described above but may be modified into an alternative embodiment as exemplified below. In the first and second preferred embodiments, the liquid-discharge passage is closed during the maximum-displacement operation of the compressor. In the alternative embodiment, the liquid-discharge passage may be opened during the operation of the compressor other than the variable-displacement operation of the compressor.
Therefore, the present examples and embodiments are to be considered as illustrative and not restrictive, and the invention is not to be limited to the details given herein but may be modified within the scope of the appended claims.
Number | Date | Country | Kind |
---|---|---|---|
2005-266147 | Sep 2005 | JP | national |