KR102590810B1 - Leakage preventing valve - Google Patents

Abstract

The present invention relates to an anti-leakage valve, and more specifically, to an anti-leakage valve that is applied to a pilot valve to prevent leakage. The anti-leakage valve of the present invention has the effect of preventing leakage by balancing the forces inside and outside the valve by adjusting the pressure inside or outside the valve when the pressure of the pressurizing source is very small. More specifically, by connecting an additional pressure source to the cylinder of the valve, by applying additional pressure inside the cylinder when the pressure inside the cylinder is very low, the inside and outside of the valve can be balanced, or by installing an additional pressure reducing valve on the pressure source. By offsetting the pressure of the pressurizing source within the pressure section where leakage may occur, there is an effect of preventing leakage by balancing the forces inside and outside the valve.

Description

Leakage preventing valve

The present invention relates to an anti-leakage valve, and more specifically, to an anti-leakage valve that is applied to a pilot valve to prevent leakage.

Pilot drive valves, which are used to control a larger flow rate, contain two or more valves to control the flow rate and can be opened and closed more stably than direct-acting valves, so they have been used in nuclear reactors that require higher safety.

As shown in Figure 1, the conventional pilot actuation valve consists of a primary valve on which pressure acts first and a secondary valve located within the cylinder of the primary valve, and is located inside the member that opens and closes the primary valve. By including an orifice that regulates the flow path and hydraulic pressure, the difference between the inlet side area and the outlet side area of the member that opens and closes the primary valve is offset, and the force on the pressurizing source side and the force inside the cylinder are maintained in a balanced state, thereby maintaining the valve. is configured not to be opened.

At this time, when the hydraulic pressure is gradually raised from the pressurizing source, in a section where the force on the pressurizing source side is very small, both the force on the pressurizing source side and the force on the inside of the cylinder are so small that the valve is not properly closed, causing leakage. There was.

As mentioned above, pilot valves are often applied in cases where high safety is required, that is, in pipelines through which hazardous substances such as toxic gases or high-temperature fluids pass, and when a leak occurs, the hazardous substances leak out to the outside, causing great casualties. Damage to facilities around me could have occurred.

Accordingly, in cases where the pilot valve is actually used, there is an inconvenience in that the user must manually intervene and check the valve to prevent the pilot valve from opening in a low pressure state.

Korean registered patent 10-2076456 “Leakage test device for air compressor intake valve and discharge valve”

The present invention was devised to solve the above problems. The purpose of the present invention is to achieve balance of force inside and outside the valve by adjusting the pressure inside and outside the valve when the pressure of the pressurizing source is very small. The aim is to provide an anti-leakage valve that can prevent leakage.

In more detail, an anti-leakage valve is designed to prevent leakage by connecting an additional pressure source to the cylinder of the valve and applying additional pressure to the inside of the cylinder when the pressure inside the cylinder is very low, thereby achieving force balance between the inside and outside of the valve. It is provided.

Alternatively, an anti-leakage valve is provided that can prevent leakage by installing a pressure reducing valve on the pressurization source to balance the force inside and outside the valve by offsetting the pressure of the pressurization source within a pressure section where leakage may occur.

In order to solve the problems described above, the leakage prevention valve according to an embodiment of the present invention includes a first valve that opens and closes by receiving pressure from a first pressurizing source, and is disposed inside the cylinder of the first valve to open and close the valve. A second valve that is closed, an internal flow path formed inside the first valve and transmitting the pressure of the first pressure source to the inside of the cylinder of the first valve, a second pressure source, and one end connected to the second pressure source, It includes a pressure adjustment passage for adjusting the pressure inside and outside the cylinder of the first valve, and the second pressure source adjusts the pressure inside and outside the cylinder of the first valve within a predetermined pressure range of the first pressure source through the pressure adjustment passage. It is characterized by applying a predetermined pressure to the inside and outside of the cylinder of the first valve so that the difference is maintained below a predetermined value.

In addition, the other end of the pressure adjustment passage is connected to the inside of the cylinder of the first valve, a first check valve installed in the internal passage, and controlling the fluid to flow from the first pressure source to the inside of the cylinder of the first valve, and a pressure adjustment It is installed in the flow path and further includes a second check valve that controls fluid to flow from the second pressure source to the inside of the cylinder of the first valve.

In addition, it further includes a pressure reducing valve installed in the pressure adjustment passage to reduce the hydraulic pressure output from the second pressure source, the inlet of the pressure reducing valve is located on the second pressure source side, and the outlet of the pressure reducing valve is located on the second check valve side. It is located and is characterized in that it includes a pressure regulating spring having an elastic coefficient of a predetermined value.

In addition, the other end of the pressure adjustment passage is connected to the internal passage, one side is in communication with the internal passage, and the other side is characterized by further comprising a shuttle valve installed in communication with the pressure adjustment passage.

In addition, the shuttle valve includes a flow space extending in one direction inside, and a moving member that moves inside the flow space to open and close the inlet, and the inlet is formed on both sides of one direction of the flow space. It communicates with the internal flow path and the pressure adjustment flow path, respectively, and the outlet is formed in a direction perpendicular to the inflow direction of the fluid and communicates with the inside of the cylinder of the first valve.

In addition, it further includes a pressure reducing valve installed in the pressure adjustment passage to reduce the hydraulic pressure output from the second pressure source, the inlet of the pressure reducing valve is located on the second pressure source side, and the outlet of the pressure reducing valve is located on the shuttle valve side, , the pressure reducing valve is characterized by including a pressure regulating spring having an elastic coefficient of a predetermined value.

In addition, it is formed outside the first valve and further includes an external passage communicating with the first pressure source and the internal passage, and a pressure reducing valve communicating with the external passage to reduce the hydraulic pressure of the external passage, and the second pressure source is the 1 It is the same as the pressurizing source, and is characterized in that one end of the pressure adjustment passage is connected to an external passage, and the other end of the pressure adjustment passage is connected to a pressure reducing valve.

Additionally, the inlet of the pressure reducing valve is located on the side of the external flow passage, and the pressure reducing valve includes a pressure regulating spring having an elastic coefficient of a predetermined value.

The anti-leakage valve of the present invention with the above configuration has the effect of preventing leakage by adjusting the pressure inside or outside the valve to achieve balance of force inside and outside the valve when the pressure of the pressurizing source is very small. There is.

More specifically, by connecting an additional pressure source to the cylinder of the valve, additional pressure is applied to the inside of the cylinder when the pressure inside the cylinder is very low, which has the effect of preventing leakage by balancing the forces inside and outside the valve.

Alternatively, by installing an additional pressure reducing valve on the pressurizing source to offset the pressure of the pressurizing source within the pressure section where leakage may occur, there is an effect of preventing leakage by balancing the forces inside and outside the valve.

1 is a diagram showing a conventional pilot valve.
Figure 2 is a schematic diagram showing an anti-leakage valve of the present invention.
Figure 3 is a schematic diagram showing a first embodiment of the present invention.
Figure 4 is a hydraulic circuit diagram of the first embodiment of the present invention.
Figure 5 is a schematic diagram showing a second embodiment of the present invention.
Figure 6 is a hydraulic circuit diagram of the second embodiment of the present invention.
Figure 7 is a schematic diagram showing a third embodiment of the present invention.
Figure 8 is a hydraulic circuit diagram of a third embodiment of the present invention.

Hereinafter, the technical idea of the present invention will be described in more detail using the attached drawings. Prior to this, the terms or words used in this specification and claims should not be construed as limited to their usual or dictionary meanings, and the inventor should appropriately define the concept of terms in order to explain his or her invention in the best way. It must be interpreted as meaning and concept consistent with the technical idea of the present invention based on the principle of definability.

Hereinafter, the basic configuration of the anti-leakage valve 1000 of the present invention will be described with reference to FIG. 2.

The present invention includes a first valve 300 that opens and closes by receiving pressure from the first pressurizing source 100, and a second valve that is disposed inside the cylinder 320 of the first valve 300 and opens and closes ( 400).

The first pressure source 100 can open and close the first valve 300 and the second valve 400 through the external flow path 110, and the first valve 300 can open and close the cylinder 320 and the cylinder ( It may include an opening and closing member 310 that opens and closes the opening and closing passage 330 communicating between 320 and the external passage 110, and directly connects the inside of the cylinder 320 and the external passage 110, and the opening and closing passage It may include an internal flow path 311 that exists separately from 330. The internal flow path 311 may transmit the pressure of the first pressure source 100 to the inside of the cylinder 320 of the first valve 300. The first valve 300 can be opened and closed by moving the opening and closing member 310 when a pressure difference occurs between the external passage 110 and the cylinder 320, and the internal passage 311 is opened and closed by the opening and closing member 310. ) may be a hole formed through the cylinder 320, or may be a passage formed on the outside of the cylinder 320 to communicate with the side of the cylinder 320 and the external passage 110.

At this time, the internal passage 311 may include an orifice 312, and the orifice 312 takes into account the difference between the area on the external passage 110 side and the internal passage 311 side of the opening and closing member 310, By adjusting the flow rate injected into the cylinder 320 through the internal passage 311, the force on the external passage 110 side and the force inside the cylinder 320 can be maintained in balance.

The second valve 400 may be connected to the inside of the cylinder 320 of the first valve 300 as described above. When the pressure inside the cylinder 320 of the first valve 300 is above a predetermined level, the second valve 400 may be finally opened.

The first valve 300 and the second valve 400 inside the cylinder 320 of the first valve 300 are preferably check valves including springs, and the first valve 300 has an opening and closing member 310. It is preferable that the force is balanced through the above-described orifice 312 and the internal passage 311 and is almost motionless, and the second valve 400 is a cylinder of the first valve 300 provided through the internal passage. (320) It is desirable to open when the internal hydraulic pressure rises above a predetermined level. Accordingly, the elasticity coefficient of the spring of the first valve 300 is relatively small compared to that of the second valve 400 and is used only to the extent of adjusting the error in force balance, and the elasticity coefficient of the spring of the second valve 400 is less than that of the first valve 400. It is relatively larger than the valve 300 and can be used to determine whether the leakage prevention valve 1000 is open or not.

In addition, the present invention may include a second pressure source 200 and a pressure adjustment passage 210. The second pressure source 200 may be the first pressure source 100, or may be another pressure source driven independently from the first pressure source 100. Each embodiment will be described later. One end of the pressure adjustment flow path 210 is connected to a second pressure source, and the pressure inside and outside the cylinder 320 of the first valve 300 can be adjusted. The second pressure source applies pressure to the cylinder 320 of the first valve 300 so that the difference between the internal pressure and the external pressure of the cylinder 320 of the first valve 300 is maintained below a predetermined value through the pressure adjustment flow path 210. A predetermined pressure can be applied internally and externally.

Accordingly, in a section where the pressure of the first pressure source is very small (when the pressure of the first pressure source 100 slowly increases from 0 Pa), almost no force is applied to the opening and closing member 310 and the spring of the first valve 300. It does not work, preventing the valve from loosening its closure. In more detail, by supplying additional pressure to the inside of the first valve 300 or reducing the external pressure, a predetermined force is applied to fix the opening and closing member 310 of the first valve 300 to prevent leakage. There is an effect that can be done.

Hereinafter, a first embodiment of the leakage prevention valve 1000 of the present invention will be described with reference to FIGS. 3 and 4.

In the first embodiment of the present invention, the second pressure source 200 may be a separate pressure source that is driven independently from the first pressure source 100. As shown in FIGS. 3 and 4, one end of the pressure adjustment passage 210 of the present invention may be connected to the second pressure source 200, and the other end of the pressure adjustment passage 210 may be connected to the first valve 300. It may be connected to the inside of the cylinder 320. Accordingly, the second pressure source 200 can apply a predetermined hydraulic pressure to the inside of the cylinder 320 of the first valve 300, thereby allowing the opening and closing member 310 to close the first valve 300 more tightly.

At this time, the anti-leakage valve 1000 of the present invention is a first valve installed in the internal flow path 311 and the pressure adjustment flow path 210 to allow fluid to flow inside the cylinder 320 of the first valve 300. It may further include a check valve 510 and a second check valve 520. The first check valve 510 can control the fluid to flow from the first pressure source 100 into the cylinder 320 of the first valve 300, and the second check valve 520 can control the fluid to flow into the second pressure source 100. It can be controlled to flow from the pressure source 200 into the cylinder 320 of the first valve 300.

At this time, the maximum output of the second pressure source 200 is based on the shape of the opening and closing member 310 (area on the side of the external passage 110 and the area on the inside of the cylinder 320) and the specifications of the orifice 312. This can be determined. In more detail, assuming that the pressure applied from the first pressure source 100 (hereinafter referred to as P1) increases linearly from 0 Pa, the internal pressure (hereinafter referred to as P2) of the cylinder 320 of the first valve 300 ) also increases, but when P1 is very small and less than a predetermined value, the P2 value hardly increases due to the orifice 312 of the internal flow path 311, so the balance of force is not maintained, and the first valve 300 is opened. Therefore, P2 can be forcibly raised through the second pressure source 200. At this time, when P1 becomes large enough, even if the inside of the cylinder 320 is not additionally pressurized, P2 rises normally and the first valve 300 is normally operated, so it is unnecessary to apply additional pressure through the second pressure source 200. . That is, it is desirable that the maximum output of the second pressure source 200 is equal to or greater than the value of P1 at the point when P2 starts to rise normally.

Alternatively, the anti-leakage valve 1000 of the present invention may further include a pressure reducing valve 600 that reduces the pressure provided by the second pressure source 200. The pressure reducing valve 600 may be installed in the pressure adjustment flow path 210, the inlet of the pressure reducing valve 600 is located on the second pressure source 200, and the outlet of the pressure reducing valve 600 is connected to the second check valve ( 520) It is preferable to be located on the side. At this time, the pressure reducing valve 600 may include a pressure regulating spring 610 having an elastic coefficient of a predetermined value, and the cylinder 320 may be adjusted according to the elastic coefficient of the pressure regulating spring 610 applied to the pressure reducing valve 600. The maximum output of the additional pressure applied inside can be adjusted, and the additional pressure can be supplied more stably inside the cylinder 320.

Hereinafter, a second embodiment of the leakage prevention valve 1000 of the present invention will be described with reference to FIGS. 5 and 6.

In the second embodiment of the present invention, the second pressure source 200 may be a separate pressure source that is driven independently from the first pressure source 100. As shown in FIGS. 5 and 6, one end of the pressure adjustment passage 210 of the present invention may be connected to the second pressure source 200, and the other end of the pressure adjustment passage 210 may be connected to the first valve 300. It may be connected to the inside of the cylinder 320. Accordingly, the second pressure source 200 can apply a predetermined hydraulic pressure to the inside of the cylinder 320 of the first valve 300, thereby allowing the opening and closing member 310 to close the first valve 300 more tightly.

At this time, the anti-leakage valve 1000 of the present invention may further include a shuttle valve 530 installed so that one side communicates with the internal passage 311 and the other side communicates with the pressure adjustment passage 210. The shuttle valve 530 includes a flow space extending in one direction inside, and a moving member 531 that moves inside the flow space to open and close the inlet, and the inlet moves in one direction of the flow space. It is formed on each side and communicates with the internal flow path 311 and the pressure adjustment flow path 210, respectively, and the outlet is formed in a direction perpendicular to the inflow direction of the fluid and communicates with the inside of the cylinder 320 of the first valve 300. desirable. At this time, it is preferable that the outlet communicates with the internal flow path 311.

By including the shuttle valve 530, when the pressure on the second pressure source side (pressure adjustment passage 210) is greater than the pressure on the first pressure source 100 side (external passage 110), the pressure adjustment passage 210 ) is opened to pressurize the inside of the cylinder 320 of the first valve 300, and the pressure on the second pressure source side (pressure adjustment passage 210) is adjusted to the first pressure source 100 side (external passage 110). )), the valve can be operated normally by allowing the external passage 110 and the inside of the cylinder 320 to communicate.

In more detail, assuming that the pressure applied from the first pressure source 100 (hereinafter referred to as P1) increases linearly from 0 Pa, the internal pressure (hereinafter referred to as P2) of the cylinder 320 of the first valve 300 ) also increases, but when P1 is very small and less than a predetermined value, the P2 value hardly increases due to the orifice 312 of the internal flow path 311, so the balance of force is not maintained, and the first valve 300 is opened. Therefore, P2 can be forcibly raised through the second pressure source 200. At this time, when P1 becomes large enough, even if the inside of the cylinder 320 is not additionally pressurized, P2 rises normally and the first valve 300 is normally operated, so it is unnecessary to apply additional pressure through the second pressure source 200. . By including the shuttle valve 530, the pressure inside the cylinder 320 can be automatically adjusted by selectively opening the flow path.

Alternatively, the anti-leakage valve 1000 of the present invention may further include a pressure reducing valve 600 that reduces the pressure provided by the second pressure source 200. The pressure reducing valve 600 may be installed in the pressure adjustment flow path 210, the inlet of the pressure reducing valve 600 is located on the second pressure source 200, and the outlet of the pressure reducing valve 600 is connected to the second check valve ( 520) It is preferable to be located on the side. At this time, the pressure reducing valve 600 may include a pressure regulating spring 610 having an elastic coefficient of a predetermined value, and the cylinder 320 may be adjusted according to the elastic coefficient of the pressure regulating spring 610 applied to the pressure reducing valve 600. The maximum output of the additional pressure applied inside can be adjusted, and the additional pressure can be supplied more stably inside the cylinder 320.

Hereinafter, a third embodiment of the leakage prevention valve 1000 of the present invention will be described with reference to FIGS. 7 and 8.

In the third embodiment of the present invention, the second pressure source 200 may be the first pressure source 100. At this time, the pressure reducing valve 600 is directly connected to the first pressure source 100 (=second pressure source 200) to directly lower the pressure on the external flow path 110, thereby maintaining force balance. As shown in Figures 7 and 8, it is preferable that one end of the pressure adjustment passage 210 of the present invention is connected to the external passage 110, and the other end of the pressure adjustment passage 210 is connected to the pressure reducing valve 600. do. At this time, the inlet of the pressure reducing valve 600 is preferably located on the side of the external flow path 110, and the pressure reducing valve 600 includes a pressure regulating spring 610 having an elastic coefficient of a predetermined value.

At this time, the pressure reducing valve 600 may include a pressure regulating spring 610 having an elastic coefficient of a predetermined value, and the external flow path 110 may be formed according to the elastic coefficient of the pressure regulating spring 610 applied to the pressure reducing valve 600. ) can be adjusted to the degree of decompression.

In more detail, assuming that the pressure applied from the first pressure source 100 (hereinafter referred to as P1) increases linearly from 0 Pa, the internal pressure (hereinafter referred to as P2) of the cylinder 320 of the first valve 300 ) also increases, but when P1 is very small and less than a predetermined value, the P2 value hardly increases due to the orifice 312 of the internal flow path 311, so the balance of force is not maintained, and the first valve 300 is opened. Therefore, the pressure of P1 can be forcibly lowered. At this time, when P1 becomes sufficiently large, P2 rises normally even without additional pressure inside the cylinder 320, so that the first valve 300 can be normally driven. That is, the elastic coefficient of the pressure control spring 610 applied to the pressure reducing valve 600 is opened when the pressure of the external passage 110 exceeds the P1 value at which P2 can normally rise, and the pressure is not reduced, and the external passage 110 If the pressure is less than the P1 value at which P2 can normally rise, it can be reduced to ensure that the forces inside and outside the opening and closing passage 330 are balanced.

The technical idea of the present invention should not be interpreted as limited to the above-described embodiments. Not only is the scope of application diverse, but various modifications can be made at the level of those skilled in the art without departing from the gist of the present invention as claimed in the claims. Therefore, such improvements and changes fall within the scope of protection of the present invention as long as they are obvious to those skilled in the art.

1000: Leakage prevention valve
100: first pressurized source
110: External flow path
200: Second pressurized source
210: Pressure adjustment flow path
300: first valve
310: Opening and closing member
311: Internal flow path
312: Orifice
320: cylinder
330: Open/close flow path
400: second valve
510: 1st check valve
520: 2nd check valve
530: Shuttle valve
531: moving member
600: Pressure reducing valve
610: Pressure adjustment spring

Claims (8)

a first valve that opens and closes by receiving pressure from a first pressure source;
a second valve disposed inside the cylinder of the first valve to open and close;
an internal flow path formed inside the first valve and transmitting the pressure of the first pressure source to the inside of the cylinder of the first valve;
a second pressurized source; and
a pressure adjustment flow path, one end of which is connected to the second pressure source and which adjusts the pressure inside and outside the cylinder of the first valve;
The other end of the pressure adjustment passage is connected to the inside of the cylinder of the first valve,
a first check valve installed in the internal flow path and controlling fluid to flow from the first pressure source into the cylinder of the first valve; and
A second check valve installed in the pressure adjustment passage and controlling fluid to flow from the second pressure source into the cylinder of the first valve,
The second pressurizing source is,
Applying a predetermined pressure to the inside and outside of the cylinder of the first valve through the pressure adjustment passage so that the difference between the pressure inside and outside the cylinder of the first valve is maintained below a predetermined value within the predetermined pressure range of the first pressure source. An anti-leakage valve characterized in that.
delete According to clause 1,
It further includes a pressure reducing valve installed in the pressure adjustment passage to reduce the hydraulic pressure output from the second pressure source,
The inlet of the pressure reducing valve is located on the second pressure source side,
The outlet of the pressure reducing valve is located on the second check valve side,
An anti-leakage valve comprising a pressure regulating spring having an elastic coefficient of a predetermined value.
a first valve that opens and closes by receiving pressure from a first pressure source;
a second valve disposed inside the cylinder of the first valve to open and close;
an internal flow path formed inside the first valve and transmitting the pressure of the first pressure source to the inside of the cylinder of the first valve;
a second pressurized source; and
a pressure adjustment flow path, one end of which is connected to the second pressure source and which adjusts the pressure inside and outside the cylinder of the first valve; and
The other end of the pressure adjustment passage is connected to the internal passage,
One side is in communication with the internal flow path,
It includes a shuttle valve installed so that the other side communicates with the pressure adjustment passage,
The second pressurizing source is,
Applying a predetermined pressure to the inside and outside of the cylinder of the first valve through the pressure adjustment passage so that the difference between the pressure inside and outside the cylinder of the first valve is maintained below a predetermined value within the predetermined pressure range of the first pressure source. And
The shuttle valve is,
It includes a flow space extending in one direction inside, and a moving member that moves within the flow space to open and close the inlet,
Inlets are formed on both sides of one direction of the flow space and communicate with the internal flow path and the pressure adjustment flow path, respectively,
An anti-leakage valve, characterized in that the outlet is formed in a direction perpendicular to the inflow direction of fluid and communicates with the inside of the cylinder of the first valve.
delete According to clause 4,
It further includes a pressure reducing valve installed in the pressure adjustment passage to reduce the hydraulic pressure output from the second pressure source,
The inlet of the pressure reducing valve is located on the second pressure source side,
The outlet of the pressure reducing valve is located on the shuttle valve side,
The pressure reducing valve is,
An anti-leakage valve comprising a pressure regulating spring having an elastic coefficient of a predetermined value. a first valve that opens and closes by receiving pressure from a first pressure source;
a second valve disposed inside the cylinder of the first valve to open and close;
an internal flow path formed inside the first valve and transmitting the pressure of the first pressure source to the inside of the cylinder of the first valve;
a second pressurized source; and
a pressure adjustment flow path, one end of which is connected to the second pressure source and which adjusts the pressure inside and outside the cylinder of the first valve;
an external passage formed outside the first valve and communicating with the first pressure source and the internal passage; and
It further includes a pressure reducing valve that communicates with the external passage and reduces the hydraulic pressure of the external passage,
The second pressure source is the same as the first pressure source,
One end of the pressure adjustment flow path is connected to the external flow path,
The other end of the pressure adjustment flow path is connected to the pressure reducing valve,
The second pressurizing source is,
Applying a predetermined pressure to the inside and outside of the cylinder of the first valve through the pressure adjustment passage so that the difference between the pressure inside and outside the cylinder of the first valve is maintained below a predetermined value within the predetermined pressure range of the first pressure source. An anti-leakage valve characterized in that.
According to clause 7,
The inlet of the pressure reducing valve is located on the external flow path,
The pressure reducing valve is,
An anti-leakage valve comprising a pressure regulating spring having an elastic coefficient of a predetermined value.

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