The present invention relates to a flow control valve and, more particularly, a flow control valve for preventing hunting of the valve body from being induced by the pressure of operating fluid which flows through a valve orifice during a valve opening action.
There is a flow control valve used for a variable displacement compressor as prior art of the present invention. This flow control valve controls the operating fluid during valve opening action by accurately positioning the valve body relative to the valve seat in accordance with electric current supplied to a solenoid. Pressure of the operating fluid, however, raises a hunting problem of the valve body. This will lead to an insufficient control of the operating fluid and unexpected operation of the variable displacement compressor and the like.
100 in
The valve main body 101 disposes a suction port 106 which introduces fluid of suction pressure Ps, and the suction port 106 is able to communicate a control chamber (pressure regulation camber), not shown, via suction relief valve and orifice which are disposed in a communication passage, not shown. As shown in the upper portion of the figure, a second control port 105 is disposed which is able to communicate the control chamber and a second valve chamber. The second control port 105 admits fluid of control pressure Pc2. Even further up in the figure, there is disposed a first control port 104 which is able to communicate a first valve chamber 107 and the control chamber. The second control port 104 admits fluid of control pressure Pc1. The second valve chamber and suction passageway 106 communicate each other via a bypassing passageway. In the valve main body 101, a first valve seat is formed on the periphery of the first valve orifice which is located at the interface which communicates a discharge port 103 with the first valve chamber 107 in which the first valve face 102C lifting from or resting on the first valve seat makes opening/closing of the discharge port 103. And the fluid under discharge pressure Pd is allowed to flow into the first valve chamber 107 side from the discharge port 103. Also a second valve seat is formed on the periphery of the second valve orifice of a communication passage port in which the second valve face 102D lifting from or resting on the second valve seat makes opening/closing the passage between the second valve chamber and the suction port 106. The dimension A of the diameter of the discharge port 103 is identical to the dimension C of the diameter of the communication passage port.
In the flow control valve thus configured, the diameters of the first valve orifice and the second valve orifice, which lifts from or rest on the first valve face 102C and the second valve face 102D, respectively, share the same dimension. Therefore the forces exerted to the valve body 102 by the control fluid Pc1 and the control fluid Pc2 negate each other. This implies that the valve body 102 is actuated by means of suction pressure Ps and discharge pressure Pd alone. When the pressure differential between discharge pressure Pd and suction pressure Ps becomes greater than an attraction force determined by the current supplied to the solenoid portion 120, high-pressure valve body 102A opens so as to achieve flow control. In such an operation of the valve body 102, since the diametral dimension D of the high-pressure valve body 102A is greater than the diametral dimension A of the discharge port 103, a decrease in pressure differential between discharge pressure Pd and suction pressure Ps will reduce a pressure-driven retaining force of the valve body, thereby inducing a hunting phenomenon in which the valve body 102 makes pulsating movement in the axial direction because the valve body 102 is easily susceptible to a force due to pulsation or turbulent flow of the fluid under discharge pressure Pd. Occurrence of such hunting phenomenon in the valve body 102 makes it difficult to conduct a flow control. Also as the magnitude (intensity) of the current supplied to the solenoid portion 120 no longer remains proportionate to the operation speed in opening/closing of the valve body 102, a flow control for the fluid under discharge pressure Pd by means of the valve body 102 is likely to deteriorate.
Patent reference 1: Japanese Patent Laid-Open Publication No. 2003-328936 (
The present invention is proposed for alleviating the above mentioned disadvantages, and the technical problem to be solved by the invention is to prevent occurrence of a hunting in the valve body when the valve body makes a valve opening action due to discharge pressure. Another technical problem is to achieve a precise flow control under discharge pressure.
A primary object of the present invention is to solve the above mentioned technical problems, and a solution to such problems is embodied as follows.
Flow control valve of the present invention is a flow control valve for controlling a flow pressure or flow volume of control chamber by regulating fluid flow under discharge pressure. The flow control valve is comprised of a first valve chamber being disposed in a valve main body, a first fluid passage communicating with the first valve chamber and introducing the fluid under the discharge pressure, a valve seat being disposed in the periphery of the valve orifice at the interface between the first valve chamber and the first fluid passage, a second fluid passage communicating with the first valve chamber and discharging the fluid under the discharge pressure, a second valve chamber communicating with the first valve chamber via a guide bore, a third fluid passage communicating with the second valve chamber and introducing or discharging fluid under suction pressure, a valve body being disposed in the first valve chamber and having a valve portion and a shaft portion, in which the valve portion introduces the fluid under the discharge pressure by lifting from or resting on the valve seat, in which the shaft portion fits the guide bore in freely moveable manner, and a solenoid disposing a solenoid rod and making the solenoid rod move in accordance with the current supplied in which the solenoid rod forms a joint with the valve body, wherein a pressure-receiving area of the discharge pressure in the contact interface between the valve portion and the valve seat is arranged larger than a pressure-receiving area of the shaft portion.
The flow control valve of the present invention is comprised of a first fluid passage which communicates with the first valve chamber and introduces the fluid under the discharge pressure, a valve seat which is disposed in the periphery of the valve orifice at the interface between the first valve chamber and the first fluid passage, a second fluid passage which communicates with the first valve chamber and discharges the fluid under the discharge pressure, and a valve body which is disposed in the first valve chamber and has a valve portion and a shaft portion therein, in which the valve portion introduces the fluid under the discharge pressure by lifting from or resting on the valve seat, in which the shaft portion fits the guide bore in freely moveable manner, wherein a pressure-receiving area of the discharge pressure in the contact interface between the valve portion and the valve seat is arranged larger than a pressure-receiving area of the shaft portion. Therefore, a force acted on the valve body is given by F=Pd×B−Ps×A+Pc (B−A), which always operates on the valve body for opening the valve, thereby preventing occurrence of hunting phenomenon in the valve body. Also being able to increase the pressure-receiving area of discharge pressure is advantageous in that the flow capacity of the first fluid passage can be increased and even a compact flow control valve exhibits an outstanding control capability of the control chamber.
[
[
[
[
1 flow control valve
2 valve
2A valve housing (valve main body)
3 first valve chamber
4 second valve chamber
5 first fluid passage
6 second fluid passage
7 third fluid passage
8 flow-in cavity
9 valve seat
10 guide bore
10A joint surface
22 valve body
22A outer circumferential surface
22B valve portion
22C valve face
30 solenoid
31 moveable attraction element
32 fixed attraction element
32A inner circumferential surface
33 coil portion
36 sleeve
37 connecting portion
38 solenoid rod
Described below is the details of the figures of a preferred embodiment in accordance with the principles of the present invention. All the figures explained below are constructed according to actual design drawings with accurate dimensional relations.
Further disposed in the first valve chamber 3 is a second fluid passage 6 which admits the fluid under discharge pressure Pd into a control chamber, not shown. Fluid flowing into the control chamber via the second fluid passage 6 is under control pressure Pc. This second fluid passage 6 should preferably be disposed in plurality which radially span from the center of the first valve chamber 3. There is also disposed a second valve chamber 4 communicating with the first valve chamber 3 via guide bore 10 which extends through the axis of the first valve chamber 3. The second valve chamber 4 disposes third fluid passage 7 for allowing flow-in and flow-out of the fluid under suction pressure Ps. This third fluid passage 7 should preferably be disposed in plurality which radially span from the center of the second valve chamber 4. The guide bore 10 in the valve housing 2A might as well have a slightly larger diametrical dimension than that of the outer diameter surface 22A of the shaft portion so that fluid is allowed to pass through a passageway 13A which is formed between the guide bore 10 and the outer diameter surface 22A. This permits fluid located at one end for flowing through the passageway 13A to the other end due to the pressure differential between suction pressure Ps and control pressure Pc. The passageway 13A forming a small annulus on the periphery of the shaft portion can make the shaft portion aligned in the axial center as the result of the uniform flow formed between the outer diameter surface 22A of the shaft portion and the guide bore 10.
Valve body 22 disposed in the first valve chamber 3 and the second valve chamber 4 has a shaft portion with a cross section area “A” which served as a pressure-receiving area, and disposes a valve portion 22B of diameter “C” in the end portion of the shaft portion. The end tip of this valve portion 22B forms a valve face 22C of a truncated cone shape which lifts from or rests on a first valve seat 9. The other end of the valve body 22 opposite the valve portion 22B forms a recessed conical shape, defining a joint surface 10A. Pressure-receiving area of the joint surface 10A is “A” as well. The passageway 13A formed in the clearance between the shaft portion of this valve body 22 and the guide bore 10 allows the fluid in the first valve chamber 3 under discharge pressure Pd to flow into the second valve chamber 4. Also the shaft portion of the valve body 22 makes a movement under a guidance of the guide bore 1010 and the valve portion 22B opens or closes the valve by lifting from or resting on the first valve seat 9. This valve opening/closing action enables the fluid under discharge pressure Pd to flow from the first fluid passage 5 to the first valve chamber 3.
The solenoid 30 disposes a connecting portion 37 which has a bore-like recessed portion for making a secure engagement with the end portion of the valve housing 2A. The connecting portion 37 is fixed with a casing 35 which contains a coil element 33 therewithin. In the inner circumferential portion of the coil element 33, one end portion of a sleeve 36 is securely fitted between the fixed attraction element 32 and the connecting portion 37 while the other end portion is joined with the inner circumferential surface of the casing 35. In addition, there is disposed a moveable attraction element 31 which fits the inner circumferential surface of the sleeve 36 in freely moveable manner. This moveable attraction element 31 is connected with one end of a solenoid rod 38. The other end surface of the solenoid rod 38 forms a contact with the joint surface 10A of the valve body 22. Also the fixed attraction element 32 arranged in opposing manner against the moveable attraction element 31 is securely fixed inside the sleeve 36 and the connecting portion 37.
And the fixed attraction element 32 gives an attraction force to the moveable attraction element 31 in accordance with the intensity of the current supplied to the coil element 33. The inner circumferential surface 32A of the fixed attraction element 32 forms a clearance fit with the solenoid rod 38. The fluid under suction pressure Ps is introduced to the clearance gap between the inner circumferential surface 32A of the fixed attraction element 32 and the solenoid rod 38 so as to avoid occurrence of pressure imbalance due to suction pressure Ps within the solenoid element. The upper portion shown in the figure of the inner circumferential surface 32A of the fixed attraction element 32 is arranged in a large diameter for receiving a spring 34. The spring 34 always exerts a resilient, urging force so as to keep the moveable attraction element 31 sway from the fixed attraction element 32. Urging force of the solenoid rod 38 is determined as a mutually opposing force resulted from the joint attraction force of the moveable attraction element 31 and the fixed attraction element 32 and the spring force given by the spring 38.
The flow control valve 1 thus configured creates a contact state between the joint surface 10A of the valve body 22 and the end portion of the solenoid rod 38. And the moveable attraction element 31 is attracted toward the fixed attraction element 32 in accordance with the intensity of the current supplied to the coil element 33. The moveable attraction element 31, on the other hand, is resiliently urged by the spring 34 in the opposite direction of the attraction force. This valve body 22 lifts from or rests on the valve seat 9 according to a set force determined by an attraction force given to the moveable attraction element 31 in accordance with the intensity of the current supplied to the coil element 33 and an opposing spring force, thereby opening or closing the valve orifice. If, for instance, the current supplied to the coil element 33 is reduced, then the valve body 22 lifts from the valve seat 9, thereby opening the valve orifice. The fluid under discharge pressure Pd then flows in from the first fluid passage 5, runs through the first valve chamber 3 and flows out to the second fluid passage 6 to become fluid under control pressure Pc. In this case, as the pressure-receiving area “A” of the shaft portion is arranged smaller than the pressure-receiving area “B” at the valve orifice of the first valve chamber 3, the valve body 22 operates based on the force relation (numeral 1) given below as clearly seen from
(numeral 1)
F=Pd×B−Ps×A+Pc (B−A)
where F is a force for closing the valve body,
Pd is discharge pressure,
Pc is control pressure,
Ps is suction pressure,
A is pressure-receiving area of the shaft portion,
B is pressure-receiving area of the valve orifice,
in which the discharge pressure Pd is greater than control pressure Pc and suction pressure Ps when the valve body 22 is in a valve opening action.
And the force “F” given by the solenoid 30 and the forces acted via valve orifices oppose with respect to the valve body 22. Therefore, in case of valve opening action of the valve body 22, occurrence of hunting of the valve body 22 due to the operating fluid can be prevented. In the conventional setting in which the pressure-receiving area “A” of the shaft portion and the pressure-receiving area “B” of the valve orifice have an identical area size, a relation F2=A(Pd−Ps) follows and a pressure change in discharge pressure Pd and suction pressure Ps is likely to cause hunting of the valve body 22. The pressure-receiving area “B” of the valve orifice should preferably be larger than the pressure-receiving area “A” of the shaft portion by the range of from 1% to 20%. The pressure-receiving area “B” of the valve orifice should be determined by considering strength of spring force of the spring 34 as well as magnitude of discharge pressure Pd relative to the pressure-receiving area “A” of the shaft portion.
Application of this flow control valve 1 to a conventional variable displacement compressor will be described next. The variable displacement compressor is so well-known that figure thereof is omitted. Flow-in cavity 8 side of the first fluid passage 5 communicates with a discharge chamber of the variable displacement compressor, not shown. Then the discharge chamber communicates with inside cylinders via discharge lead valve. Also the second fluid passage 6 communicates via communication passage to a control chamber (pressure regulation chamber). Furthermore the third fluid passage 7 communicates with a suction chamber. Within the suction chamber, a swash plate is installed in the rotary shaft in tiltable manner. This swash plate then is connected with individual pistons which are fitted to respective cylinders in freely reciprocating manner. And the angle of the swash plate is varied by regulating the pressure inside the pressure regulation chamber according to discharge chamber Pd, suction chamber Ps and control (pressure regulation chamber) pressure Pc adjusted by means of flow control valve 1, thereby creating reciprocal movement of the pistons. The reciprocal movement of the piston varies a volume within the cylinder. This volumetric change enables the variable displacement compressor to operate under a maximum volume or under a minimum volume. Under this variable displacement operation, hunting induced in the valve body 22 deteriorates precision in flow control. The present invention, however, prevents occurrence of hunting and realizes an accurate operation of the variable displacement compressor.
Construction and operational effect of a mechanical seal device as other embodiment related to the present invention will be described below.
In a flow control valve of the first invention relative to the present invention, a fluid passage is disposed between a shaft portion of the valve body and a guide bore, thereby communicating the first valve chamber with the second valve chamber.
According to the flow control valve of the first invention, the passageway 13A permits fluid to communicate between the first valve chamber 3 (first fluid passage 5) and the second valve chamber 4 (third fluid passage 7). Therefore, a force imbalance acted on the valve body 22 due to control pressure Pc is cancelled so that only a pressure differential between discharge pressure Pd via first fluid passage 5 and suction pressure Ps via third fluid passage 7 can be acted on the valve body 22. Also as the suction pressure Ps is located in the operational portion side with respect to the solenoid 30 and can be delivered to inside the solenoid 30 through the clearance gap between the solenoid rod 38 and the inner circumferential surface 32A of the fixed attraction element 32, unwanted operational force due to suction pressure Ps can be prevented during the action of the solenoid rod 38.
In a flow control valve of the second invention relative to the present invention, a guide bore fittingly guides a shaft portion in freely slidable manner and a passageway is arranged to have a clearance which is formed by chamfering the outer circumferential surface of the shaft portion.
According to the flow control valve of the second invention in which the passageway 13A is formed by chamfering the outer circumferential surface 22A of the shaft portion in the valve body 22, since the shaft portion and the guide bore 10 make a sliding movement under a contact state except on the chamfered portion, fluctuation of the shaft axis can be eliminated by the guide bore 10 guiding the shaft portion. This not only makes it possible to cancel an force imbalance acted on the valve body during the operation of the valve body 22, but also makes the valve portion 22B and the valve seat 9 to achieve precise lifting/resting operations for opening/closing operations of the valve. Therefore flow control as well as pressure control of the flow control valve 1 will be enhanced.
As described so far a flow control valve of the present invention is advantageous in the applications to pneumatic machinery, compressor and the like. It is particularly advantageous as a flow control valve for preventing hunting of the valve body and assuring precise flow control.
Number | Date | Country | Kind |
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2005-112587 | Apr 2005 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2006/307203 | 4/5/2006 | WO | 00 | 10/5/2007 |