JPS6148684A - Rotary type multiposition valve - Google Patents

Abstract

PURPOSE:To float-up and lightly revolve a main valve piece by allowing a pilot valve to release the pressure on the upper surface of the main valve piece before the main valve piece is revolved stepwise by pulse signals. CONSTITUTION:When a plunger 5 is pulled-up by the electric pulse signals, a needle valve body 12 is raised to open a pilot valve, and the space over the upper surface of a main valve piece 3 is connected to a low-pressure port 2D, and the pressure over the upper surface of the main valve piece is released, and the fluidic pressure applied onto the loer part of the main valve piece pushes-up the main valve piece 3. Then, a pin 7 installed onto the plunger 5 revolves the plunger 5, led on the aslant surface part of the teeth of a guide installed onto the periphery of the plunger 5, and the floated-up main valve piece 3 is revolved. When the supply of the signal is cut-off, and the plunger 5 returns, the pilot valve is closed, and the main valve piece 3 is pushed onto the bottom surface of a body 1.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a valve that can be used for switching the flow path of pressure fluid, controlling the flow rate, etc., and particularly relates to a rotary valve that uses a novel step-type electromagnetic drive device.

Conventional technology Various types of control valves have traditionally been used to switch the flow path and control the flow rate of pressure fluids, but with the recent development of automatic control systems, control valves are driven by electric No. 4B. The number of cases in which this is done is increasing.

As a flow path switching valve for electric remote control, an electric VA valve is often used for small capacity, and a fluid pressure driven valve equipped with an electromagnetic pilot valve is used for large capacity. A solenoid valve attracts a plunger by energizing a solenoid, and this force causes the valve body to slide through a bushing pin, etc., but it is possible to switch between 2 or 3 positions using two solenoids or a combination of a solenoid and a spring. is normal. In addition, in a pilot-operated valve, the pressure of the fluid switched as described above is applied to a piston or the like, so that the valve body is moved smoothly through a stroke with a single strong force. However, although these electromagnetic valves are generally suitable for two- or three-position switching, they are not suitable for multi-position switching or continuous flow control.

Furthermore, most flow rate control valves for electrical remote control are so-called electrically operated valves that use a motor and a speed reducer to rotate or move the valve body in the axial direction.

This kind of electric valve is a valve with a conventional structure that is equipped with a driving motor, and although it can be electrically operated regardless of the valve structure or capacity, it is generally The disadvantage is that the parts are large and heavy, making it uneconomical.

Problems to be Solved The present invention is a small valve operated by an electric signal, which eliminates the above-mentioned drawbacks of solenoid valves and electric valves, such as their limitations in use and their large size and weight. The purpose is to provide a new rotary valve.

The purpose of the present invention is to use a snap-type electromagnetic actuator using a solenoid to lift a rotary piston-type valve body from a surface using fluid pressure. This is achieved by adopting a new actuation method in which the port is then rotated by an actuator and then pressed against the port surface by fluid pressure.

That is, the valve of the present invention has a fluid passage provided at the rotational axis position. The body and an electromagnetic actuator configured to generate rotational force around the axis when the plunger is attracted in the axial direction are coaxially coupled, and the electromagnetic actuator is provided at the upper open end of the fluid passage and the tip of the plunger. The pilot valve releases the pressure on the surface of the main valve body before the main valve body rotates stepwise in response to a pulse signal. The main valve body is configured to float above the port surface by reversing the pressure applied to the lower part of the valve body.

The rotary piston type main valve body in the valve of the present invention is formed into an appropriate shape so that its lower part can block part or all of the ports provided in the body. The middle part can rotate in contact with the body via the piston ring.
), it is formed into an almost cylindrical shape, and the upper part is provided with a coupling part that receives the rotational force of the actuator, and furthermore, a fluid passage is provided in the center along the rotation axis from the upper surface to the lower surface. There is.

In addition, the body has a roughly cylindrical valve chamber for accommodating the piston-type main valve body as described above, and a port is provided on the bottom or side of the valve chamber, but at least the port is located at the center of the bottom. A low pressure port is provided to open to.

The actuator for rotating the main valve body of a valve constructed in this way is attached to the end of a plunger which can be moved a short distance in the axial direction by being attracted by a solenoid and can be rotated about its own axis. A pin is arranged in line with the axis and protrudes in a perpendicular direction, a pair of serrated guides are provided facing each other around the plunger, and the pin is positioned between the serrated guides, and the plunger is moved in the axial direction. The structure is such that rotational force is generated in only one direction as a result of the rotation.

Furthermore, a needle valve body is provided at the tip of the plunger of the actuator, and the upper opening end of the fluid passage of the main valve body and the needle valve body form a piezoelectric valve F structure. ing.

Operation Since the valve of the present invention is constructed as described above, normally when fluid pressure is applied, the entire piston-type main valve body is pressed against the port surface on the bottom of the body. When the actuator is actuated by an electrical pulse signal and the plunger is pulled back, the needle valve body first opens at -L and the valve opens, and the space above the main valve body communicates with the low pressure port. As a result, the pressure on the top surface of the main valve body is released, and the fluid pressure applied to the bottom of the main valve body pushes up the main valve body.Subsequently, the pin provided on the plunger engages the teeth of the guide provided around the plunger. The plunger is rotated by being guided by the slope, and the rotational force at this time is applied to the upper part of the main valve body.
It is transmitted to the connecting part with the actuator, which rotates the floating main valve body. When the Nocruz Counter is finished, the Pyro Notopr is closed again at the same time as the main valve body, so high pressure fluid leaks from the supply port through the gap between the piston rings around the main valve body and enters the upper surface of the gap 1. As a result, the main valve body becomes even more pressed against the port surface on the bottom of the body.

In this way, the main valve body rotates depending on the number of teeth on the guide depending on the number of pulses, but the upper part of the main valve body rotates depending on the number and arrangement of ports provided on the bottom or side of the body. Since it is formed in a shape that allows some or all of these to be blocked, as the main valve body rotates, the ports are sequentially throttled and closed, or the ports are switched and further closed. .

When using the valve of the present invention for flow control, it is necessary to select the most appropriate shape and number of ports and the shape of the lower part of the main valve body depending on the purpose. It is essentially a multi-stage process.

Fig. 1 shows an example in which the multi-position valve according to the present invention is used as a three-way switching valve.

Supply port 2A on the bottom side of body 1, switching ports 2B and 2C1 on the bottom, and low pressure side port 2D in the center of the bottom.
A screw type main valve body 3 is rotatably fitted into the valve chamber.

A plunger 5, which is constantly pressed upward by a plunger spring 6, is inserted into a central space of a solenoid 4 attached above the body 1. A pin 7 is installed at the bottom of the plunger 5, passing through the plunger laterally, and the protruding portion of this pin is located between the upper guide 8 and the lower guide 9, and limits the movement of the plunger 5. There is. Further, the protruding portion of the pin 7 is freely engaged with a slotted groove 10, which is a connecting portion provided at the -L portion of the main valve body 3, so that only the rotational movement of the plunger 5 is caused by the rotation of the main valve body 3. It is now possible to convey the information to (Fig. 2) An upper guide 8 and a lower guide 9 for restricting the movement of the pin 7 and converting vertical movement into rotational movement are attached to the inside of the upper part of the body 1 by wrapping the lower part of the plunger 5 with iQ. The opposing portions of the guide are serrated.

The positional relationship between the teeth of the guides 8 and 9 and the pin 7 is shown in FIG. 5 on a plane. When the brush jar 5 is attracted by the solenoid 4, the pin 7 slides along the slope of the teeth of the upper guide 8 and is sent about half a mountain to the right, and then when the plunger 5 is pushed back by the plunger spring G, the pin 7 slides along the slope of the teeth of the upper guide 8. 7 is sent to the right by the remaining single items while sliding along the slope of the teeth of the lower guide 9. In this case, the number of teeth on the guide is 12, or every 302, around the entire circumference, so each time a pulse signal is given to the solenoid 4, the plunger 5 is moved by 3-0". It will rotate.

- As described above, a needle valve body 12 is attached to the lower end of the plunger 5 of the electromagnetic actuator formed with a G-tube so as to be pushed downward by a needle valve spring 13, while the main Jr body 3 is attached to the lower end of the plunger 5. A fluid passage (1ffl) 1 is provided extending along the rotation axis from the upper surface to the lower surface.

And fluid communication till'.

The end portion and the needle valve body 12 constitute a pyrosotobur. A piston ring 14 is fitted into the main valve body 3 to prevent pressure fluid from leaking to the two surfaces of the main valve body, so as not to prevent the main valve body from floating and rotating.

15 is a hair ring ball, which is numbered in order to minimize the amount of floating of the main valve body 3 and to ensure that the main valve body rotates in a raised state.

FIG. 6 shows the opening/closing relationship of the ports as the main valve body 3 rotates in this example valve. As mentioned above, since the actuator rotates 30 degrees with one pulse, the main valve body also rotates once with 360 degrees. However, port 2B and port 2C are in symmetrical positions, and there are two states: a fully open state where fluid supplied from the two ports flows to both port 2B and port 2C, and a state where fluid flows to either port 2B or port 2C. , fully closed 4
The state of the seeds can be changed in 360 degrees.

- Also, a low pressure port is located at the center of the bottom of the valve chamber of the body ■.
1-2D is open, and the fluid passage 1 in the main valve body is connected to the low pressure port 2D regardless of the rotational position of the main valve body 30.

- When an electric pulse signal is applied to the valve configured in this way, the plunger 5 is attracted by the solenoid 4, the needle valve body 12 is also pulled, and the pilot valve opens. Therefore, the pressure on the upper surface of the main valve body 3 is removed, and the fluid pressure applied to the lower part of the main valve body causes the main valve body to float, allowing fluid to flow through the gap between the port surface and the lower surface of the main valve body. This, together with the effects of the piston ring 14 and the pawl, helps to rotate the main valve body 3 very lightly. Next, when the signal is cut off and the plunger 5 returns, the pilot valve on the top surface of the main valve body closes and the main valve body also closes, and then the fluid leaking from around the piston ring 14 flows to the top surface of the main valve body and enters the upper space. This increases the pressure on the main valve body, thereby further pressing the main valve body against the bottom of the body and stopping fluid leakage from the port surface.

Furthermore, by changing the communication between the valves I and I without changing the shape of the main valve body, it is possible to form a valve t for switching the flow rate into two stages. An example of such a port configuration is shown in FIG.

22 inlet ports in the body 21 and the bow 1 on the bottom
22B, 22C and 22D are all connected to the same outlet 23 at the bottom of the body 21. Therefore, the flow rate of the outlet 23 is switched in two stages: when it passes through both ports 1-22B and 22C, and when it passes through either port 22B or 22C.

Furthermore, Fig. 4 shows examples of valve port shapes and main valve body shapes suitable for switching the flow rate in multiple stages. Although this valve switches the flow rate in multiple stages, fine adjustment can be made by increasing the number of teeth on the guide of the step type actuator.

In this way, the valve of the present invention has the shape of the main valve body and the shape of the bow.
By selecting and combining various arrangements and shapes of ~, switching It or flow rate control valves with various characteristics can be obtained.

811. <As explained above, the rotary multi-position valve of the present invention rotates a piston-type main valve body by a step-type actuator with a short stroke of a pulse-driven plunger, and rotates a piston-type main valve body by a pilot valve. By temporarily reversing the pressure applied to the top and bottom of the main valve body, the main valve body can be floated and rotated lightly.

The pulse-driven step-type actuator used in the rotary multi-position valve of the present invention has the features of being cooperative and compact because the plunger stroke is short, and because it is driven by a pulse signal, the temperature rise is small and it is energy-saving. In addition, the rotary piston type main valve body rotates with little friction, making it even more compact, and the valve has extremely good durability. The valve of the present invention has the advantages of not having to provide an adjustment mechanism, having a simple structure, being small and economical, and being applicable to various uses, especially It is suitable as a valve for use in remote control systems in place of conventional electric valves and electromagnetic valves.

[Brief explanation of the drawing]

- Fig. 1 is a longitudinal cross-sectional view of a three-way switching goose which is an embodiment of the U-tally set multi-position valve according to the present invention, and Fig. 2 shows the joint between the pin and the valve body - FIG. 3 is an explanatory diagram.
FIG. 4 is a diagram showing the shape of a port and a valve body in another example of a flow rate switching valve. FIG. 5 is a diagram for explaining the positional relationship between the guide and the bottle, and FIG. 6 is a diagram for explaining the rotational positional relationship between the port and the valve body.

Claims (1)

[Claims] A rotary piston type main valve body with a fluid passage provided at the rotation axis position, a body provided with at least a low pressure port at the center axis position of the port surface where the bottom surface of the main valve body contacts, and a plunger that is sucked in the axial direction. An electromagnetic actuator configured to generate rotational force around an axis is coaxially coupled, and the upper open end of the fluid passage and the needle provided at the tip of the plunger form a pilot valve structure. The pilot valve releases the pressure on the top surface of the main valve body before the main valve body rotates stepwise in response to a pulse signal, thereby reversing the pressure applied to the top and bottom of the main valve body and porting the main valve body. A rotary multi-position valve characterized by being configured to float above a surface.