KR102205867B1 - Multi check valve - Google Patents

Abstract

The present invention is a multi-check valve that prevents reverse flow of fluid flowing in one direction and can quickly shut off in case of an emergency, and is formed on a valve body, a flow path communicating with the valve body and receiving hydraulic oil, and at one side of the flow path. A regulator including an opening and closing port through which hydraulic oil is input and discharged, a pressurizing part installed at an end of the flow path and pressurizing the hydraulic oil, a valve seat separating an inflow space and an outflow space in the valve body, and one end of the valve seat The other end includes a disk having a protrusion formed therein to be accommodated in the flow path, an outer circumferential surface in close contact with the inner circumferential surface of the flow path, a cylinder disk having a through hole receiving the protrusion, and a spring installed between the disk and the cylinder disk. It characterized in that it includes.

Description

Multi check valve

The present invention relates to a multi-check valve, and more particularly, to a multi-check valve capable of preventing reverse flow of fluid flowing in a unidirectional direction and quickly shutting off in case of an emergency.

In general, a valve refers to a device that controls the flow rate, flow rate, pressure, etc. of a fluid flowing in a pipe. In particular, a check valve is a valve that flows in only one direction and blocks the flow in the opposite direction. valve).

Check valves are installed in water pipes of apartments, officetels, and houses, and are used to prevent reverse flow of tap water through the water pipes.

As an example of such a conventional check valve, a valve seat, which is a boundary between an inlet and an outlet, is provided in the middle of the passage, and the valve body has a body portion having a through hole formed to guide the shaft above the valve seat, and the through hole of the body portion penetrates. A structure including a shaft that slides and is integrally fixedly coupled to the lower end of the shaft and provided with a seat contact portion for opening and closing the valve seat at the bottom thereof, and a spring disposed between the disk and the body to elastically support the disk. It is made into.

The shaft has a locking jaw formed on the outer circumferential surface of the shaft, and the disk is held on the locking jaw so that the disk is fixed to the shaft through a fastener such as a washer and a nut in a state in which the sheet contact portion is disposed on the bottom of the locking jaw.

In the check valve of the prior art according to this structure, the shaft is penetrated through the through hole of the body part, the disk is integrally fixed at the lower end thereof, and the seat contact part of the body part is in close contact with the valve seat through the spring between the disk and the body part When the valve is closed and high pressure is generated from the inlet side, the disk is pushed upward and the valve seat is opened and the fluid flows to the outlet.

At this time, the disk that is pushed upward by the pressing force of the fluid is in a state of having an elastic repulsive force by the spring.

Then, when the pressing force of the fluid is released, the disk is pushed back to its original state by the repulsive force of the spring and the valve seat is sealed to block the flow of the fluid.

In this way, in the check valve of the prior art, the valve seat is opened only by pressurization from the inlet side, and the flow in the reverse direction can be completely blocked.

On the other hand, since the check valve of the prior art as described above has a structure in which the disk is integrally fixed to the shaft, it is necessary to form a locking protrusion on the shaft and provide a separate fastener. Accordingly, there is a problem of an increase in cost, and there is a problem in that it is not possible to control the flow rate of the fluid according to the error range of the set value occurring in the manufacturing process of the spring.

Korean Patent Laid-Open Patent No. 10-2011-0073954 "Check Valve" (Publication date: 2011.06.30.)

The present invention was conceived to solve the above problems, and the structure is simple as the disk is in close contact with and spaced apart from the valve seat through the pressure of the hydraulic oil, and a minute error according to the elastic modulus of the spring is adjusted by the pressure of the hydraulic oil. Its main purpose is to provide a multi-check valve that can compensate for the error range of the spring.

The multi-check valve according to the present invention includes a valve body, a flow path communicating with the valve body and receiving hydraulic oil, an opening and closing opening formed on one side of the flow path through which hydraulic oil is injected and discharged, and installed at an end of the flow path to pressurize hydraulic oil. A regulator including a pressurizing part to allow, a valve seat separating an inflow space and an outflow space in the valve body, a disk having a protrusion formed at one end to be in contact with the valve seat, and at the other end to be accommodated in the flow path, and an outer circumferential surface It characterized in that it comprises a cylinder disk in close contact with the inner circumferential surface of the flow path and having a through hole in which the protrusion is accommodated, and a spring installed between the disk and the cylinder disk.

In addition, the multi-check valve is characterized in that it further comprises a packing member provided on the outer peripheral surface of the cylinder disk and the outer peripheral surface of the pressing portion.
In addition, the flow path further includes an upper flow path which is located on the upper part of the valve body and is installed so as to seal a pressing part on one side, and a connection flow path connected to the upper flow path and connected to the through hole, and It characterized in that the packing member is additionally installed at a position where the inner circumferential surface of the upper flow path is in close contact.

In the multi-check valve according to the present invention, when the pressure of the fluid is greater than the pressure of the hydraulic oil, the hydraulic oil moves the cylinder disk in the direction in which the spring is compressed while the disk is spaced apart from the valve seat, and the pressure of the hydraulic oil and the pressure of the spring are the same. When the disk is stopped, the fluid can flow between the valve seat and the disk, thereby providing an effect of preventing the occurrence of backflow of the fluid.

In addition, an opening and closing opening through which hydraulic oil is input and discharged is formed in the flow path, and when reverse flow occurs because the pressure in the outlet space is higher than the pressure in the inlet space, the valve seat and the disk are quickly separated by opening the opening and discharging the hydraulic oil to the outside. It provides the effect of discharging the fluid at maximum pressure.

In addition, a packing member is provided on the outer circumferential surface of the cylinder disk and the outer circumferential surface of the pressing unit to provide an effect of preventing the hydraulic oil from being discharged from the inside of the flow path.

1 is a cutaway perspective view showing a multi-check valve according to an embodiment of the present invention.
2 is an exemplary view showing a state in which the inflow space and the outflow space are closed in the disk of the present invention.
3 is an exemplary view showing a state in which the inflow and outflow spaces of the disk of the present invention are opened.

Hereinafter, the technical idea of the present invention will be described in more detail using the accompanying drawings.

The accompanying drawings are only an example shown to describe the technical idea of the present invention in more detail, so the technical idea of the present invention is not limited to the form of the accompanying drawings.

However, in describing the present invention, descriptions of already known functions or configurations will be omitted in order to clarify the subject matter of the present invention.

1 is a cutaway perspective view showing a multi-check valve according to an embodiment of the present invention.

As shown in Figure 1, the multi-check valve 1000 according to the present invention includes a valve body 100, a regulator 200, a valve seat 300, a disk 400, a cylinder disk 500, and a spring 600. , Including a packing member 700.

First, the valve body 100 forms a basic skeleton of the valve, and the inflow space S1 and the outflow space S2 are separated through the valve seat 300 therein.

In addition, the material of the valve body 100 is preferably made of cast steel, bronze, or stainless steel according to specifications of high temperature, high pressure, and fluid.

Next, the regulator 200 is formed on the upper portion of the valve body 100, the flow path 210 communicates with the valve body 100 to receive hydraulic oil, and is formed on one side of the flow path 210 and the hydraulic oil is injected And a discharge opening 220 and a pressing part 230 installed at an end of the flow path 210 and pressurizing the hydraulic oil.

In addition, a disk 400, a cylinder disk 500, and a spring 600 are located at the other end of the flow path 210, and as the pressure inside the flow path 210 changes according to the reciprocating movement of the pressing unit 230, the disk ( 400), the cylinder disk 500 and the spring 600 are to be moved organically.

In detail, the flow path 210 includes an upper flow path 211, a connection flow path 212 and a lower flow path 213.

The upper flow path 211 is preferably located above the valve body 100, and is installed on one side so that the pressurizing part 230 is sealed to the inner circumferential surface.

In addition, an opening 220 is formed on the upper side of the upper flow path 211 to inject hydraulic oil into the flow path 210 and discharge hydraulic oil so that the check valve 1000 does not operate in an emergency.

In addition, the hydraulic oil injected into the opening 220 moves from the upper flow path 211 to the lower flow path 213 along the connection flow path 212 and is filled except for a partial space of the flow path 210.

Next, the cylinder disk 500 is formed to seal the lower flow path 213 and is formed to have the same axis as the axis of the valve seat 300.

At this time, the valve seat 300 is formed to be separated into an inlet space (S1) and an outlet space (S2) inside the valve body 100, and a state in which the valve seat 300 and the disk 400 are in close contact with each other and separated from each other. Accordingly, the fluid flowing in the inflow space S1 is moved and stopped in the outflow space S2.

In addition, one end of the disk 400 is in contact with the valve seat 300, and the other end of the disk 400 is formed with a protrusion 410 so as to be received in the lower flow path 213.

The valve seat 300 is in contact with the disk 400, and the pressure of the hydraulic oil is initially adjusted so that the disk 400 is kept in contact with the valve seat 300 so that it is opened and closed only by the pressure of the inflow space S1. Is done.

The protrusion 410 is accommodated in the lower flow path 213 formed to be the same as the axis of the valve seat 300, and may be in close contact with or spaced apart from the valve seat 300 according to the pressure of the hydraulic oil inside the flow path 210. You will be able to.

In addition, the cylinder disk 500 is formed between the outer peripheral surface of the protrusion 410 and the inner peripheral surface of the lower flow path 213.

The cylinder disk 500 has a through hole (not shown) formed in the center, and the protrusion 410 is in close contact with the through hole and is movable.

At this time, the packing member 700 is installed so that the hydraulic oil inside the flow path 210 does not leak between the outer circumferential surface of the cylinder disk 500 and the inner circumferential surface of the flow path 210 or between the through hole and the protrusion 410 of the cylinder disk 500. do.

In addition, a packing member 700 is additionally installed at a position where the outer circumferential surface of the pressing part 230 and the inner circumferential surface of the upper flow path 211 are in close contact with each other, and the hydraulic oil injected into the upper flow path 211 is external to the pressing part 230. By preventing discharge to the flow path 210, it is possible to reduce an error in the pressure of the hydraulic oil inside the flow path 210.

Here, the spring 600 is installed between the disk 400 and the cylinder disk 500 to provide an elastic force according to the pressure of the hydraulic oil.

Specifically, the cylinder disk 500 is formed in close contact with the outer circumferential surface of the lower flow path 213, and the protrusion 410 of the disk 400 is inserted into a through hole formed through the central portion of the cylinder disk 600. do.

In addition, the spring 600 is interposed along the outer circumferential surface of the protrusion 410, and the disk 400 and the cylinder disk 500 are moved according to the pressure of the hydraulic oil and the pressure of the fluid flowing from the inflow space S1, By opening and closing S1) and the outlet space S2, it is possible to discharge and block the flow of the fluid.

An example of the operation of the multi-check valve 1000 of the present invention configured as described above will be described with reference to FIGS. 2 and 3,

First, FIG. 2 is an exemplary view showing a state in which the inflow space and the outflow space are closed by the disk of the present invention.

As shown in FIG. 2, hydraulic oil is injected into the flow path 210 through the opening 220 and the opening 220 is sealed. In a state in which the hydraulic oil is injected into the flow path 210, pressure is applied to the hydraulic oil through the pressurizing unit 230 to adjust the compression rate of the spring 600 to adjust the position of the initial disk 400.

At this time, one end of the disk 400 is in close contact with the valve seat 300 to stop at a position to close the inlet space S1 and the outlet space S2, and the end of the protrusion 410 and the cylinder disk 500 The ends are located at the same position where the pressure of the same hydraulic oil and the elastic force of the spring 600 are the same.

That is, in the initial stage, since the valve seat 300 and the disk 400 are kept in close contact, the fluid flowing from the inflow space S1 is maintained in a closed state, and as the pressure of the fluid increases, the disk 400 ) Is pressed so that the valve seat 300 and the disk 400 are spaced apart from each other so that the fluid is discharged to the outlet space S2.

This is, as shown in FIG. 3, when the pressure of the fluid in the inflow space S1 is greater than the pressure of the hydraulic oil, the disk 400 is pushed so that the disk 400 is spaced apart from the valve seat 300 and the flow path ( 210) As the internal hydraulic oil pressurizes the cylinder disk 500, it is moved in the direction of the spring 600.

And the cylinder disk 500 and the disk 400 are stopped at the point where the pressure of the hydraulic oil and the elastic force of the spring are the same, and the fluid is discharged to the space spaced apart from the valve seat 300 of the disk 400, and the outlet space (S2) ).

In addition, when the fluid moving from the inflow space (S1) moves to the outflow space (S2) and the pressure of the fluid is lower than the pressure of the hydraulic oil, the disk 400 and the cylinder disk 500 by the elastic force of the spring 600 Is restored to both sides, and the disk 400 is in close contact with the valve seat 300 to close.

On the other hand, when the pressure in the outflow space (S2) is high or when the function of the check valve 1000 is to be stopped in case of another emergency, the opening 220 connected to the flow path 210 is opened and the inside of the flow path 210 By discharging the residual hydraulic oil, the disk 400 and the cylinder disk 500 are momentarily moved in a direction away from the inflow space (S1), and flow through at the maximum pressure and maximum flow rate of the fluid flowing from the inflow space (S1). It is possible to prevent explosions due to pressure in the pipe connected to the space S1.

The present invention is not limited to the above-described embodiments, and of course, various modifications can be made without departing from the gist of the present invention as claimed in the claims.

1000: multi check valve
S1: inflow space
S2: Outflow space
100: valve body
200: regulator
210: Euro
211: upper flow path
212: connection flow
213: lower flow path
220: opening
230: pressurization part
300: valve seat
400: disk
410: protrusion
500: cylinder disk
600: spring
700: packing member

Claims (2)

Valve body;
A regulator comprising a flow path communicating with the valve body and receiving hydraulic oil, an opening and closing opening formed at one side of the flow path through which hydraulic oil is input and discharged, and a pressurizing part installed at an end of the flow path to pressurize the hydraulic oil;
A valve seat separating an inlet space and an outlet space in the valve body;
A disk having one end in contact with the valve seat and the other end having a protrusion formed to be accommodated in the flow path;
A cylinder disk having an outer circumferential surface in close contact with the inner circumferential surface of the flow path and having a through hole for receiving the protrusion;
A spring installed between the disk and the cylinder disk; And
Includes; a packing member provided on the outer peripheral surface of the cylinder disk and the outer peripheral surface of the pressing portion,
The above flow path is
It is located on the upper portion of the valve body and further comprises an upper flow path installed to seal the pressurizing portion on one side, and a connection flow path connected to the upper flow path and connected to the through hole,
A multi-check valve, characterized in that a packing member is additionally installed at a position where the outer circumferential surface of the pressing portion and the inner circumferential surface of the upper flow path are in close contact with each other.
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