KR101156108B1 - Contact pressure adjusting valve - Google Patents

Abstract

PURPOSE: A valve for adjusting contact pressure is provided to adjust elastic restoring force according to adjusting contraction of a spring by moving the position of a support surface of the spring, applying elastic restoring force to a valve seat, to an adjusting part. CONSTITUTION: A valve for adjusting contact pressure comprises a valve body(100), a valve seat holder(300), an elastic body(400), a ball(200), and an adjusting part(500). The valve body comprises a conduit connector(110) connected to conduits and an internal space. The valve seat holder is installed in the inner circumference of the conduit connector to be slid toward the internal space of the valve body, and a valve seat(310) is mounted on the valve seat holder. The elastic body elastically pushes the valve seat holder toward the internal space of the valve body. The ball is installed in the internal space of the valve body to control the flow of fluid by contact with the valve seat. The adjusting part is mounted on the inner circumference of the conduit connector to adjust the position of the elastic body.

Description

Contact surface pressure regulating valve {CONTACT PRESSURE ADJUSTING VALVE}

The present invention is a valve for opening and closing the flow path in accordance with the driving of the ball by contacting the valve seat installed in the passage of the fluid, in the valve assembly state by easily adjusting the contact surface pressure between the ball and the valve seat operating environment of the valve A contact surface pressure regulating valve that can be fitted to a.

The ball valve is connected to the middle of the pipeline to control the flow path (fluid passage) or to control the flow rate or oil pressure.The ball valve is installed on the inner circumferential surface forming the flow path and the ball is in contact with the valve seat to rotate the ball. According to the opening and closing of the flow path through the valve seat or adjust the size of the flow path.

1 is a cross-sectional view of a ball valve according to the prior art, referring to the cross-sectional view of FIG. It is formed in the shape of a sphere having a ball (20) embedded in the inner space of the valve body 10 so that it can be rotated by the spindle 22, and is provided on the inner peripheral surface of the opening provided on both sides of the valve body 10 It is configured to include a ring-shaped valve seat holder 30. The ball valve configured as described above is opened when the ball is rotated to face the inner flow path 21 in the direction of both openings, and when the ball is rotated so that the ball is indicated by a broken line in FIG. The outer spherical surface in which the inner flow passage 21 'is not formed is brought into contact with the valve seat 31 provided in the valve seat holder 30 to block the flow passage.

Here, the valve seat holder 30 wraps the valve seat 31 in contact with the ball 20 with the members 32 and 33, and receives the elastic restoring force of the spring 40 supported by the valve seat 31. Accordingly, the contact surface pressure between the ball 20 and the valve seat 31 is maintained at a pressure corresponding to the elastic restoring force of the spring 40, so that the valve seat 31 is pressed against the ball 20 when assembling the ball valve. By assembling the spring 40 to contract, it is possible to maintain the contact surface pressure with an elastic restoring force corresponding to the contraction change amount of the spring 40.

Such a ball valve can normally control the opening / closing operation of the flow path (including the operation of controlling the size of the flow path) without leaking only when the contact surface pressure between the valve seat and the ball is maintained within a predetermined range. In other words, when the contact surface pressure exceeds the pressure of the fluid, the opening and closing of the flow path can be normally controlled without leakage, and when the contact surface pressure becomes too large, the power required for driving the ball also increases, so it is desirable to keep the contact surface pressure constant. Do. To this end, when the ball valve is assembled, the spring 40 is pressed to have an appropriate elastic restoring force.

Since the actual ball valve is used in various environments, the contact surface pressure may vary depending on the use environment. For example, when used to block the flow of hot or medium temperature fluids, the volume increases due to thermal expansion of the ball and valve seat, and the contact surface pressure rises due to the increased volume, and eventually the torque required to rotate the ball. This leads to an increase of, so that the opening and closing operation is impossible. In addition, when used to block the low or low temperature fluid flow, the volume is reduced by the heat shrinkage of the ball and valve seat, the contact surface pressure is reduced by the reduced volume is lower than the pressure of the fluid, eventually blocking the fluid flow Even if the ball is rotated in order to prevent leakage.

Therefore, the ball valve should be adjusted to have an appropriate contact surface pressure according to the type, temperature and pressure of the fluid.

However, referring to the ball valve shown in FIG. 1, in the state where the assembly is completed by adjusting the pressing degree of the spring for determining the contact surface pressure between the ball and the valve seat, the pressing degree of the spring cannot be adjusted so that the contact surface pressure is appropriate for the use environment. Can't fit. Accordingly, the ball valve according to the prior art had to adjust the degree of pressing of the spring to have an elastic restoring force corresponding to the contact surface pressure between the ball and the valve seat. As a result, after the ball valve according to the prior art is assembled into a valve specialized in one use environment, it cannot be used in another use environment unless disassembled and reassembled.

KR 10-2010-0022379 A 2010.03.02. KR 10-2009-0049484 A 2009.05.18. KR 10-2001-0027658 A 2001.04.06.

Accordingly, an object of the present invention is to solve the conventional problems in which the contact surface pressure between the ball and the valve seat cannot be adjusted unless the valve is disassembled. It is to provide a contact surface pressure control valve that can easily adjust the elastic restoring force to have an appropriate contact surface pressure for the operating environment of the valve.

In order to achieve the above object, the present invention, the valve body 100 having a hollow pipeline connector 110 and the inner space communicated with the pipeline; A ring-shaped valve seat holder 300 installed on an inner circumferential surface of the conduit connector 110 so as to slide toward an inner space of the valve body 100 and to which the valve seat 310 is mounted; An elastic body 400 elastically pushing the valve seat holder 300 toward the inner space of the valve body 100; Ball 200 is installed in the interior space of the valve body 100 to control the flow of the fluid by the contact with the valve seat 310; In the valve comprising a, characterized in that further comprises an adjusting unit 500 is mounted to the inner peripheral surface of the pipe connector 110 to adjust the support position of the elastic body 400.

The adjusting part 500 is installed on an extension line in the direction in which the elastic body 400 contracts and expands and is supported by the pipe connector 110, and the length in the direction in which the elastic body 400 contracts and expands. It is characterized by adjusting.

The adjuster 500 includes two adjust rings 510 having a ring shape; An adjust key 520 interposed between two adjust rings 510 to adjust a distance between the adjust rings; It is configured to include, the elastic body 400 by pushing the elastic member 400 to the other adjust ring distance adjusted by the adjust key 520 in a state in which one side adjust ring is supported on the inner peripheral surface of the pipe connector 110 It is characterized by adjusting the support position of the.

The adjust key 520 has a shape that becomes narrower toward the inside of the conduit connector 110, and has a surface facing the two-side adjust ring 510 in a slope shape, and both-side adjust ring 510 is formed to have a surface in contact with the adjust key 520 to have the same slope as the adjust key 520, to move the adjust key 520 in the radial direction of the pipeline connector (110) The distance between the two side adjust ring 510 is adjusted by the distance.

The adjusting unit 500 includes an annular adjust guide ring 540 covering the adjust key 520 and both side adjust rings 510; The screw is fastened to the adjust key 520 through the adjust guide ring 540, and the bolt head is pivotally caught to the adjust guide ring 540, and the thickness of the adjust key 520 is adjusted. Adjust bolt 530 to move the adjust key 520 in the radial direction of the conduit connector 110 by the rotation for the fastening to smaller than the thickness of 510; Characterized in that further comprises a.

The adjust key 520 may be installed at a distance from each other along a circumferential direction of the adjust ring 510 provided in plural and having a ring shape.

Therefore, the present invention configured as described above can adjust the contraction degree of the spring to adjust the elastic restoring force by moving the support surface position of the spring applying the elastic restoring force to the valve seat in contact with the ball to the adjusting unit 500. With the valve assembled, the contact surface pressure between the ball and the valve seat can be adjusted to the operating environment without disassembling the valve.

In addition, since the operation for adjusting the contact surface pressure to the use environment is also made only by rotating the adjust bolt, it is possible to easily set the final valve produced by the assembly process of the production line to be used in various environments.

1 is a cross-sectional view of a valve according to the prior art.
Figure 2 is a perspective view of a contact surface pressure regulating valve according to an embodiment of the present invention.
Figure 3 is an exploded perspective view of the contact surface pressure regulating valve according to the embodiment of the present invention.
Figure 4 is a cross-sectional view of the contact surface pressure regulating valve according to the embodiment of the present invention.
5 is a perspective view of a valve seat holder 300 in the contact surface pressure regulating valve according to the embodiment of the present invention.
6 is an exploded perspective view of the valve seat holder 300 in the contact pressure regulating valve according to the embodiment of the present invention.
7 is a perspective view of the adjusting unit 500 in the contact surface pressure regulating valve according to the embodiment of the present invention.
8 is an exploded perspective view of the adjusting part 500 in the contact surface pressure regulating valve according to the embodiment of the present invention.
9 is a partial cross-sectional view for explaining a surface pressure control method between the ball and the valve seat in the contact surface pressure control valve according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. It should be noted that, in the drawings, the same reference numerals are used to denote the same or similar components in other drawings. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

2 to 4 are views for explaining a contact surface pressure regulating valve according to an embodiment of the present invention, Figure 2 is a perspective view, Figure 3 is an exploded perspective view, Figure 4 is a cross-sectional view. In the cross-sectional view of Figure 4 it is shown to omit the rotating means (130, 131) and the support (121) for supporting the valve body 100 is mounted to the outside of the valve body 100 to rotate the spindle 210 to be described later Be careful.

2 to 4, the contact surface pressure regulating valve according to the embodiment of the present invention includes a valve body 100 connecting pipes at both ends, and a ball 200 for controlling fluid flow between the pipes at both ends and the valve. The seat holder 300, the elastic seat 400 which pushes the valve seat holder 300 with the elastic restoring force toward the ball 200, and the elastic body supported by the step formed on the inner circumferential surface of the pipe connector of the valve body 100 to be described later. And an adjusting part 500 configured to adjust the length of the contraction and expansion direction of the 400.

The valve body 100 is open at both ends and provided with an inner space, and fixed to the main body 120 and the opening at both ends of the main body 120 so as to rotatably embed the ball 200 in the inner space. It is configured to include a hollow conduit connector 110 in communication with the pipeline to form a flow path through the inner space of the main body (120).

The ball 200 is formed in the shape of a sphere as a whole, and has a cylindrical inner flow passage 220 penetrating through the center, and when the ball 200 is embedded in the main body 120, the inner flow passage 220 is rotated. The lower end is rotatably supported at the inner lower end of the main body 120 so as to be directed to the connector 110, and is mounted to rotate by the spindle 210.

The rotatable ball 200 is in close contact with the valve seat 310 of the valve seat holder 300, which is mounted on the inner circumferential surface of the pipe connector 110, and by adjusting the rotational direction of the ball 200. 220 to be in the same line as the both ends of the connector 110 to form a flow path or otherwise block the flow path by blocking the ball between the two pipe connectors (110). 4 is a cross-sectional view of an operating state in which the inner flow path 220 is in line with both side pipe connectors 110, and in this state, a surface of a portion surrounding the opening of the inner flow path 220 at the spherical surface of the ball 200. To the valve seat 310. In addition, the ball in a closed operation state, that is, a state of blocking the conduit connector 110, is indicated by a broken line for better understanding. In the closed operation state, since the direction of the inner flow path 220 'of the ball 200' forms a right angle with the line connecting the two pipeline connectors 110, there is no opening of the inner flow path 220 at the outer spherical surface of the ball 200. No contact with the valve seat 310 on the side.

Here, the spindle 210 is connected to the ball 200 to rotate the ball 200 and penetrates the upper portion of the main body 120 to expose the top to the outside, it can be rotated outside the main body 120 To be. Rotating means for rotating the spindle 210 may be composed of a handle 131 and a power transmission means 130 for transmitting the power of the handle to the spindle 210, as shown in Figs. It is not limited to the rotating means, for example, it may be configured by a motor or an actuator connected to the upper end of the spindle (210).

The shape of the ball 200, the main body 120 incorporating the ball 200, the control of the flow path by the ball 200 and the valve seat 310 to be described later, and means for rotating the ball 200 Since these are generally known techniques, they are briefly described in the above description.

Hereinafter, the characteristic components of the present invention will be described.

On the inner circumferential surface of the pipe connector 110, two stepped steps 111 and 112 are formed at a portion connected to the main body 120. Then, the valve seat holder 300 is inserted into the stepped jaw 112 close to the ball 200 embedded in the main body 120, and the adjusting part 500 is provided at the stepped jaw 111 far from the ball 200. The elastic body 400 is inserted between the valve seat holder 300 and the adjusting part 500.

In this way, the pipe connector 110 in which the valve seat holder 300, the elastic body 400, and the adjusting part 500 are mounted on the stepped portions 111 and 112 of the inner circumferential surface is connected to an opening of the main body 120. The valve seat holder 300 may slide toward the inner space of the valve body 100 in which the ball 200 is installed, and the elastic body 400 has elastic restoring force that is stretched again when pressed in the contracted direction. It has an elastic restoring force to push the valve seat holder 300 toward the ball 200 at the other end in the state in which it is supported by the adjusting unit 500.

In other words, when the valve seat 310 is mounted to be in contact with the ball 200, the elastic body 400 is pressed so that the valve seat holder 300 has an elastic restoring force to push the valve seat holder 300 to the elastic body 400. Accordingly, the contact surface pressure between the valve seat 310 mounted on the valve seat holder 300 and the ball 200 may be maintained. This contact surface pressure makes a good contact between the ball 200 and the valve seat 310, that is, a gas tight state.

The valve seat holder 300, the elastic body 400, and the adjusting unit 500 mounted on the inner circumferential surface of the pipe connector 110 will be described with reference to FIGS. 5 to 8.

5 is a perspective view of the valve seat holder 300, and FIG. 6 is an exploded perspective view of the valve seat holder 300.

5 and 6, the valve seat holder 300 has a short hollow tube shape in which a ring-shaped valve seat 310 is mounted, but the valve seat 310 protrudes toward one end of the valve seat holder 300. And the other end of the opening is provided with a plurality of grooves 321 for mounting the elastic body 400 one by one.

According to a specific embodiment, the valve seat holder 300 is formed in a short hollow tube shape having a stepped portion 331 formed at one end by bending inwardly, so as to interpolate the valve seat 310 as the valve seat 310. The seat cap 330 which protrudes toward the opening of one end in the state which caught the seat 310 at the stepped 331, and the valve seat | bed | sheet inserted in the other end opening of the seat cap 330 which inserted the valve seat 310 It is configured to include a ring-shaped seat ring 320, the grooves 321 are formed along the surface to prevent the separation of 310 and exposed in the other end direction.

Then, in the state where the valve seat 310, the seat ring 320 and the seat cap 330 are coupled as described above, the bolt 332 is fastened through the outer circumferential surface of the seat cap 330, the seat cap 330 An outer circumferential surface of the seat ring 320 inserted into the other end opening of the seat ring 320 is formed along the circumferential direction to form an annular groove 322 that is formed in an annular shape, and an end of the bolt 332 penetrates through the seat cap 330. It is fitted into the annular groove 322 formed on the outer peripheral surface of the seat ring 320. The bolts 332 fastened in this way are installed in plural along the outer circumference of the seat cap 330.

In the valve seat holder 300 formed of a combination of the valve seat 310, the seat ring 320, and the seat cap 330, a plurality of O-rings 340 are installed. According to an embodiment of the present invention, the position where the O-ring is installed, before and after the portion where the bolt 332 is fastened to the outer peripheral surface of the seat cap 330 in contact with the inner circumferential surface stepped 112 of the pipe connector 110, the seat cap ( The inner circumferential surface of the 330 is an inner side of the step 331 on which the valve seat 310 is caught, a portion where the seat cap 330 and the seat ring 320 contact each other, and a portion where the seat ring 320 and the valve seat 310 contact each other. .

On the other hand, the width of the annular groove 322 formed on the outer peripheral surface of the seat ring 320 is formed larger than the end of the bolt 332, the seat ring 320 is seat bolt 330 by the bolt 332 Although it does not allow to deviate from, but allows the seat ring 320 to flow slightly with respect to the seat cap 330 even when the bolt 332 is fastened. Accordingly, the valve seat 310 may also flow slightly with respect to the seat cap 330.

The valve seat holder 300 having the above-described structure inserts the elastic member 400 into the recess 321 of the seat ring 320, and then inserts the adjusting part 500, which will be described later, into the inner chin 111. Next, the adjusting part 500 is inserted into the stepped portion 112 which is in contact with the stepped portion 111 inserted therein. In this case, the valve seat 310 is inserted in the direction toward the ball 200.

The elastic body 400 has an elastic restoring force to be stretched again against contraction by external force, and may be configured, for example, as a compression spring. The elastic body 400, the greater the change in length due to shrinkage, the greater the elastic restoring force.

And, the elastic body 400 is inserted into the groove 321 of the seat ring 320, but the other end to protrude to the outside, to support the other end by the adjuster 500 to be described later, accordingly The elastic body 400 is supported by the adjusting part 500 to elastically push the valve seat holder 300 toward the ball 200 mounted in the inner space of the valve body 100.

7 is a perspective view of the adjusting unit 500, Figure 8 is an exploded perspective view of the adjusting unit 500.

7 and 8, the adjusting unit 500 is inserted into the inner circumferential end step 111 of the pipe connector 110 to support the other end of the elastic body 400, but the other end of the elastic body 400. It is configured to be able to adjust the position of the surface supporting the.

According to a specific embodiment, the adjusting part 500 includes a short guide tube guide ring 540 of the hollow tube shape; A ring-shaped adjust ring 510 provided with two and extrapolated to an outer circumferential surface of the adjust guide ring 540; An adjust key 520 interposed between the two adjust rings 510; It consists of two; through the adjust guide ring 540, the adjust bolt 530 to be fastened to the adjust guide ring 540, and screwed to the adjust key 520; The distance between the adjust rings 510 may be adjusted by the adjust key 520.

According to the embodiment of the present invention, by adjusting the depth screwed to the adjust key 520 by the rotation of the adjust bolt 530, the position of the adjust key 520 is changed to adjust the adjust rings 510. Adjust the distance between them. To this end, the adjust key 520 has a shape that becomes narrower toward the inside of the pipeline connector 110 (the radial direction of the adjust guide ring or the radial direction of the pipeline connector in a state in which it is mounted on the pipeline connector). A surface in contact with the just ring 510 is provided as an inclined surface, and is formed to have a thickness smaller than the thickness of the adjust ring 510 (length in the radial direction of the pipe connector). Then, both side adjust rings 510 are provided with an inclined surface at the same angle as the slope of the shaving adjust key 520 in contact with the adjust key 520.

Accordingly, if the adjust bolt 530 does not move in the radial direction of the pipe connector 110, the screw depth of the adjust bolt 530 may be changed to adjust the adjust key 520 on both sides of the adjust ring 510. It is possible to move in the radial direction of the pipe connector 110 as if slipping), and the distance between the two adjust ring 510 by the movement of the adjust key 520 can also be changed.

The adjust bolt 530 does not move in the radial direction of the pipe connector 110, as described later, when the pipe connector 110 is mounted on the main body 120, the elastic body 400 is mounted in a compressed state. This is because the elastic body 400 always receives a force in a direction in which both side adjust rings 510 are close to each other. In other words, the force received in the direction in which both side adjust ring 510 is closer to each other, so that the adjust key 520 inclined contact with the adjust ring 510 is directed toward the outside of the conduit connector 110, Regardless of the threading depth of the bolt 530 and the adjust key 520, the adjust bolt 530 is forced outwardly of the conduit connector 110. Here, the screw groove 521 of the adjust key 520 screwed to the adjust bolt 530 is deep enough or to pass through the adjust key 520 to ensure the movement of the adjust key 520. In addition, the through hole 541 of the adjust guide ring 540 penetrated by the bolt 530 may have a larger groove than the through hole 541 for mounting the head of the bolt 530.

The adjusting part 500 configured as described above is a step 111 far from the main body 120 among the stepped steps 111 and 112 formed on the inner circumferential surface of the pipe connector 110. The valve seat holder 300 having the elastic body 400 is inserted into the stepped portion 112 on the side close to the main body 120, and thus, one side adjust ring 510a is formed on both side adjust rings 510. The elastic body 400 is supported by the other side adjust ring 510b in a state in which it is supported on the inner circumferential step 111 of the pipe connector 110.

On the other hand, the adjust guide ring 540 is an annular ring covering the adjust key 520 and the adjust ring 510 when viewed from the inside of the pipe connector 110, the adjust key 520 and the adjust ring Prevent departure of 510.

In addition, when the adjust key 520 is moved in the radial direction of the pipe connector 110 by rotating the bolt 530, the adjust key 520 may be formed by the inclined surface contact between the adjust key 520 and the adjust ring 510. Since the 520 flows slightly in the line toward the ball 200, the adjust guide ring 540 also slightly in the line toward the ball 200 by the bolt 530 screwed to the adjust key 520. Flow. In the embodiment of the present invention, in order to prevent the adjust guide ring 540 flowing in accordance with the rotation of the adjust bolt 530 does not protrude from the inner circumferential surface of the pipe connector 110, shown in Figures 3 and 4 As described above, another step 111a may be formed on the step 111 supporting the adjust rings 510: 510a to allow the adjust guide ring 540 to flow.

In this case, the adjust key 520 is interposed between two adjust rings 510 having a ring shape, and is provided in plural and spaced from each other along the circumferential direction of the adjust guide ring 540. It is preferable to install. This is to equalize the contact surface pressure between the ball 200 and the valve seat 310.

Pipe fittings 110 equipped with the adjusting unit 500 and the valve seat holder 300, the valve seat 310 is pressed by the ball 200 when connected to the main body 120, the elastic body 400 Should be slightly compressed.

As described above, after connecting the pipe connector 110 to the main body 120, the contact surface pressure between the ball 200 and the valve seat 310 can be adjusted. This will be described with reference to FIG. 9.

9 is a partial cross-sectional view for explaining a surface pressure control method between the ball and the valve seat. Specifically, the cross-sectional view shown in (a) of FIG. 9 is a partial cross-sectional view of a state in which the contact surface pressure is increased by increasing the elastic restoring force of the elastic body 400, and the cross-sectional view shown in FIG. Is a partial cross-sectional view of a state in which contact surface pressure is lowered by reducing elastic restoring force.

Referring to FIG. 9 (a), the main body in which the ball 200 is mounted has a pipe connector 110 mounted on the inner circumferential surface of the valve seat holder 300, the elastic body 400, and the adjusting part 500. After connecting to 120, by rotating the adjustment bolt 530 of the adjusting part 500 exposed on the inner peripheral surface of the pipe connector 110 to deepen the screwing depth with the adjust key 520, The adjust key 520 is moved in the direction of the adjust guide ring 540 (inner direction of the pipe connector). Accordingly, the adjust ring 510: 510b on one side of the elastic body 400 slides toward the elastic body 400 to contract the elastic body 400, thereby increasing the elastic restoring force of the elastic body 400, and increasing the elasticity. Contact surface pressure between the ball 200 and the valve seat 310 is also increased by the restoring force.

Next, referring to FIG. 9B, the direction of the distance away from the adjust guide ring 540 by lowering the depth of screwing with the adjust key 520 by rotating the adjust bolt 530 backward (pipe connector) In the outward direction). Accordingly, the separation occurs between the adjust ring 510: 510b and the adjust key 520 on one side of the elastic body 400, but the adjust ring 510: 510b on the one side is the elastic body 400. Sliding in the direction in contact with the adjust key 520, the elastic body 400 is extended by the sliding distance. As a result, the elastic restoring force of the elastic body 400 is reduced by the elongated length so that the contact surface pressure between the ball 200 and the valve seat 310 is also lowered.

As described above, the contact surface pressure regulating valve according to the embodiment of the present invention shrinks the elastic body 400 by changing the position of the adjusting ring 510b of one side supporting the elastic body 400 in an assembled state. Since the contact surface pressure between the ball 200 and the valve seat 310 is adjusted by adjusting the degree, there is no need to dismantle for adjusting the contact surface pressure, and the surface pressure can be adjusted simply by rotating the adjust bolt 530. It's easy to work with.

On the other hand, in the above description of the embodiment of the present invention, although the embodiment is applied to the ball valve for opening and closing the flow path by the rotation of the ball 200 having the internal flow path 220, the present invention is not limited to the ball valve. In other words, the present invention is also applicable to a general valve which opens or closes a ball without an internal flow path to the valve seat or is spaced apart from the valve seat. However, since the valve seat holder 300 in which the valve seat is fixed may be detached in a state in which the valve seat and the ball are spaced apart from each other, only a means for preventing separation of the valve seat halter 300 may be added.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, . ≪ / RTI > Accordingly, such modifications are deemed to be within the scope of the present invention, and the scope of the present invention should be determined by the following claims.

100: valve body 110: pipe connection 120: main body
200: ball 210: spindle
300: valve seat holder 310: valve seat 320: seat ring
330: seat cap
400: elastic body
500: Adjusting unit 510: Adjust ring 520: Adjust key
530: Adjust bolt 540: Adjust guide ring

Claims (6)

delete delete A valve body 100 having a hollow conduit connector 110 and an inner space communicating with the conduit;
A ring-shaped valve seat holder 300 installed on an inner circumferential surface of the conduit connector 110 so as to slide toward an inner space of the valve body 100 and to which the valve seat 310 is mounted;
An elastic body 400 elastically pushing the valve seat holder 300 toward the inner space of the valve body 100;
Ball 200 is installed in the interior space of the valve body 100 to control the flow of the fluid by the contact with the valve seat 310;
In the valve configured to include,
It is configured to further include an adjusting unit 500 is mounted to the inner peripheral surface of the pipe connector 110 to adjust the support position of the elastic body 400,
The adjusting unit 500,
Is installed on the extension line in the direction of contraction and expansion of the elastic body 400 is supported by the pipe connector 110, and adjusting the length in the direction of contraction and expansion of the elastic body 400, but having a ring shape Adjust ring 510; An adjust key 520 interposed between two adjust rings 510 to adjust a distance between the adjust rings; Consisting of,
While adjusting the support position of the elastic member 400 by pushing the elastic member 400 to the other adjust ring distance adjusted by the adjust key 520 while the one side adjust ring is supported on the inner circumferential surface of the pipe connector 110. Contact surface pressure regulating valve, characterized in that. The method of claim 3, wherein
The adjust key 520 has a shape that becomes narrower toward the inside of the pipe connector 110, and has a surface facing both of the adjust ring 510 in a slope shape,
Both side adjust ring 510 is formed such that the surface in contact with the adjust key 520 has the same slope as the adjust key 520,
Contact surface pressure control valve, characterized in that for adjusting the distance between the two-side adjust ring 510 by the distance in which the adjust key 520 in the radial direction of the pipe connector (110). The method of claim 4, wherein
The adjusting unit 500,
An annular adjust guide ring 540 covering the adjust key 520 and both side adjust rings 510;
The screw is fastened to the adjust key 520 through the adjust guide ring 540, and the bolt head is pivotally caught to the adjust guide ring 540, and the thickness of the adjust key 520 is adjusted. Adjust bolt 530 to move the adjust key 520 in the radial direction of the conduit connector 110 by the rotation for the fastening to smaller than the thickness of 510;
Contact surface pressure regulating valve, characterized in that further comprises a. 6. The method of claim 5,
The adjust key 520, the contact surface pressure regulating valve, characterized in that the plurality is provided at a distance from each other along the circumferential direction of the adjust ring 510 is provided with a ring shape.

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