KR200463508Y1 - 3 port piezoelectric valve - Google Patents

Abstract

It is an object of the present invention to provide a three-port piezoelectric valve having a structure in which it is easy to improve the operation accuracy of the valve and to downsize the entire valve.
In order to achieve the above object, the three-port piezoelectric valve of the present invention includes: a valve body having a supply port, an exhaust port, and a load port formed to allow fluid to enter and exit, and a valve space communicating with the supply port, the exhaust port, and the load port; A spool slidably installed in a valve space of the valve body and having a valve flow path formed to connect the supply port and the load port or the load port and the exhaust port according to a sliding position with respect to the valve body; An elastic member disposed in a valve space of the valve body to provide an elastic force to the spool such that the spool slides along the valve space; A plunger installed on the valve body so as to contact the spool and sliding the spool to a position where the valve flow path of the spool connects the supply port and the load port or the load port and the exhaust port; And a piezoelectric actuator installed in the valve body and connected to the plunger to operate to push or pull the plunger by a piezoelectric element.

Description

3 PORT PIEZOELECTRIC VALVE

The present invention relates to a three-port piezoelectric valve, and more particularly to a three-port piezoelectric valve for opening and closing the port of the valve by operating the valve using a piezoelectric element.

Directional control valves for controlling the flow of fluid in pneumatic or hydraulic circuits are well known. A slide spool valve is generally used for the directional valve, and a solenoid is generally used to operate the spool.

The three-port solenoid valve, which is one of the directional control valves, is generally used to change the direction of movement of a pneumatic or hydraulic actuator in two sets, and is widely applied as a pilot valve for operating other large flow control valves.

However, the solenoid valve is inadequate to be used for applications requiring precise operation because the slide spool moves along a hysteresis curve even when the slide spool does not move linearly. In particular, in the case of connecting a plurality of valves to form a pneumatic circuit and connecting the valves to operate at a high speed, the nonlinear operating characteristics of the solenoid valve cause a decrease in the operating performance and accuracy of the entire pneumatic circuit. In addition, since electromagnetic force generated in the solenoid may act on other adjacent valves, it causes a malfunction of the pneumatic circuit.

In addition, since the coil is used to generate the electromagnetic force by the solenoid, there is a problem in that the volume of the valve is large, and it is difficult to miniaturize.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a three-port piezoelectric valve having a structure that is easy to improve the operation accuracy of the valve and to downsize the entire valve.

In order to achieve the above object, the three-port piezoelectric valve of the present invention includes: a valve body having a supply port, an exhaust port, and a load port formed to allow fluid to enter and exit, and a valve space communicating with the supply port, the exhaust port, and the load port; A spool slidably installed in a valve space of the valve body and having a valve flow path formed to connect the supply port and the load port or the load port and the exhaust port according to a sliding position with respect to the valve body; An elastic member disposed in a valve space of the valve body to provide an elastic force to the spool such that the spool slides along the valve space; A plunger installed on the valve body so as to contact the spool and sliding the spool to a position where the valve flow path of the spool connects the supply port and the load port or the load port and the exhaust port; And a piezoelectric actuator installed in the valve body and connected to the plunger to operate to push or pull the plunger by a piezoelectric element.

The three-port piezoelectric valve of the present invention has an advantage that the operation accuracy is improved because the operation is linear without the solenoid and malfunction does not occur even when a plurality of the connection is used.

In addition, since the three-port piezoelectric valve of the present invention does not have a solenoid composed of a coil, there is an advantage that it is easy to downsize the valve.

1 and 2 are cross-sectional views for explaining an embodiment of a three-port piezoelectric valve according to the present invention.
FIG. 3 is a perspective view illustrating a portion of the three port piezoelectric valve shown in FIG. 1.

Hereinafter, an embodiment of a three-port piezoelectric valve according to the present invention will be described with reference to the accompanying drawings.

1 and 2 is a cross-sectional view for explaining an embodiment of a three-port piezoelectric valve according to the present invention, Figure 3 is a perspective view showing a part of the three-port piezoelectric valve shown in FIG.

1 and 2, the three-port piezoelectric valve of this embodiment includes a valve body 10, a spool 20, an elastic member 30, and a plunger 40.

Three ports are formed in the valve body 10. The three ports are divided into supply port P, load port A and exhaust port R, respectively. The supply port P is connected to an air pump or accumulator, which is a conventional pneumatic generator, to receive compressed air. The load port A is connected to an actuator such as an air cylinder or a pilot port of another valve to output or recover compressed air. The exhaust port R is for exhausting the compressed air recovered through the load port A to the outside.

A cylindrical valve space 13 is formed in the valve body 10, and a spool 20 is disposed in the valve space 13. The valve space 13 is formed to communicate with the supply port P, the exhaust port R, and the load port A. FIG.

The spool 20 is formed in a cylindrical shape and is installed to be slidably movable in the valve space 13 of the valve body 10. A valve flow passage 21 is formed in the spool 20 as shown in FIG. 3, and the valve flow passage 21 has a supply port P and a load port A depending on the position in the valve space 13. It is formed to connect the load port A and the exhaust port R.

The valve body 10 and the spool 20 may be formed of a metal material, and the valve space 13 and the spool 20 may be formed between the valve space 13 and the spool 20 rather than installing an O-ring for airtight airtightness. It is advisable to process the dimensional tolerances between 20) to 2 to 4 µm.

An elastic member 30 formed of a coil spring is provided between the spool 20 and the valve body 10 in the valve space 13. The elastic member 30 provides an elastic force to push the spool 20 to the right relative to the valve body 10 with reference to FIG. 1.

Guide grooves 22 are formed along the longitudinal direction of the outer surface of the spool 20, and the guide pin 11 is installed in the valve body 10 so as to protrude into the valve space 13, and a part of the guide groove 22 is formed in the valve body 10. It is arranged to be received in the groove 22. The guide pin 11 and the guide groove 22 prevent the spool 20 from rotating in the valve space 13 while allowing the spool 20 to slide in the longitudinal direction with respect to the valve space 13. Done.

One side of the valve body 10 is provided with a piezoelectric actuator 50, the plunger 40 is connected to the piezoelectric actuator 50. The plunger 40 is arranged in contact with the spool 20. As the piezoelectric actuator 50 operates, the plunger 40 moves forward or backward, and the spool 20 slides in the valve space 13 according to the operation of the plunger 40.

The piezoelectric actuator 50 is extended or contracted according to the polarity of the power applied by the operation of the piezoelectric element. That is, as the piezoelectric element expands or contracts, the plunger 40 connected to the piezoelectric actuator 50 moves to connect the supply port P and the load port A, or connect the load port A and the exhaust port R with each other. Will be connected.

The push button 60 is installed in the valve body 10. Referring to FIG. 1, the push button 60 has a button body 61 and a spring 62. The button body 61 is installed to be able to move forward and backward with respect to the valve body 10, and the spring 62 provides an elastic force to push the button body 61 out of the valve space 13. The end of the spool 20 is tapered to form a slope as shown in Figure 3, and the inclined portion 23 of the spool 20 at the position where the spool 20 is advanced toward the push button 60 The button bodies 61 of the push button 60 are configured to contact each other. At this time, when the button body 61 is pressed, the inclined portion 23 of the spool 20 is pushed against the button body 61 so that the spool 20 moves backward with respect to the valve space 13.

Hereinafter, the operation of the three-port piezoelectric valve configured as described above will be described.

When the piezoelectric element is extended by applying power to the piezoelectric actuator 50, the plunger 40 is advanced toward the spool 20. Pushed by the plunger 40, the spool 20 also moves along the valve space 13 in a direction away from the piezoelectric element, and the elastic member 30 contracts. When the spool 20 moves along the valve space 13, the guide pin 11 is inserted into the guide groove 22 of the spool 20, so that the spool 20 is prevented from rotating relative to the valve space 13. It moves to the state. When the spool 20 moves to the left end of the valve space 13, the load port A and the exhaust port R are connected to each other by the valve flow path 21 and compressed from the exhaust port R to the load port A. Air flows and the supply port P is closed by the spool 20.

When the direction of the power applied to the piezoelectric actuator 50 is reversed, the piezoelectric element contracts and pulls the plunger 40. When the plunger 40 moves to the right, the spool 20 slides to the right of the valve space 13 by the elastic force of the elastic member 30. Accordingly, the exhaust port (R) is closed by the spool 20 and the supply port (P) and the load port (A) are connected to each other while pneumatic pressure is supplied to the load port (A).

When the piezoelectric actuator 50 does not operate due to a power failure or other reason, when the button body 61 of the push button 60 is pressed, the inclined portion 23 of the spool 20 is pushed by the button body 61 and the spool is pushed. 20 moves to the left. When the spool 20 moves to the left end of the valve space 13, the supply port P is closed by the valve flow path 21, and the load port A and the exhaust port R are connected to each other.

Since the spool 20 is moved by the piezoelectric actuator 50, such a three-port piezoelectric valve has an excellent operating performance as compared to a valve using electromagnetic force by a conventional solenoid. Since the solenoid operates by drawing a hysteresis curve, the spool movement has a nonlinear problem. For this reason, if a plurality of such solenoid valves are connected to form a pneumatic circuit, such a problem often occurs when malfunction occurs frequently and operates at high speed. However, in the case of a three-port piezoelectric valve according to the present invention, a solenoid Piezoelectric actuators are used without using coils, so this problem does not occur. In addition, since the piezoelectric actuator is more easily downsized than the solenoid, the three-port piezoelectric valve of the present invention has an advantage of being smaller than the conventional three-port valve.

On the other hand, the valve body 10 and the plunger 40 are each formed of a metal material, the dimensional tolerance is preferably 2 ~ 4 ㎛ between the valve space 13 and the plunger 40 without the O-ring is installed. If the dimensional tolerance between the valve space 13 and the plunger 40 is smaller than 2 μm, the space between the valve space 13 and the plunger 40 may be so small that much energy required to move the valve may be required. . If the dimensional tolerance between the valve space 13 and the plunger 40 is larger than 4 μm, air pressure may leak into the space therebetween, thereby lowering the operation efficiency of the valve.

As described above, when the plunger 40 is formed of a metal material, it is easier to process the plunger 40 with higher precision than the synthetic resin material, and there is an advantage of improving the operation performance of the valve. In addition, when the O-ring is installed between the plunger 40 and the valve space 13, as the O-ring wears over time, the operation performance of the valve may be degraded. Since the operating performance of the valve is kept constant, the service life is extended.

As described above with reference to a preferred embodiment for the three-port piezoelectric valve according to the present invention, the scope of the present invention is not limited to the form described and illustrated above.

10: valve body 20: spool
30: elastic member 40: plunger
50: piezoelectric actuator 60: push button

Claims (4)

A valve body having a supply port, an exhaust port, and a load port formed to allow fluid to enter and exit, and a valve space communicating with the supply port, the exhaust port, and the load port;
A spool slidably installed in a valve space of the valve body and having a valve flow path formed to connect the supply port and the load port or the load port and the exhaust port according to a sliding position with respect to the valve body;
An elastic member disposed in a valve space of the valve body to provide an elastic force to the spool such that the spool slides along the valve space;
A plunger installed on the valve body so as to contact the spool and sliding the spool to a position where the valve flow path of the spool connects the supply port and the load port or the load port and the exhaust port; And
And a piezoelectric actuator installed in the valve body and connected to the plunger to operate to push or pull the plunger by a piezoelectric element.
The valve space of the valve body is formed in a cylindrical shape, provided with a guide pin protruding into the valve space,
The spool is formed in a cylindrical shape, the three-port piezoelectric valve, characterized in that the guide groove for receiving the guide pin of the valve body is formed along the longitudinal direction. delete The method of claim 1,
And a push button installed in the valve body to push the spool into and out of the valve space according to a push operation. The method of claim 3,
The valve body and the spool is made of a metal material, the O-ring (O-ring) is not installed between the spool and the valve body, the three port characterized in that the tolerance between the valve space and the spool is 2 ~ 4 ㎛ Piezoelectric valve.

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