The present invention relates to a capacity control valve for variably controlling the capacity or pressure of a working fluid; and particularly relates to a capacity control valve for controlling, in accordance with the pressure load, the discharge rate of a variable capacity compressor or the like used in the air-conditioning system of a motor vehicle or the like.
A variable capacity swash plate compressor used in the air-conditioning system of a motor vehicle or the like is provided with a rotating shaft rotatably driven by the rotational force of the engine, a swash plate linked to the rotating shaft so that the angle of inclination can be varied, a compression piston linked to the swash plate, and the like. In the compressor, the stroke of the piston is varied by varying the angle of inclination of the swash plate to control the discharge rate of the coolant gas.
The angle of inclination of the swash plate can be continuously varied by appropriately controlling the pressure inside the control chamber and adjusting the state of balance of the pressure acting on both surfaces of the piston. This is achieved using a capacity control valve opened and closed by electromagnetic force while applying the suction pressure of the suction chamber for drawing in the coolant gas, the discharge pressure of the discharge chamber for discharging the coolant gas pressurized by the piston, and the control chamber pressure of the control chamber (crank chamber) for accommodating the swash plate.
Such capacity control valves are known to be provided, as shown in
In the capacity control valve 70, in cases in which the control chamber pressure must be changed during capacity control even though a crank structure is not provided in the variable capacity compressor, the discharge chamber and the control chamber can be made to communicate with each other, and the pressure (control chamber pressure) Pc in the control chamber can be adjusted. An arrangement is also possible in which the third valve part (valve-opening linkage) 79 is disengaged from the valve seat body (engaging part) 80 to open the suction-side passages and to provide communication between the suction chamber and the control chamber in cases in which the control chamber pressure Pc increases while the variable capacity compressor is in a stopped state.
Liquid refrigerant (the coolant gas cooled and liquefied during the period of idleness) accumulates in the control chamber (crank chamber) in cases such as those in which the variable capacity swash plate compressor is stopped and then restarted after a long period of idleness. Therefore, the coolant gas cannot be compressed and the discharge rate cannot be maintained at the set level as long as the liquid refrigerant is not discharged.
The liquid refrigerant of the control chamber (crank chamber) must be discharged as quickly as possible immediately after startup to perform the desired capacity control.
When the solenoid S is first turned off and the variable capacity compressor is left in a stopped state for a long time while the second valve part 75 is blocking the communication passages (suction-side passages) 71, 72 in the capacity control valve 70 of Prior Art 1, a state arises in which the liquid refrigerant accumulates in the control chamber (crank chamber) of the variable capacity compressor. In cases in which the variable capacity compressor is stopped for a long period of time, the interior of the variable capacity compressor achieves a uniform pressure, and the control chamber pressure Pc rises substantially above the control chamber pressure Pc and the suction pressure Ps during operation of the variable capacity compressor.
When the solenoid S is turned on and the valve body 81 is started up in this state, the first valve part 76 moves in the closing direction at the same time as the second valve part 75 moves in the opening direction, and the liquid refrigerant in the control chamber of the variable capacity compressor is discharged. The control chamber pressure Pc then constricts the pressure-sensitive body 78, and the third valve part 79 is disengaged from the valve seat body 80 and opened. The state at this time is such that the second valve part 75 opens to open the communication passages (suction-side passages) 72, 71, and the liquid refrigerant inside the control chamber is therefore discharged to the suction chamber of the variable capacity compressor through the communication passages (suction-side passages) 74, 72, 71. When the control chamber pressure Pc reaches or decreases below a preset level, the pressure-sensitive body 78 elastically recovers and elongates, the valve seat body 80 engages with the third valve part 79 and closes, and the communication passages (suction-side passages) 74, 72, 71 are blocked.
However, in Prior Art 1, the structure is such that the pressure-sensitive body 78 is constricted and the third valve part 79 is disengaged from the valve seat body 80 and opened. Problems therefore arise in that the length of the pressure-sensitive body 78 must be increased and other actions taken to increase the opening-valve stroke, and increasing the opening-valve stroke is difficult to accomplish. Specifically, although the capacity control valve of Prior Art 1 can discharge the liquid refrigerant faster than a conventional capacity control valve not configured to be able to open the third valve part 79 (a capacity control valve for discharging the coolant via only a fixed orifice that provides direct communication between the control chamber and the suction chamber), there are limits to the discharge performance.
In view of this, a device provided with a supplementary communication passage 85 on the lateral surface of the third valve part 79 has been proposed by the present inventors (hereinafter referred to as “Prior Art 2”; for example, refer to Patent Document 2), as shown in
The device of Prior Art 2 has the ability to more quickly discharge the liquid refrigerant and more efficiently discharge pressure during maximum capacity, but problems arise in that flow from the control chamber (crank chamber) to the suction chamber is produced during operation because of a state in which the control chamber (crank chamber) and suction chamber are in constant communication with each other, and the control speed of the swash plate is adversely affected during control of the variable capacity compressor.
A description will now be given with particular reference to Prior Art 1 and Prior Art 2. For the sake of convenience, s1 in this description is the aperture surface area of the fixed orifice, s2 is the aperture surface area of the third valve part 79 and the valve seat body 80, and s3 is the aperture surface area of the supplementary communication passage 85.
In Prior Art 1, the sum s1+s2 is the aperture surface area during discharge of the liquid refrigerant, and s1 is the aperture surface area during maximum capacity operation, regular control, and minimum capacity operation (hereinafter occasionally referred to collectively as “during control”).
In contrast, an object of Prior Art 2 is to increase the aperture surface area during discharge of the liquid refrigerant, and the aperture surface area during discharge of the liquid refrigerant is increased to s1+s2+s3 by providing the supplementary communication passage 85. However, the supplementary communication passage 85 is constantly open during operation, and the aperture surface area during regular control is therefore also increased to s1+s3. Increasing the aperture surface area during regular control creates the problem that the variation in control chamber pressure Pc relative to the variation in suction pressure Ps is slow, reducing the control speed of the swash plate during regular control. Therefore, the increase in the aperture surface area s1+s3 during regular control is prevented in Prior Art 2 by increasing the aperture surface area s1+s2+s3 during discharge of the liquid refrigerant and reducing the aperture surface area s1 of the fixed orifice as compared with Prior Art 1.
The increase in the aperture surface area s1+s3 during regular control is prevented in the above-described Prior Art 2, but the aperture surface area during regular operation is greater than in Prior Art 1, as shown in
The present invention was devised in order to solve the problems in Prior Art 1 and 2, and an object of the present invention is to provide a capacity control valve capable of maintaining an enhanced state for the function (aperture surface area during the discharge of liquid refrigerant according to Prior Art 2 in
Aimed at achieving the aforementioned object, the capacity control valve according to a first aspect of the present invention is characterized in comprising: a discharge-side passage for providing communication between a discharge chamber for discharging a fluid and a control chamber for controlling the discharge rate of the fluid;
a first valve chamber formed in the middle of the discharge-side passage;
a suction-side passage for providing communication between a suction chamber for drawing in the fluid and the control chamber;
a second valve chamber formed in the middle of the suction-side passage;
a valve body integrally having a first valve part for opening and closing the discharge-side passage in the first valve chamber and a second valve part for opening and closing the suction-side passage in the second valve chamber, and performing an operation in which opening and closing occur opposite to each other by reciprocation thereof;
a third valve chamber formed nearer to the control chamber and away from the second valve chamber in the middle of the suction-side passage;
a pressure-sensitive body disposed in the third valve chamber, the pressure-sensitive body exerting an urging force in a direction for opening the first valve part by elongation, and undergoing constriction in accordance with an increase in the surrounding pressure;
an adapter provided to a free end of the pressure-sensitive body in the elongation and constriction direction, the adapter having an annular bearing surface;
a valve body for discharging a liquid refrigerant, moveably provided inside the adapter;
a third valve part having an annular engaging surface for integrally moving with the valve body in the third valve chamber and opening and closing the suction-side passage by engagement with and disengagement from the bearing surface of the adapter and the valve body for discharging the liquid refrigerant; and
a solenoid for exerting an electromagnetic driving force on the valve body in a direction for closing the first valve part;
wherein a slit is provided to an engaging part of the adapter with the third valve part, an introduction hole for causing the control chamber pressure to act on a bottom surface of the valve body for discharging the liquid refrigerant is provided to the base part side, and urging means is provided whereby the valve body for discharging the liquid refrigerant is urged in a valve-opening direction away from the third valve part.
According to the first aspect, an enhanced state can be maintained for the function to discharge the liquid refrigerant in the control chamber during startup of the variable capacity compressor, an enhanced state can be maintained for the pressure discharge efficiency during maximum capacity, and the control speed of the swash plate during regular control and minimum capacity operation can be improved.
Secondly, the capacity control valve according to a first aspect of the present invention is characterized in that a contact surface that the valve body for discharging the liquid refrigerant has with the third valve part is formed in a tapered shape.
According to the second aspect, the seal diameter between the valve body for discharging the liquid refrigerant and the third valve part can be adjusted.
Thirdly, the capacity control valve according to a first or second aspect of the present invention is characterized in that a Y-ring is mounted to an external periphery of the valve body for discharging the liquid refrigerant, and the space between the valve body and the inner surface of the adapter is sealed.
According to the third aspect, the effect of the pressure difference between the control chamber pressure Pc and the suction chamber pressure Ps can be applied to the maximum.
The present invention achieves the following remarkable effects.
(1) An enhanced state can be maintained for the function to discharge the liquid refrigerant in the control chamber during startup of the variable capacity compressor, an enhanced state can be maintained for the pressure discharge efficiency during maximum capacity, and the control speed of the swash plate during regular control and minimum capacity operation can be improved by providing:
an adapter provided to a free end of the pressure-sensitive body in the elongation and constriction direction, the adapter having an annular bearing surface, and
a valve body for discharging a liquid refrigerant, moveably provided inside the adapter;
wherein a slit is provided to an engaging part of the adapter with the third valve part, an introduction hole for causing the control chamber pressure to act on a bottom surface of the valve body for discharging the liquid refrigerant is provided to the base part side, and urging means is provided whereby the valve body for discharging the liquid refrigerant is urged in a valve-opening direction away from the third valve part.
(2) The seal diameter between the valve body for discharging the liquid refrigerant and the third valve part can be adjusted by forming a contact surface that the valve body for discharging the liquid refrigerant has with the third valve part in a tapered shape.
(3) The effect of the pressure difference between the control chamber pressure Pc and the suction chamber pressure Ps can be applied to the maximum by mounting a Y-ring to an external periphery of the valve body for discharging the liquid refrigerant, and sealing the space between the valve body and the inner surface of the adapter.
The modes of working the capacity control valve according to the present invention are described in detail with reference to the drawings, but various changes, modifications, and improvements are possible within the scope of the present invention based on the knowledge of one skilled in the art, without limiting the interpretation of the present invention.
A variable capacity swash plate compressor M is provided with a discharge chamber 11; a control chamber (also referred to as a crank chamber) 12; a suction chamber 13; a plurality of cylinders 14; a port 11b opened and closed by a discharge valve 11a and used to provide communication between the cylinders 14 and the discharge chamber 11; a port 13b opened and closed by a suction valve 13a and used to provide communication between the cylinders 14 and the suction chamber 13; a discharge port 11c and a suction port 13c connected to an external cooling circuit; a communication passage 15 used as a discharge-side passage for providing communication between the discharge chamber 11 and the control chamber 12; a communication passage 16 doubling as the aforementioned discharge-side passage and as a suction-side passage for providing communication between the control chamber 12 and the suction chamber 13; a casing 10 for defining a communication passage 17 or the like as a suction-side passage; a rotating shaft 20 rotatably provided so as to protrude from the inside of the control chamber (crank chamber) 12 to the outside; a swash plate 21 integrally rotated with the rotating shaft 20 and linked to the rotating shaft 20 so that the angle of inclination can be varied; a plurality of pistons 22 fitted in a reciprocating manner inside each of the cylinders 14; a plurality of linking members 23 for linking each of the pistons 22 with the swash plate 21; a driven pulley 24 attached to the rotating shaft 20; a capacity control valve V of the present invention incorporated into the casing 10; and the like, as shown in
In addition, a communication passage 18 for direct communication between the control chamber (crank chamber) 12 and the suction chamber 13 is provided to the variable capacity swash plate compressor M, and a fixed orifice 19 is provided to the communication passage 18.
Moreover, the cooling circuit is connected to the discharge port 11c and the suction port 13c in the variable capacity swash plate compressor M, and a condenser (condensing device) 25, an expansion valve 26, and an evaporator (evaporating device) 27 are provided in a sequential arrangement to the cooling circuit.
The capacity control valve V is provided with a body 30 formed from a metal material or a resin material, a valve body 40 disposed in a reciprocating manner inside the body 30, a pressure-sensitive body 50 for urging the valve body 40 in one direction, a solenoid 60 connected to the body 30 and used to exert an electromagnetic driving force on the valve body 40, and the like, as shown in
The body 30 is provided with communication passages 31, 32, 33 functioning as discharge-side passages, communication passages 33, 34 functioning as suction-side passages together with a below-described communication passage 44 of the valve body 40, a first valve chamber 35 formed in the middle of the discharge-side passage, a second valve chamber 36 formed in the middle of the suction-side passage, a guide passage 37 for guiding the valve body 40, a third valve chamber 38 formed near the control chamber 12 of the discharge-side passage and the suction-side passage, and the like. In addition, a blocking member 39 that defines the third valve chamber 38 and constitutes a part of the body 30 is attached to the body 30 by threadable engagement.
Specifically, the communication passage 33 and the third valve chamber 38 are formed so as to double as a part of the discharge-side passage and the suction-side passage, and the communication passage 32 forms a valve hole for providing communication between the first valve chamber 35 and the third valve chamber 38 and accommodating the valve body 40 (accommodating the valve 40 while maintaining a gap for the flow of the fluid). The communication passages 31, 33, 34 are each arranged in a radial shape in a circumferential direction, and are formed in a plural number (for example, four passages at intervals of 90°).
A bearing surface 35a on which a first valve part 41 of the below-described valve body 40 is seated is formed on an edge part of the communication passage (valve hole) 32 in the first valve chamber 35, and a bearing surface 36a on which a second valve part 42 of the below-described valve body 40 is seated is formed on an end part of a below-described fixed iron core 64.
The valve body 40 is formed in a substantially cylindrical shape, and is provided with the first valve part 41 on one end, the second valve part 42 on the other end, a third valve part 43 linked by being mounted on the side opposite to the second valve part 42 across from the first valve part 41, the communication passage 44 passing through from the second valve part 42 to the third valve part 43 in the axial direction and functioning as a suction-side passage, and the like.
The third valve part 43 is formed in a fan shape spreading from a state of reduced diameter from the first valve chamber 35 toward the third valve chamber 38 to accommodate the communication passage (valve hole) 32, and is provided with an annular engaging surface 43a facing a below-described adapter 53 on the outside peripheral edge of the third valve part (refer to
Here, the engaging surface 43a of the third valve part 43 with the adapter 53 is formed in a spherical shape having an outward convexity and a radius of curvature R, as shown in
In
The adapter 53 is provided with a hollow cylindrical part 53a having a substantial U-shape in cross section and engaging via the distal end thereof with the third valve part 43, and is also provided with an annular bearing surface 53b that has a protrusion extending into the bellows 51 and can engage with and disengage from the engaging surface 43a of the third valve part 43 in a facing arrangement at the distal end of the hollow cylindrical part 53a, as shown in
Specifically, the pressure-sensitive body 50 is disposed in the third valve chamber 38 and operates so as to exert an urging force in a direction for opening the first valve part 41 by elongation (expansion), and undergo constriction in accordance with an increase in the surrounding pressure (inside the communication passage 44 of the third valve chamber 38 and the valve body 40) to reduce the urging force exerted on the first valve part 41.
As shown in
The valve body 48 for discharging the liquid refrigerant has a cylinder part 48a and a bottom part 48b fitted with the interior surface of the hollow cylindrical part 53a of the adapter 53; a protrusion 48c is provided facing the exterior in the center of the bottom part 48b; a space is formed between the base part 53c of the adapter 53 and the bottom part 48b; and control chamber pressure Pc from the hole 55 for introducing pressure into the control chamber is introduced into the space. The valve body 48 for discharging the liquid refrigerant is urged in the direction in which a contact surface 48d at the distal end of the cylinder part 48a is separated from the end face 47 of the third valve part 43 by a spring 49 provided at the end face 47 of the third valve part 43. The repulsive force of the spring 49 is set to a level at which the valve body 48 for discharging the liquid refrigerant closes when the set pressure difference (Δp) between Pc and Ps is reached or exceeded (specifically, the setting is established so that the repulsive force of the spring 49 is less than ΔP at the time of valve closure). In the present example, the distal end face 48d of the cylinder part 48a is formed in a planar shape orthogonal to the central axis direction, and is parallel to the end face 47 of the third valve part 43. Moreover, the slit 54 of the adapter 53 is completely open in a state in which the valve body 48 for discharging the liquid refrigerant is opened to the maximum extent.
The fixed orifice 19 of the present embodiment (present invention) is set to the same aperture surface area as the aperture surface area s1 of the fixed orifice of Prior Art 2, and the surface area s4 of the slit is set to the same aperture surface area as the aperture surface area s3 of the supplementary communication passage of Prior Art 2, as shown in
Accordingly, in the present embodiment, the aperture surface area during the discharge of the liquid refrigerant is the same s1+s2+s4 as the aperture surface area of Prior Art 2, and the aperture surface area during maximum capacity operation (when the control chamber pressure Pc and the suction pressure Ps are substantially the same) is the same s1+s4 as the aperture surface area of Prior Art 2 because a state is maintained in which the valve body 48 for discharging the liquid refrigerant is opened.
However, in the present embodiment, the aperture surface area during regular control is a surface area in which the valve body 48 for discharging the liquid refrigerant operates in the closing direction when the pressure difference between the control chamber pressure Pc and the suction pressure Ps approaches ΔP, as shown in
According to the present embodiment, the aperture surface area during the discharge of the liquid refrigerant is increased to the same surface area as that of Prior Art 2, and an enhanced state can be maintained for the function to discharge the liquid refrigerant in the control chamber during startup and an enhanced state can be maintained for the pressure discharge efficiency during maximum capacity. In addition, the aperture surface area during regular control and minimum capacity operation can be reduced to the aperture surface area of the fixed orifice. The control chamber pressure Pc can therefore be highly responsive to the change in suction pressure Ps, and the control speed of the swash plate during regular control and minimum capacity operation can be improved, as shown by the solid line in
The solenoid 60 is provided with a casing 62 linked to the body 30, a sleeve 63 in which one end part is closed, a cylindrical fixed iron core 64 disposed inside the casing 62 and the sleeve 63, a drive rod 65 disposed in the fixed iron core 64 in a reciprocating manner and arranged so that the distal end of the drive rod is linked to the valve body 40 to form the communication passage 44, a moveable iron core 66 fixedly attached to the other end of the drive rod 65, a coil spring 67 for urging the moveable iron core 66 in the direction that opens the first valve part 41, an excitation coil 68 wound on the outside of the sleeve 63 via a bobbin, and the like, as shown in
In the above-described structure, in a state in which the coil 68 is unpowered, the valve body 40 is moved upward in
When the variable capacity compressor is left in a stopped state for a long time while the communication passages (suction-side passages) 34, 44 are blocked, a state arises in which the liquid refrigerant accumulates in the control chamber (crank chamber) 12 of the variable capacity compressor, the interior of the variable capacity compressor achieves a uniform pressure, and the control chamber pressure Pc rises substantially above the control chamber pressure Pc and the suction pressure Ps during operation of the variable capacity compressor.
When the coil 68 is powered above a preset electric current value (I), the valve body 40 is moved downward in
The bellows 51 elongates when the liquid refrigerant and the like in the control chamber are discharged and the control chamber pressure Pc reaches or surpasses a preset level. The third valve part 43 rests on the bearing surface 53b of the adapter 53, as shown in
In the above-described structure, the formula for the equilibrium relationship of the force acting on the valve body 40 is as shown below, where Ab is the pressure-receiving surface area at the effective diameter of (the bellows 51 of) the pressure-sensitive body 50, Ar1 is the pressure-receiving surface area at the seal diameter of the third valve part 43, As is the pressure-receiving surface area at the seal diameter of the first valve part 41, Art is the pressure-receiving surface area at the seal diameter of the second valve part 42, Fb is the urging force of the pressure-sensitive body 50, Fs is the urging force of the coil spring 67, Fsol is the urging force due to the electromagnetic driving force of the solenoid 60, Pd is the discharge pressure of the discharge chamber 11, Ps is the suction pressure of the suction chamber 13, and Pc is the control chamber pressure of the control chamber (crank chamber) 12, as shown in
Pc·(Ab−Ar1)+Pc·(Ar1−As)+Ps·Ar1+Ps·(Ar2−Ar1)+Pd·(As−Ar2)=Fb+Fs−Fso1
In the above-described structure, the pressure-receiving surface area Ab of the pressure-sensitive body 50 and the pressure-receiving surface area Ar1 of the third valve part 43 are formed in the same manner, as are the pressure-receiving surface area As of the first valve part 41 and the pressure-receiving surface area Ar2 of the second valve part 42, and the pressure-receiving surface area Ar1 of the third valve part 43 and the pressure-receiving surface area As of the first valve part 41.
Specifically, the control chamber pressure Pc acting on the pressure-sensitive body 50 in the third valve chamber 38 can be canceled out by making the pressure-receiving surface area Ab and the pressure-receiving surface area Ar1 equal. The effect of the pressure can be prevented, the valve body 40 can operate without being affected by the control chamber pressure Pc, and capacity can be controlled in a stable manner.
In addition, the discharge pressure Pd acting on the valve body 40 can be canceled out by making the pressure-receiving surface area As and the pressure-receiving surface area Ar2 equal to each other. The effect of the pressure can be prevented, the valve body 40 can operate without being affected by the discharge pressure Pd, and capacity can be controlled in a stable manner.
An operation in which the variable capacity swash plate compressor M provided with the capacity control valve V is applied to an air-conditioning system of a motor vehicle is described below.
The rotating shaft 20 is first rotated via a transmission belt (not shown) and the driven pulley 24 by the rotary driving force of the engine, whereupon the swash plate 21 rotates integrally with the rotating shaft 20. When the swash plate 21 rotates, the piston 22 reciprocates in the cylinder 14 at a stroke corresponding to the angle of inclination of the swash plate 21, and a coolant gas drawn into the cylinder 14 from the suction chamber 13 is compressed by the piston 22 and discharged to the discharge chamber 11. The discharged coolant gas is supplied to the evaporator 27 from the condenser 25 via the expansion valve 26, and the gas returns to the suction chamber 13 while a cooling cycle is performed.
Here, the discharge rate of the coolant gas is determined by the stroke of the piston 22, and the stroke of the piston 22 is determined by the angle of inclination of the swash plate 21 controlled by the pressure inside the control chamber 12 (control chamber pressure Pc).
During compression of the piston 22, blowby gas from the clearance between the piston 22 and the cylinder 14 constantly flows toward the control chamber 12 and causes the pressure Pc of the control chamber 12 to increase. However, pressure discharge occurs at a constant rate from the control chamber 12 to the suction chamber even when the communication passages (suction-side passages) 33, 44, 34 are closed because a fixed orifice 19 is provided. The aperture surface area during maximum capacity operation is therefore preferably large.
When the solenoid 60 is first turned off and the variable capacity compressor is left in a stopped state for a long time period of time while the second valve part 42 is blocking the communication passages (suction-side passages) 34, 44, a state arises in which the liquid refrigerant accumulates in the control chamber 12, the interior of the variable capacity compressor achieves a uniform pressure, and the control chamber pressure Pc rises substantially above the control chamber pressure Pc and the suction pressure Ps during driving of the variable capacity compressor.
When the solenoid 60 is turned on and the valve body 40 is started up in this state, the first valve part 41 moves in the closing direction at the same time as the second valve part 42 moves in the opening direction. The liquid refrigerant in the control chamber is discharged immediately following the startup, but the bellows 51 is constricted because the control chamber pressure Pc reaches or surpasses a preset level. As shown in
In this discharge process, the engaging surface 43a of the third valve part 43 is formed in a spherical shape having a radius of curvature R, and the bearing surface 53b of the adapter 53 is formed in a tapered planar shape having a central angle α. The liquid refrigerant can therefore be efficiently discharged, and quick movement to the desired capacity control is possible.
In an operating state having a maximum discharge rate, the solenoid 60 (coil 68) is powered by a preset electric current (I), the moveable iron core 66 and the drive rod 65 act against the urging force of the pressure-resistant body 50 and the coil spring 67, and the valve body 40 moves to a position in which the first valve part 41 rests on the bearing surface 35a to block the communication passages (discharge-side passages) 31, 32, and the second valve part 42 is separated from the bearing surface 36a to open the communication passages (suction-side passages) 34, 44.
The pressure-sensitive body 50 elastically recovers and elongates because the control chamber pressure Pc reaches or decreases below a preset level, and the adapter 53 engages with the third valve part 43.
The control chamber pressure Pc inside the control chamber 12 and the suction pressure Ps are substantially the same; specifically, the difference between Pc and Ps is less than ΔP. As shown in
During regular control (between maximum capacity operation and minimum capacity operation), the magnitude of the electric power provided to the solenoid 60 (coil 68) is appropriately controlled to vary the electromagnetic driving force (urging force). Specifically, the position of the valve body 40 is appropriately adjusted by the electromagnetic driving force, and the opening rate of the first valve part 41 and the opening rate of the second valve part 42 are controlled so as to attain the desired discharge rate. In this state, the suction pressure Ps is smaller than the control chamber pressure Pc, and the valve body 48 for discharging the liquid refrigerant is operated in the closing direction (the aperture surface area during regular control in
In addition, in a minimum capacity operation state, the solenoid 60 (coil 68) is unpowered, and the moveable iron core 66 and the drive rod 65 are retracted and stopped in a resting position by the urging force of the coil spring 67. The valve body 40 is moved to a position in which the first valve part 41 is separated from the bearing surface 35a to open the communication passages (discharge-side passages) 31, 32, and the second valve part 42 rests on the bearing surface 36a to close the communication passages (suction-side passages) 34, 44. The discharge fluid (discharge pressure Pd) is thereby supplied inside the control chamber 12 through the communication passages (discharge-side passages) 31, 32, 33. The angle of inclination of the swash plate 21 is then controlled so as to be greatly reduced, and the stroke of the piston 22 reaches the minimum. As a result, the discharge rate of the coolant gas is at the minimum. In this state, the control chamber pressure Pc is large and the suction pressure Ps is small, and the pressure difference between Pc and Ps is therefore large. As shown in
During regular control, the aperture surface area of the communication passages (33, 44, 34) can thus be reduced to substantially the same surface area as that of the fixed orifice, and the control speed of the swash plate during regular control and minimum capacity operation can be increased because the communication passages (33, 44, 34) can be blocked during minimum capacity operation.
The members in
In the present example, the contact surface 48d at the distal end of the cylinder part 48a of the valve body 48 for discharging the liquid refrigerant is formed in a shallow shape that tapers off in the direction from the outside periphery toward the inside periphery. The seal diameter of both the contact surface 48d and the spherical engaging surface 43a of the third valve part 43 can therefore be adjusted.
The members in
In the present example, the structure is such that a Y-ring 56 is mounted to the external periphery of the valve body 48 for discharging the liquid refrigerant, and the effect of the pressure difference between the control chamber pressure Pc and the suction chamber pressure Ps can be applied to the maximum extent by forming a secure seal between the valve body 48 for discharging the liquid refrigerant and the inner surface of the hollow cylindrical part 53a of the adapter 53. Mounting the Y-ring 56 allows the bottom part 48b of the valve body 48 for discharging the liquid refrigerant to be extended in the axial direction, and a circular channel for mounting the Y-ring 56 to be provided.
Number | Date | Country | Kind |
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2010-059895 | Mar 2010 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2011/053810 | 2/22/2011 | WO | 00 | 4/4/2012 |