Patent Grant
11434885
This application is the U.S. National Phase under 35 U.S.C. § 371 of International Application PCT/JP2018/047693, filed Dec. 26, 2018, which claims priority to Japanese Patent Application No. JP2017-252351, filed Dec. 27, 2017. The International Application was published under PCT Article 21(2) in a language other than English.
The present invention relates to a capacity control valve and a method for controlling the capacity control valve used for controlling a flow rate or pressure of a variable capacity compressor.
As the variable capacity compressor, for example, a swash plate type capacity variable compressor used in an air conditioning system of an automobile, etc. includes a rotation shaft to be driven and rotated by rotation force of an engine, a swash plate coupled to the rotation shaft so that a tilting angle is variable, and compressing pistons coupled to the swash plate, etc., and is to change strokes of the pistons and control a discharge amount of a coolant by changing the tilting angle of the swash plate.
This tilting angle of the swash plate can be continuously changed by appropriately controlling pressure in a control chamber by using a capacity control valve to be driven and opened/closed by electromagnetic force while utilizing suction pressure of a suction chamber to which the coolant is sucked in, discharge pressure of a discharge chamber from which the coolant pressurized by the pistons is discharged, and control chamber pressure of the control chamber (crank chamber) in which the swash plate is housed, and by adjusting a balance state of pressure acting on both surfaces of the pistons.
In this capacity control valve 160, without providing a clutch mechanism in the variable capacity compressor, in a case where the need for changing the control chamber pressure arises, the pressure (control chamber pressure) Pc in the control chamber and the suction pressure Ps (suction pressure) can be controlled by providing communication between the discharge chamber and the control chamber (hereinafter, referred to as the “conventional art”. See Patent Document 1, for example).
In the conventional art, in a case where the swash plate type capacity variable compressor is stopped for a long time, a liquid coolant (made by cooling and liquefying a coolant during abandonment) is accumulated in the control chamber (crank chamber). Thus, even when the compressor is started up in this state, it is not possible to ensure a discharge amount as it is set. Therefore, in order to perform desired capacity control immediately after start-up, there is a need for discharging the liquid coolant of the control chamber (crank chamber) as soon as possible.
As shown in
However, in the above conventional art, at an initial stage of a liquid coolant discharging process, pressure of the control chamber is high and hence an opening degree of the third valve portion 179 is large. Thus, it is possible to efficiently discharge the liquid coolant. However, as discharge of the liquid coolant progresses and the pressure of the control chamber is lowered, the opening degree of the third valve portion is decreased. Thus, there is a problem that it takes time to discharge the liquid coolant.
Conventionally, at the time of a liquid coolant discharging operation, focus is placed only on how quickly the discharge of the liquid coolant is completed. Thus, control of reducing an engine load is not performed at the time of the liquid coolant discharging operation. However, when the liquid coolant discharging operation is performed with a high engine load, the engine load is further increased, and there is also a problem that energy efficiency of the entire automobile is lowered.
The present invention is achieved to solve the problems of the above conventional art, and an object of the present invention is to provide a capacity control valve and a method for controlling a capacity control valve, capable of, in the capacity control valve that controls a flow rate or pressure of a variable capacity compressor in accordance with a valve opening degree of a valve portion, stably controlling an opening degree of a main valve portion at the time of control, efficiently discharging a liquid coolant irrespective of pressure of a suction chamber, shifting to a cooling operation for a short time, and further lowering drive force of the compressor at a liquid coolant discharging operation.
In order to solve the foregoing problems, a capacity control valve according to a first aspect of the present invention is a capacity control valve that controls a flow rate or pressure of a variable capacity compressor in accordance with a valve opening degree of a valve portion, the capacity control valve being characterized by including a valve main body having a first communication passage through which a fluid of first pressure passes, a second communication passage arranged adjacent to the first communication passage, the second communication passage through which a fluid of second pressure passes, a third communication passage through which a fluid of third pressure passes, and a main valve seat arranged in a valve hole which provides communication between the second communication passage and the third communication passage, a solenoid that drives a rod having an auxiliary valve seat, a valve element having an intermediate communication passage providing communication between the first communication passage and the third communication passage, a main valve portion to be separated from and connected to the main valve seat so as to open and close the valve hole, and an auxiliary valve portion to be separated from and connected to the auxiliary valve seat so as to open and close the intermediate communication passage, and a first biasing member that biases in the valve closing direction of the main valve portion, characterized in that a spring constant of the first biasing member has a characteristic that the spring constant is increased in an opened state of the main valve portion and decreased in a closed state.
According to the first aspect, in the opened state of the main valve portion where a load acting on the first biasing member is decreased, the spring constant is increased and hence the first biasing member is hardly deformed. Therefore, the rod and the valve element are integrally displaced in a state where relative positions are maintained. Thus, the capacity control valve can stably control an opening degree of the main valve portion. In the closed state of the main valve portion where the load acting on the first biasing member is increased, the spring constant of the first biasing member is decreased. Thus, without excessively increasing an output of the solenoid, the rod can easily deform the first biasing member and forcibly open the auxiliary valve portion. Thereby, in liquid coolant discharge, it is possible to maintain an opening degree of the auxiliary valve portion in a fully opened state and efficiently discharge the liquid coolant irrespective of pressure of a suction chamber.
The capacity control valve according to a second aspect of the present invention is characterized in that the first biasing member is arranged between the rod and the valve element.
According to the second aspect, it is possible to transmit drive force of the solenoid in the valve closing direction of the main valve portion via the first biasing member arranged between the rod and the valve element and reliably close the main valve portion.
The capacity control valve according to a third aspect of the present invention is characterized in that the first biasing member has a communication portion communicating with the intermediate communication passage.
According to the third aspect, regarding a coolant flowing through the intermediate communication passage, by the communication passage, a flow of the coolant is not inhibited.
The capacity control valve according to a fourth aspect of the present invention is characterized in that the solenoid further includes a plunger connected to the rod, a core arranged between the plunger and the valve main body, an electromagnetic coil, and a second biasing member arranged between the plunger and the core.
According to the fourth aspect, by the second biasing member arranged between the plunger and the core, it is possible to reliably bias the valve element in the valve opening direction of the main valve portion.
The capacity control valve according to a fifth aspect of the present invention is characterized in that the first pressure is suction pressure of the variable capacity compressor, the second pressure is discharge pressure of the variable capacity compressor, and the third pressure is pressure of a crank chamber of the variable capacity compressor. The capacity control valve according to a sixth aspect of the present invention is characterized in that the first pressure is pressure of a crank chamber of the variable capacity compressor, the second pressure is discharge pressure of the variable capacity compressor, and the third pressure is suction pressure of the variable capacity compressor.
According to the fifth or sixth aspect, it is possible to respond to various variable capacity compressors.
In order to solve the foregoing problems, a method for controlling a capacity control valve according to a seventh aspect of the present invention is a method for controlling a capacity control valve, characterized by including the step of making the main valve portion from a closed state to an opened state when the auxiliary valve portion is in an opened state.
According to the seventh aspect, in a state where biasing force of the pressure-sensitive body does not act on the valve element at the time of the liquid coolant discharge, the main valve portion is opened and a flow rate from a discharge chamber to a control chamber is increased, so that it is possible to reduce the load of the compressor.
Hereinafter, with reference to the drawings, a mode for carrying out the present invention will be described illustratively based on an embodiment. However, the dimensions, materials, shapes, relative positions, etc. of constituent parts described in this embodiment are not limited only to themselves unless otherwise described particularly explicitly.
With reference to
Hereinafter, with reference to
A second communication passage 12 is continuously provided in the second valve chamber 15. This second communication passage 12 communicates with the inside of a discharge chamber (not shown) of a variable capacity compressor so that a fluid of discharge pressure Pd (second pressure according to the present invention) can flow in from the second valve chamber 15 to the third valve chamber 16 by opening and closing the capacity control valve 1.
A third communication passage 13 is continuously provided in the third valve chamber 16. The third communication passage 13 communicates with a control chamber (not shown) of the variable capacity compressor so that the fluid of discharge pressure Pd flowing in from the second valve chamber 15 to the third valve chamber 16 by opening and closing the capacity control valve 1 flows out to the control chamber (crank chamber) of the variable capacity compressor and a fluid of control chamber pressure Pc (third pressure according to the present invention) flowing into the third valve chamber 16 flows out to a suction chamber of the variable capacity compressor via an intermediate communication passage 29 to be described later and through the first valve chamber 14.
Further, a first communication passage 11 is continuously provided in the first valve chamber 14. This first communication passage 11 leads a fluid of suction pressure Ps (first pressure according to the present invention) from the suction chamber of the variable capacity compressor to the pressure-sensitive body 24 via the intermediate communication passage 29 to be described later, and controls the suction pressure of the compressor to a set value.
Between the first valve chamber 14 and the second valve chamber 15, a hole portion 18 having a diameter smaller than a diameter of any of these chambers is continuously formed. A labyrinth 21f to be described later is formed in this hole portion 18, and forms a seal portion that seals a part between the first valve chamber 14 and the second valve chamber 15. Between the second valve chamber 15 and the third valve chamber 16, a valve hole 17 having a diameter smaller than a diameter of any of these chambers is continuously provided. A main valve seat 15a is formed around the valve hole 17 on the second valve chamber 15 side. This main valve seat 15a is separated from and connected to a main valve portion 21c to be described later so as to control opening and closing of a Pd-Pc flow passage providing communication between the second communication passage 12 and the third communication passage 13.
The pressure-sensitive body 24 is arranged in the third valve chamber 16. One end portion of a metal bellows 24a of this pressure-sensitive body 24 is combined to a partition adjusting portion 24f in a sealed state. This bellows 24a is made of phosphor bronze, stainless, etc. and a spring constant of the bellows is designed to be a predetermined value. An internal space of the pressure-sensitive body 24 is vacuum or the air exists in the internal space. Pressure acts on a valid pressure receiving area of the bellows 24a of this pressure-sensitive body 24 so that the pressure-sensitive body 24 is extended and contracted. A flange portion 24d is arranged on the free end portion side of the pressure-sensitive body 24. By directly pressing this flange portion 24d by a locking portion 26 of a rod 36 to be described later, the pressure-sensitive body 24 is extended and contracted. That is, as described later, the pressure-sensitive body 24 is extended and contracted in accordance with the suction pressure Ps led to the pressure-sensitive body 24 via the intermediate communication passage 29, and also extended and contracted by pressing force of the rod 36.
The partition adjusting portion 24f of the pressure-sensitive body 24 is sealed, fitted, and fixed so as to close the third valve chamber 16 of the valve main body 10. By screwing the partition adjusting portion 24f and fixing by a locking screw (not shown), it is possible to adjust axial movement of spring force of a compression spring arranged in parallel in the bellows 24a or the bellows 24a.
For example, two to six parts of each of the first communication passage 11, the second communication passage 12, and the third communication passage 13 pass through a peripheral surface of the valve main body 10 at equal intervals. Further, attachment grooves for O rings are provided at three points while being separated in the axial direction on an outer peripheral surface of the valve main body 10. O rings 47, 48, 49 that seal a part between the valve main body 10 and an installment hole of a casing (not shown) fitted to the valve main body 10 are attached to the attachment grooves. Flow passages of the first communication passage 11, the second communication passage 12, and the third communication passage 13 are formed as independent flow passages.
Next, the valve element 20 will be described. The valve element 20 is mainly formed by a main valve element 21 which is a cylindrical hollow member, and an adapter 23. First, the main valve element 21 will be described. The main valve element 21 is a cylindrical hollow member, and the labyrinth 21f is formed in a substantially center portion in the axial direction of an outer peripheral portion of the main valve element. The main valve element 21 is inserted into the valve main body 10, and the labyrinth 21f slides on the hole portion 18 between the first valve chamber 14 side and the second valve chamber 15 side so as to form a seal portion that seals the first valve chamber 14 and the second valve chamber 15. Thereby, the first valve chamber 14 communicating with the first communication passage 11 and the second valve chamber 15 communicating with the second communication passage 12 are formed as independent valve chambers.
The main valve element 21 is arranged on the first communication passage 11 side and on the second communication passage 12 side across the labyrinth 21f. The main valve portion 21c is formed in an end portion of the main valve element 21 arranged on the second communication passage 12 side. The main valve portion 21c is separated from and connected to the main valve seat 15a so as to control opening and closing of the valve hole 17 providing communication between the second valve chamber 15 and the third valve chamber 16. The main valve portion 21c and the main valve seat 15a form a main valve 27b. A situation where the main valve portion 21c and the main valve seat 15a are brought from a contact state into a separate state will be indicated as the main valve 27b is opened or the main valve portion 21c is opened. A situation where the main valve portion 21c and the main valve seat 15a are brought from a separate state into a contact state will be indicated as the main valve 27b is closed or the main valve portion 21c is closed. A shut-off valve portion 21a is formed in an end portion of the main valve element 21 arranged in the first valve chamber 14. The shut-off valve portion 21a is brought into contact with an end portion 32c of a core 32 when the solenoid 30 to be described later is turned off, so as to shut off communication between the intermediate communication passage 29 and the first valve chamber 14. The shut-off valve portion 21a and the end portion 32c of the core 32 form a shut-off valve 27a. The shut-off valve portion 21a and the main valve portion 21c of the valve element 20 are formed to perform opening and closing actions in the opposite directions to each other. A situation where the shut-off valve portion 21a and the end portion 32c of the core 32 are brought from a contact state into a separate state will be indicated as the shut-off valve 27a is opened or the shut-off valve portion 21a is opened. A situation where the shut-off valve portion 21a and the end portion 32c of the core 32 are brought from a separate state into a contact state will be indicated as the shut-off valve 27a is closed or the shut-off valve portion 21a is closed.
Next, the adapter 23 forming the valve element 20 will be described. The adapter 23 is mainly formed by a large diameter portion 23c formed to have a large diameter by a cylindrical hollow member, and a tube portion 23e formed to have a diameter smaller than the large diameter portion 23c. The tube portion 23e is fitted to an opening end portion on the main valve portion 21c side of the main valve element 21 so that the valve element 20 is formed. Thereby, the intermediate communication passage 29 passing through in the axial direction is formed in the inside of the main valve element 21 and the adapter 23, that is, the inside of the valve element 20. An auxiliary valve portion 23d is formed in the large diameter portion 23c of the adapter 23. The auxiliary valve portion 23d is brought into contact with and separated from an auxiliary valve seat 26c of the locking portion 26 of the rod 36 so as to open and close the intermediate communication passage 29 providing communication between the first communication passage 11 and the third communication passage 13. The auxiliary valve portion 23d and the auxiliary valve seat 26c form an auxiliary valve 27c. A situation where the auxiliary valve portion 23d and the auxiliary valve seat 26c are brought from a contact state into a separate state will be indicated as the auxiliary valve 27c is opened or the auxiliary valve portion 23d is opened. A situation where the auxiliary valve portion 23d and the auxiliary valve seat 26c are brought from a separate state into a contact state will be indicated as the auxiliary valve 27c is closed or the auxiliary valve portion 23d is closed.
Next, the solenoid 30 will be described. The solenoid includes the rod 36, a plunger case 38, an electromagnetic coil 31, the core 32 formed by a center post 32a and a base member 32b, a plunger 35, a plate 34, and a solenoid case 33. The plunger case 38 is a bottomed cylindrical hollow member whose one side is open. The plunger 35 is arranged movably in the axial direction with respect to the plunger case 38 between the plunger case 38 and the center post 32a arranged inside the plunger case 38. The core 32 is fitted to the valve main body 10 and arranged between the plunger 35 and the valve main body 10. The rod 36 is arranged to pass through the center post 32a of the core 32 and the valve element 20 arranged in the valve main body 10. The rod 36 has a gap from a through hole 32e of the center post 32a of the core 32 and the intermediate communication passage 29 of the valve element 20, and can be relatively moved with respect to the core 32 and the valve element 20. One end portion 36e of the rod 36 is connected to the plunger 35 and the locking portion 26 is connected to a pressing portion 36h serving as the other end portion.
The locking portion 26 serving as part of the rod 36 will be described. The locking portion 26 is a disc plate shaped member in which a base portion 26a is formed and brim portions are formed from the base portion 26a on both sides in the axial direction. One of the brim portions functions as the auxiliary valve seat 26c to be separated from and connected to the auxiliary valve portion 23d of the adapter 23, and the other brim portion functions as a pressing portion 26d to be separated from and connected to the flange portion 24d of the pressure-sensitive body 24 so as to extend and contract the pressure-sensitive body 24. A distribution hole 26f through which a coolant is distributed is formed in the base portion 26a of the locking portion 26. The locking portion 26 may be integrated with the rod 36 or the locking portion 26 may be fitted and fixed to the rod 36 and integrally formed.
A spring 37 (second biasing member according to the present invention) that biases the plunger 35 so as to separate the plunger from the core 32 is arranged between the core 32 and the plunger 35. Thereby, biasing force of the spring 37 acts in the direction in which the main valve portion 21c of the valve element 20 is opened.
An opening end portion of the plunger case 38 is fixed to an inner peripheral portion of the base member 32b of the core 32 in a sealed state, and the solenoid case 33 is fixed to an outer peripheral portion of the base member 32b in a sealed state. The electromagnetic coil 31 is arranged in a space surrounded by the plunger case 38, the base member 32b of the core 32, and the solenoid case 33 and not brought into contact with the coolant. Thus, it is possible to prevent a decrease in insulation resistance.
Next, a disc spring 43 (first biasing member according to the present invention) will be described. As shown in
The disc spring 43 is arranged between the solenoid 30 and the valve element 20. Specifically, one end of the disc spring 43 is in contact with a stepped portion 36f of the rod 36 formed at the substantially same position as the end portion 32c of the core 32, and the other end (i.e. an outer circumference 43a of the disc spring 43) is in contact with an inside stepped portion 21h formed on the intermediate communication passage 29 side of the valve element 20. The disc spring 43 has such a non-linear spring constant that the spring constant of the disc spring 43 is increased with a small applied load and the spring constant of the disc spring 43 is decreased with a large load.
Actions of the capacity control valve 1 having the configuration described above will be described. A flow passage running from the third communication passage 13 to the first communication passage 11 through the intermediate communication passage 29 will be called as the “Pc-Ps flow passage” below. A flow passage running from the second communication passage 12 to the third communication passage 13 through the valve hole 17 will be called as the “Pd-Pc flow passage” below.
First, movement of the rod 36 and movement of the valve portions of the valve element 20 will be described. First of all, in a non-energized state of the solenoid 30, as shown in
Next, as shown in
Further, when the rod 36 is driven in the forward direction, as shown in
Next, a control state of the capacity control valve 1 will be described based on
Next, a liquid coolant discharge state of the capacity control valve 1 will be described based on
Conventionally, at the time of a liquid coolant discharging operation, focus is placed only on how quickly discharge of the liquid coolant is completed. Thus, there is sometimes a case where an engine load becomes excessive during the liquid coolant discharging operation. With the capacity control valve 1 according to the present invention, even at the time of the liquid coolant discharge, it is possible to rapidly drive the valve element 20. At the time of the liquid coolant discharge, actions of the capacity control valve 1 when the engine load is reduced will be described.
In a case where the engine load is rapidly reduced at the time of the liquid coolant discharge, the solenoid 30 is turned off and magnetic attracting force Fsol between the core 32 and the plunger 35 is operated to be zero. Since settings is made to cancel upward pressure and downward pressure acting on the valve element 20, regarding major force acting on the valve element 20 at the time of the liquid coolant discharge, the biasing force of the spring 37 acting in the valve opening direction of the main valve 27b, and the total force of the biasing force of the disc spring 43 acting in the valve closing direction of the main valve 27b and the magnetic attracting force Fsol of the solenoid 30 are balanced. When the magnetic attracting force Fsol of the solenoid 30 becomes zero, the biasing force of the spring 37 acting in the valve opening direction of the main valve 27b becomes dominant, the rod 36 is moved upward, and the disc spring 43 is returned to the natural state. As a result, the rod 36 is rapidly pushed up, the locking portion 26 is brought into contact with the adapter 23, the valve element 20 is driven in the valve opening direction of the main valve 27b, and the main valve 27b is rapidly fully opened. When the main valve 27b is fully opened, a coolant amount flowing from the discharge chamber of the compressor to the crank chamber through the Pd-Pc flow passage is increased, the pressure Pc in the crank chamber is increased, and the compressor is operated by the minimum capacity. In this way, as the time of the liquid coolant discharge, even in a state where the auxiliary valve 27c is in an opened state and no force acts on the valve element 20 from the pressure-sensitive body 24, it is possible to reduce the load of the compressor and hence it is possible to reduce the engine load even at the time of the liquid coolant discharge.
In a state where the pressure of the suction chamber of the compressor is controlled to be the set value Pset by the capacity control valve 1, and in a case where the load of the engine is to be reduced, by bringing the solenoid 30 into a non-energized state similarly to the above description, the main valve 27b is brought into a fully opened state, the coolant amount of the Pd pressure flowing from the discharge chamber of the compressor to the crank chamber through the Pd-Pc flow passage is increased, and the compressor is operated by the minimum capacity, so that it is possible to perform an operation with which the load of the engine is reduced.
The disc spring 43 has such a non-linear characteristic that the spring constant is increased with a small load and the spring constant is decreased with a large load. Thereby, in the opened state of the main valve 27b where the load acting on the disc spring 43 is small, the spring constant is increased, and hence the disc spring 43 is hardly deformed. Therefore, the rod 36 and the valve element 20 are integrally displaced in a state where relative positions are maintained. Thus, the capacity control valve 1 can stably control the opening degree of the main valve 27b. In the closed state of the main valve 27b where the load acting on the disc spring 43 is large, the spring constant of the disc spring 43 is decreased. Thus, without excessively increasing an output of the solenoid 30, the rod 36 can largely deform the disc spring 43 and forcibly open the auxiliary valve 27c. Thereby, at the time of the liquid coolant discharge, it is possible to maintain the auxiliary valve 27c in a fully opened state irrespective of the pressure of the third valve chamber 16 and the pressure Ps of the suction chamber. Thus, it is possible to discharge the liquid coolant from the crank chamber to the suction chamber via the Pc-Ps flow passage for a short time.
The embodiment of the present invention is described with the drawings above. Specific configurations are not limited to the embodiment but the present invention also includes changes and additions within the range not departing from the gist of the present invention.
For example, in the above embodiment, the one end of the disc spring 43 is in contact with the stepped portion 36f of the rod 36, and the other end is in contact with the inside stepped portion 21h of the valve element 20. However, the present invention is not limited to this. For example, as shown in
In the above embodiment, the first pressure of the first valve chamber 14 is the suction pressure Ps of the variable capacity compressor, the second pressure of the second valve chamber 15 is the discharge pressure Pd of the variable capacity compressor, and the third pressure of the third valve chamber 16 is the pressure Pc of the crank chamber of the variable capacity compressor. However, the present invention is not limited to this but with the first pressure of the first valve chamber 14 being the pressure Pc of the crank chamber of the variable capacity compressor, the second pressure of the second valve chamber 15 being the discharge pressure Pd of the variable capacity compressor, and the third pressure of the third valve chamber 16 being the suction pressure Ps of the variable capacity compressor, it is possible to respond to various variable capacity compressors.
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| Number | Date | Country | |
|---|---|---|---|
| 20200332786 A1 | Oct 2020 | US |
