JP4303168B2 - Control valve - Google Patents

Description

  The present invention relates to a flow control valve, and more particularly to a control valve for controlling the flow rate of a process gas for semiconductor manufacturing.

In the process gas supply line for semiconductor manufacturing, depending on the application, the gas contact member is not rubber or resin in order to keep the inside of the pipe highly pure and prevent gas adsorption and reduce the occurrence of degassing. It is preferably formed of a metal or a chemically and mechanically stable material such as Al ₂ O ₃ . However, in the control valve, when the orifice and the valve head are made of such materials, it is difficult to ensure the adhesion of the surface, it is easy to generate a leak, and it is difficult to obtain a sufficient closing characteristic. For this reason, it is necessary to close the valve with a strong force, and as a result, a stronger actuator is required. In order to strengthen the actuator, a piezo actuator is generally used (see Patent Document 1). However, the piezo actuator is more expensive than a solenoid actuator, and as a result, metal or the like is used for the valve head. The cost is higher than that using rubber for the valve head.
JP-A-4-34275

  An object of the present invention is to provide a control valve that can obtain sufficient closing characteristics and controllability using an inexpensive solenoid actuator while using metal or the like for a valve head and a valve seat.

  In order to achieve the above object, in the present invention, the contact portion between the valve head and the valve seat is formed of metal or the like and the contact portion is finished flat, and further, the respective surfaces are completely parallel. The valve head has a function to finely adjust the angle of the surface facing the valve seat. A mechanism for adjusting the axial height of the valve head is also provided.

  Furthermore, the present invention has a structure in which a fluid passage is provided in a part of the valve seat surface so that fluid flows in a direction of pushing up the valve head.

Since the present invention is configured as described above, a metal or a chemically and mechanically stable material that does not cause degassing, for example, a valve head and a valve seat such as Al ₂ O ₃ may be used. A relatively inexpensive solenoid coil can be used, and an inexpensive control valve as a whole can be realized. Conventionally, when the inner diameter of the valve seat is increased, it is difficult to obtain a good closing characteristic by securing the parallelism between the valve head and the valve seat surface when using a valve head or valve seat made of metal or the like. Therefore, there is a problem that it is difficult to obtain a large flow rate. According to the configuration of the present invention, since a good closing characteristic can be obtained, the inner diameter of the valve seat can be increased, and a large flow rate valve with a good closing characteristic can be realized.

  Furthermore, generally, when the fluid flow rate increases, the force that the valve head receives due to the flow of fluid increases, and it is difficult to control with a small solenoid with a weak force, and there is a limit to the flow rate that can be flowed. However, since the inflow path to the valve seat as described above is used, fluid flows in so as to push up the valve head from a part of the valve seat during the opening operation. A large flow rate control valve can be realized even with a small solenoid.

  For example, in a valve that flows nitrogen gas of 10 liters per minute, when using a valve seat with an inner diameter of 2 mm, in order to suppress the amount of leakage (leakage) when the valve is closed to 0.01 liters or less per minute, The angle deviation between the valve head surface and the valve seat surface must be within 0.01 degrees. It is extremely difficult to obtain such machine accuracy. However, a solenoid valve with good closing characteristics can be realized for the first time by providing a function capable of adjusting the valve head surface to be completely parallel to the flat valve seat surface as in the configuration of the present invention.

Hereinafter, the present invention will be described in detail by specific embodiments.
FIG. 1 is a front sectional view of the most preferred embodiment of the control valve according to the present invention, and FIGS. 2 to 5 show the configuration of the main parts constituting the control valve of FIG.

The valve portion of the valve 1 includes a valve head 3 made of a metal that is partially flattened and attached to a fluid flow path in the base 2, and a fluid passage that is also partially flattened and formed in the center. And a valve seat 4 made of metal. Thus, by forming the valve head and the valve seat from metal, the occurrence of degassing can be prevented, which is advantageous in a process gas supply line for semiconductor manufacturing. The material of the valve head and the valve seat may be mechanically and chemically stable Al ₂ O ₃ other than metal.

  In FIG. 1, the base 2 has a structure in which both ends are cylindrical and a valve housing recess for housing the valve portion is provided in the middle. In FIG. 1, a fluid inlet 6 is provided at the left end of the base 2, and a fluid inflow passage 7 is connected from the fluid inlet 6 to the valve housing recess. On the other hand, a fluid outlet 8 is provided at the right end of the base 2, and a fluid outlet path 9 is connected from the valve housing recess to the fluid outlet 8.

  As can be clearly seen from FIG. 3, the valve seat 4 has a structure in which a cylindrical member 4b is press-fitted into and integrated with a central hole of a cylindrical valve seat body 4a formed with a plurality of steps. . As shown in FIG. 1, the valve seat 4 is screwed to the base 2 via O-rings 5 and 5 ′ for sealing. In the center of the valve seat body 4a, an axial through hole 4e is formed in three stages from a relatively large diameter portion to an intermediate diameter portion to a small diameter portion. The hollow cylindrical member 4b is press-fitted into the intermediate diameter portion of the central through hole 4e until it comes into contact with the edge of the small diameter portion. The inner diameter of the cylindrical member 4b is made equal to the diameter of the small diameter portion of the through hole in the axial direction of the valve seat body 4a to form a straight through hole. The upper end of the cylindrical member 4b is processed to be a flat mirror surface, and this portion forms a valve seat portion. On the other hand, an annular groove 4d is formed between the outer peripheral wall of the cylindrical member 4b and the large diameter portion of the axial through hole of the valve seat body 4a. Further, the valve seat body 4a is formed with radial through holes 4c (only three direction holes can be confirmed in FIG. 3) from four radial directions perpendicular to each other. A screw is cut on the outer periphery of the lower end of the valve seat body 4a, and the valve seat 4 is screwed into and attached to the base 2 by this threaded portion as described above. The fluid flows in from the radial hole 4c, flows upward through the annular groove 4d, and flows downward through the valve seat portion through the axial through hole 4e.

  As can be seen from FIGS. 1 and 4, the valve head 3 is screwed to one end of the plunger 11 with a disc spring 10 interposed therebetween. The plunger 11 is inserted into the hollow inside of the plunger guide 12 so as to be movable in the axial direction while maintaining a slight gap. The plunger 11 and the valve head 3 are attached to the plunger guide 12 by fixing the disc spring 10 to the lower end of the plunger guide 12 with a spring retainer 13. A yoke main body 14 is press-fitted into the hollow upper end portion of the plunger guide 12 and integrated. As will be described later, the upper end of the yoke body 14 is threaded to adjust the axial position of the yoke. The plunger 11 and the yoke main body 14 are made of a magnetic material for guiding a magnetic force of a solenoid described later. On the other hand, the plunger guide 12 is made of a non-magnetic material so as not to prevent the magnetic field from extending in the axial direction from the yoke body 14 to the plunger 11. Thus, the valve head 3, the plunger 11, the plunger guide 12, and the yoke 14 form an integrated assembly. In the assembly, the plunger 11 and the valve head 3 receive the biasing force of the disc spring 10. The plunger guide 12 can be moved in the axial direction while receiving. Further, the assembly comprising the valve head 3, the plunger 11, the plunger guide 12 and the yoke 14 is fitted into the valve housing recess of the base 2 so that the valve head 3 faces the valve seat 4, and the O-ring 15 is attached. The solenoid case 16 is sandwiched and sealed in a liquid-tight state.

  As shown in FIG. 1, the solenoid case 16 is a cavity whose center penetrates in the longitudinal direction, and a solenoid coil 17 is provided around the cavity so as to surround the cavity. The assembly including the yoke body, plunger guide, plunger, valve head and the like is inserted into the central cavity of the solenoid case 16. The configuration of the upper end portion of the solenoid case is shown in FIG. A solenoid cap 18 is attached to the upper end of the solenoid case 16. The solenoid cap 18 is fixed to the solenoid case 16 by a solenoid cap fixing screw 19. An offset ring 20 is fitted into the inner periphery of the solenoid cap 18. As shown in FIG. 5, the offset ring 20 is fixed by a shaft inclination adjusting screw 21 that is screwed into the solenoid cap from three radial directions. The shaft inclination adjusting screw 21 is used to adjust the inclination of the axis of the assembly including the yoke body, the plunger guide, the plunger, the valve head and the like in a manner described in detail later. A screw is cut in the inner periphery of the offset ring 20, and a valve head height adjusting nut 22 is screwed into the screw. The valve head height adjusting nut 22 is not only threaded on the outer periphery but also on the inner periphery. The pitches of the outer peripheral thread portion and the inner peripheral thread portion of the valve head height adjusting nut 22 are different, and the outer periphery is rough and the inner periphery is fine. The top of the yoke body 14 is screwed into the inner peripheral screw of the valve head height adjusting nut 22. Accordingly, when the valve head height adjusting nut 22 is turned, the assembly consisting of the yoke body, plunger guide, plunger, valve head, etc. is finely adjusted by the difference in pitch between the outer screw and the inner screw of the valve head height adjusting nut. It moves up and down in the direction and the height of this assembly is adjusted. After the height of the assembly is adjusted in this way, the yoke fixing nut 23 is screwed into the valve head height adjusting nut 22 until it comes into contact with the upper end surface of the solenoid cap 18, and the yoke body, plunger guide, The entire assembly comprising the plunger, valve head, etc. is fixed.

Next, with reference to FIG. 2, adjustment of the inclination of the axis of the assembly including the yoke body, the plunger guide, the plunger, the valve head, etc. will be described. Since the present invention is a valve using a metal or a chemically and mechanically stable material, for example, a hard material such as Al ₂ O ₃ for the valve head and the valve seat, the joint surface between the valve seat and the valve head The degree of parallelism is extremely important for leakage and the like. Therefore, in the present invention, a tilt adjusting mechanism using the shaft tilt adjusting screw 21 is provided to ensure the desired parallelism of the joint surface of the valve. As shown in FIG. 5, the inclination of the shaft is adjusted by loosening one of the three shaft inclination adjusting screws 21 supporting the offset ring 20 from three radial directions and tightening the other screw. This can be done by freely changing the inclination of the offset ring 20 in the axial direction. Since the offset ring 20 is fixed to the yoke main body 23 via the valve head height adjusting nut 22, the set of the yoke main body, plunger guide, plunger, valve head, etc. is changed by changing the inclination of the axis of the offset ring 20. The inclination of the axis of the entire solid body changes (θ in FIG. 2), the inclination of the valve head 3 with respect to the valve seat 4 changes, and the parallelism of the joint surfaces of both can be adjusted accurately. Thus, after the inclination of the axis is adjusted, the shaft inclination adjusting screw 21 is locked, and the height of the valve head is adjusted by the valve head height adjusting nut 22 as described above, and the yoke fixing nut 23 is adjusted. The height is also fixed by.

  In the control valve assembled and adjusted as described above, when the solenoid coil 178 is energized, the plunger 11 is lifted toward the yoke body 14 against the biasing force of the disk spring 10 and the valve head 3. 1 moves away from the valve seat 4 and fluid flows from the fluid inlet 6 through the valve (gap between the valve head 3 and the valve seat 4) to the fluid outlet 9 as shown by the arrow in FIG. The degree of opening of the valve can be controlled according to the magnitude of the supply voltage to the solenoid coil, and both controlled fluids can flow.

  Furthermore, in the present invention, as already described with reference to FIG. 3, in addition to the function of adjusting the shaft inclination and height, the annular groove 4d coaxial with the valve seat surface is formed in the valve seat 4 before fluid enters the valve seat surface. It is set as the flow-path structure which once made the fluid go upwards via. In general, when the fluid flow rate increases, the force that the valve head receives due to the fluid flow increases, and there is a limit to the flow rate that can be flowed by a small solenoid with a weak force. However, in the valve of the present invention, during the opening operation, fluid flows in so as to push up the valve head from the coaxial outer peripheral portion and flows out toward the center hole. A large flow rate control valve can be realized even with a small solenoid. Further, a passage may be added to the base 2 that directly guides the fluid that has flowed so as to push up the valve head from the coaxial outer peripheral portion to the fluid outlet.

  The parallelism adjusting mechanism of the valve body and the valve seat shown in the present embodiment is the same for a valve head made of another material partially flattened other than metal or the like and a control valve for the valve seat. Needless to say, it is effective.

  The present invention is particularly effective for controlling the flow rate of a process gas for semiconductor manufacturing in which the occurrence of degassing is not preferable. However, the present invention is not limited to this, and can be effectively used for flow rate control of any fluid.

It is front sectional drawing of the most preferable embodiment of the control valve of this invention. It is explanatory drawing of the axis-line inclination adjustment mechanism of the yoke axis | shaft in the control valve of FIG. It is the top surface and side sectional drawing of the valve seat in the control valve of FIG. FIG. 2 is an exploded view of a yoke portion, a plunger portion, and a valve head in the control valve of FIG. 1. It is an exploded view of the solenoid case upper part in the control valve of FIG.

Explanation of symbols

1 valve, 2 base, 3 valve head,
4 valve seat, 4a valve seat body, 4b cylindrical member,
4c radial through hole, 4d annular groove, 4e axial through hole,
5, 5 ′ O-ring, 6 fluid inlet, 7 fluid inlet,
8 Fluid outlet, 9 Fluid outlet, 10 Disc spring,
11 Plunger, 12 Plunger guide, 13 Spring retainer,
14 Yoke body, 15 O-ring, 16 Solenoid case,
17 solenoid coil, 18 solenoid cap,
19 Solenoid cap fixing screw, 20 Offset ring,
21 Shaft tilt adjusting screw, 22 Valve head height adjusting nut 23 Yoke fixing nut

Claims (5)

A plunger driven by a magnetic force of a solenoid, a hollow guide portion that accommodates the plunger so as to be movable in an axial direction, a yoke portion that guides the magnetic force of the solenoid to the plunger, and the plunger is elastic with respect to the yoke portion A disc spring to be held, a valve head fixed to the plunger via the disc spring and partially flattened, and a seal surface facing the valve head and partially flattened A fluid flow control valve having a valve seat,
E Bei angle adjustment mechanism which can arbitrarily adjust the angle of the valve head surface against the valve seat sealing surface,
The angle adjusting mechanism is configured to adjust the angle of the valve head surface by adjusting the inclination of the axis of the yoke portion from a direction perpendicular to the axis of the yoke portion. Control valve.   The control valve according to claim 1,
  The control valve is configured such that the angle is adjusted by adjusting screws from a plurality of radial directions at an end portion of the yoke portion.   The control valve according to claim 1 or 2,
  The fluid control valve further provided in the valve head height adjustment mechanism which adjusts the clearance of the valve head with respect to the said valve seat.   The control valve according to claim 3,
  A control valve in which the valve head height adjusting mechanism is adjusted by turning an adjusting nut that is screwed with a screw portion provided along an axial direction at the yoke end portion.   The control valve according to claim 1,
  The valve seat has a fluid flow path formed of an annular groove concentrically with the fluid flow path provided at the center of the valve seat and around the fluid flow path at the same center. valve.