KR20230038079A - Gate valve - Google Patents

Abstract

A gate valve is provided by one embodiment of the present invention. According to one embodiment of the present invention, the gate valve, which can effectively seal a gate flow path, comprises: a housing which is formed with an inlet flow path and an outlet flow path on both sides thereof, respectively, and has a gate flow path between the inlet flow path and the outlet flow path; a gate unit which slidingly moves inside the housing to open and close the gate flow path; and a driving shaft which penetrates the housing so that one end is connected to the gate unit and the other end is connected to a driving unit outside the housing to slidingly move the gate unit in a vertical direction. The gate unit comprises: a first disk in which a first valve surface sealing any one between the inlet flow path and the outlet flow path is formed, a first inclination surface is formed on a rear surface of the first valve surface, and a coupling groove to which the driving shaft is coupled is formed; and a second disk in which a second valve surface sealing the remaining one between the inlet flow path and the outlet flow path is formed and a second inclination surface coming in contact with the first inclination surface is formed on the rear surface of the second valve surface and which is coupled to the first disk with a fixing pin. Only when the driving shaft pulls the first disk to open the gate flow path, is a force point acting on the first disk spaced apart from a central axis of the driving shaft so as to generate a rotational moment in the first disk. When the central axis of the driving shaft passes through the central point of the first disk, pushes the first disk, and closes the gate flow path, the rotational moment may not be generated.

Description

Gate valve {Gate valve}

The present invention relates to a gate valve, and more particularly, to a gate valve capable of minimizing contact with a seat ring when a disc moves up and down and preventing overload of a drive unit operating a drive shaft when a flow path is opened. will be.

In general, a gate valve refers to a valve that opens and closes a flow path by moving a valve disk in a vertical direction while maintaining the flow of fluid in a horizontal direction without bending, and is used when completely opening or closing the flow path. These gate valves are of the OS&Y (Outside Stem & Yoke) type, in which the flow path opening system bounces up to the top of the valve according to the movement of the stem, which is the drive shaft of the valve disc, and the stem operates only inside the valve, even if the flow path is opened. It can be classified as NRS (Non-Rising Stem) type that does not bounce to the top of the valve. In addition, the gate valve is a solid wedge gate type that operates as a single disk, depending on the shape of the valve disk, and a split gate that can flexibly cope with pressure applied from both sides by forming a gap in the middle of the single disk It can be divided into a (split gate) type and a parallel disk and wedge gate type in which airtightness is improved by generating horizontal force when the gate is closed when it is formed of a pair of disks.

On the other hand, the conventional parallel disk and wedge gate type has the advantage of improving flexibility and airtightness by separating the disk, but the sealing surface is scratched in contact with the seat ring when the disk moves up and down, and the applied pressure of the disk Due to this, there is a problem in that an overload is applied to the drive unit that operates the stem when opening the flow path.

Therefore, there is a need for a gate valve having a structure capable of minimizing contact with the seat ring when the disc moves up and down and preventing overload of a drive unit that operates a stem, which is a drive shaft, when the flow path is opened.

Republic of Korea Patent Publication No. 10-2013-0120171 (2013. 11. 04.)

A technical problem to be achieved by the present invention is to provide a gate valve capable of minimizing contact with a seat ring when a disc moves up and down and preventing overload of a drive unit operating a drive shaft when a flow path is opened.

The technical problems of the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned will be clearly understood by those skilled in the art from the following description.

A gate valve according to an embodiment of the present invention for achieving the above technical problem is a housing in which an inflow passage and an outflow passage are formed on both sides and a gate passage is formed between the inflow passage and the outflow passage, and inside the housing A gate unit that slides to open and close the gate passage, and a drive shaft that passes through the housing and has one end connected to the gate unit and the other end connected to a driving unit outside the housing to slide the gate unit in a vertical direction. And, the gate unit has a first valve surface for sealing any one of the inflow passage and the outflow passage, a first inclined surface is formed on the rear surface of the first valve surface, and a coupling groove to which the driving shaft is coupled is formed. A first disc, a second valve surface for sealing the other of the inflow passage and the outflow passage, and a second inclined surface in contact with the first inclined surface are formed on a rear surface of the second valve surface, and a fixing pin is formed on the first disk. And when the drive shaft pulls the first disc to open the gate passage, the point of force acting on the first disc is spaced apart from the central axis of the drive shaft to generate rotational moment on the first disc. and when the central axis of the drive shaft passes through the central point of the first disk and pushes the first disk to close the gate passage, no rotational moment is generated in the first disk.

The first inclined surface and the second inclined surface form an inclined surface inclined downward or upward along the moving direction of the drive shaft, and at least one of the first disk and the second disk has a coupling hole into which the fixing pin is coupled in a vertical direction. When the first disk moves downward on the gate flow passage, the second disk moves along the first inclined surface so that the second valve face is formed on the inflow passage or the second disk. The outflow passage can be sealed.

In the gate unit, an overlapping thickness of the first disk and the second disk may be greater when closing the gate passage than when opening the gate passage.

According to the present invention, since the surface where the first disk and the second disk come into contact with each other forms an inclined surface, when the first disk moves downward on the gate passage, the second disk moves horizontally to seal the inflow passage or the outflow passage. When the first disk moves up and down, the second disk is lowered down along the inclined surface, so that the overlapping thickness of the first disk and the second disk partially decreases, so that contact between the first disk and the second disk and the seat ring can be minimized. .

In addition, when the driving shaft pulls the first disk upward to open the gate passage, the point of force acting on the first disk is spaced apart from the central axis of the driving shaft and a rotational moment is generated in the first disk, so that the first disk or the second disk The pressure of the applied fluid can be dispersed, and accordingly, the first disk can be lifted with a small force, preventing overload of the driving unit operating the driving shaft.

In addition, since a downwardly convex curved surface is formed on the lower surface of the driving shaft, a uniform sealing force is applied as the first disk is pressed downward, thereby effectively sealing the gate passage.

1 is a perspective view showing a gate valve according to an embodiment of the present invention.
2 is an exploded perspective view of a gate unit and a drive shaft.
3 is a perspective view illustrating a state in which a driving shaft and a fixing pin are coupled to a first disk;
4 is a longitudinal cross-sectional view of a gate unit and a drive shaft.
5 is a rear view of the first disk;
6 to 8 are operation diagrams for explaining the operation of the gate valve.

Advantages and features of the present invention, and methods of achieving them, will become clear with reference to the detailed description of the following embodiments taken in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and only these embodiments make the disclosure of the present invention complete, and common knowledge in the art to which the present invention belongs. It is provided to completely inform the person who has the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numbers designate like elements throughout the specification.

Hereinafter, a gate valve according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 8 .

1 is a perspective view showing a gate valve according to an embodiment of the present invention.

In the gate valve 1 according to the embodiment of the present invention, since the surface where the first disk (see 21 in FIG. 2 ) and the second disk (see 22 in FIG. 2 ) come into contact with each other forms an inclined surface, the first disk 21 When moves downward on the gate passage 10c, the second disk 22 horizontally moves to seal the inflow passage 10a or the outflow passage 10b, and when the first disk 21 moves up and down, the second disk 22 Since (22) is lowered downward along the inclined surface, the overlapping thickness of the first disk 21 and the second disk 22 is partially reduced, so that the first disk 21 and the second disk 22 are seat rings (FIG. 6 11 of) can be minimized. In addition, when the driving shaft 30 pulls the first disk 21 upward to open the gate passage 10c, the point of force acting on the first disk 21 is spaced apart from the central axis of the driving shaft so that the first disk 21 Since a rotational moment is generated in, the pressure of the fluid applied to the first disk 21 or the second disk 22 can be dispersed, and accordingly, the first disk 21 can be lifted with a small force, so that the drive shaft It is possible to prevent an overload of a drive unit (not shown) that operates 30. In addition, since a downwardly convex curved surface (see 31c in FIG. 2 ) is formed on the lower surface of the driving shaft 30, a uniform sealing force is applied as the first disk 21 is pressed downward, effectively closing the gate passage 10c. It has the ability to seal.

Hereinafter, the gate valve 1 will be described in detail with reference to FIGS. 2 to 5 .

2 is an exploded perspective view of a gate unit and a drive shaft, FIG. 3 is a perspective view showing a drive shaft and a fixing pin coupled to a first disk, FIG. 4 is a longitudinal cross-sectional view of the gate unit and the drive shaft, and FIG. 1 This is a rear view of the disk.

The gate valve 1 according to the present invention includes a housing 10, a gate unit 20, and a driving shaft 30, and the gate unit 20 includes a first disk 21 and a second disk 22 includes

The housing 10 forms the exterior of the gate valve 1, and has an inflow passage 10a and an outflow passage 10b formed on both sides, respectively, and a gate passage between the inflow passage 10a and the outflow passage 10b. (10c) can be formed. Here, the inflow passage 10a means an inlet-side passage through which fluid flows, and the outflow passage 10b means an outlet-side passage through which fluid flows out. The inflow passage 10a and the outflow passage 10b are disposed on the same line so that the fluid passes in one direction, and the gate passage 10c is formed between the inflow passage 10a and the outflow passage 10b to form an inflow passage ( 10a) and the guide passage 10d disposed perpendicularly to the outflow passage 10b. The housing 10 may be formed in an inverted 'T' shape or a 'T' shape depending on the location of the guide passage 10d, and the gate unit 20 is accommodated therein.

The gate unit 20 opens and closes the gate passage 10c and can slide vertically inside the housing 10 . For example, when the gate unit 20 accommodated in the guide passage 10d slides downward, the gate passage 10c is closed, and when the gate unit 20 slides upward and is accommodated in the guide passage 10d, The gate passage 10c may be opened. The structure of the gate unit 20 will be described later in more detail. The gate unit 20 can slide and move by the driving shaft 30 .

The drive shaft 30 slides the gate unit 20 in the vertical direction, and penetrates the housing 10 so that one end is connected to the gate unit 20 and the other end is connected to the drive unit outside the housing 10. . That is, when the driving unit provides a driving force, the driving shaft 30 and the gate unit 20 integrally slide in a vertical direction, and accordingly, the gate passage 10c may be opened or closed. The driving unit is disposed outside the housing 10 and may include, for example, a driving motor and a gearbox to slide the driving shaft 30 . However, the driving unit is not limited to including a driving motor and a gearbox, and may be formed in various structures capable of sliding the driving shaft 30 in the vertical direction.

The aforementioned gate unit 20 includes a first disk 21 and a second disk 22 .

The first disk 21 is a plate-like member, and includes a first valve face 211 sealing either one of the inflow passage 10a and the outflow passage 10b, and a first valve face 211 formed on the rear surface of the first valve face 211. 1 may include an inclined surface 212 and a coupling groove 213 to which the driving shaft 30 is coupled. In other words, the first disk 21 has a first valve face 211 formed on one side facing the inflow passage 10a or the outflow passage 10b, and a first inclined surface 212 formed on the other side, A coupling groove 213 is formed at the top or bottom. The second disk 22 is a plate-shaped member, and is formed on a second valve face 221 sealing the other of the inflow passage 10a and the outflow passage 10b and the rear surface of the second valve face 221. Including the second inclined surface 222 in contact with the first inclined surface 212, it may be coupled to the first disk 21 with a fixing pin 23. In other words, the second disk 22 has a second valve face 221 formed on one side facing the outflow passage 10b or the inflow passage 10a, and the second disk 22 in contact with the first inclined surface 212 on the other side. An inclined surface 222 is formed and coupled to the first disk 21 by a fixing pin 23 arranged in a horizontal direction. Hereinafter, the first valve face 211 of the first disk 21 seals the inflow passage 10a, and the second valve face 221 of the second disk 22 seals the outflow passage 10b. is explained more intensively.

The first disk 21 is disposed so that the first valve face 211 faces the inflow passage 10a, and the second disk 22 has the second valve face 221 faces the outflow passage 10b. And, the drive shaft 30 is interposed between the first disk 21 and the second disk 22 and coupled to the coupling groove 213 formed on the top of the first disk 21, the first disk 21, and The second disk 22 coupled to the first disk 21 by the fixing pin 23 may be slid and moved. That is, when the drive shaft 30 pushes the first disk 21 downward, the gate passage 10c is closed, and when the drive shaft 30 pulls the first disk 21 upward, the gate passage 10c is opened. When the drive shaft 30 pulls the first disc 21 to open the gate passage 10c, the point of force acting on the first disc 21 is spaced apart from the central axis of the drive shaft 30 so that the first disc 21 rotational moment can be generated. When the driving shaft 30 passes through the center point of the first disk 21 and pushes the first disk 21 to close the gate passage 10c, no rotational moment is generated in the first disk 21, and the first disk 21 does not generate rotational moment. Rotational moment can be generated in the first disk 21 only when the gate passage 10c is opened by pulling the pull (21). When the drive shaft 30 pulls the first disc 21 to open the gate passage 10c, the point of force acting on the first disc 21 is spaced apart from the central axis of the drive shaft 30 to form the first disc 21. By generating a rotational moment, the pressure of the fluid introduced into the inflow passage 10a and applied to the first disk 21 can be dispersed, and thus, the first disk 21 can be lifted with a small force, thereby increasing the drive shaft It is possible to prevent an overload of the driving unit operating the (30).

More specifically, the driving shaft 30 has an extended end inserted into the gate unit 20 to include an extension 31, and the extension 31 is formed in an inverted 'T' shape to form a first valve face ( 211) may include a first extension portion 31a and a second extension portion 31b extending to both ends around a central axis on a plane parallel to the first extension portion 31a and the second extension portion 31b. The first disk 21 includes a hooking part 214 that the extension part 31 is caught at the entrance of the coupling groove 213, and the hooking part 214 is formed at both ends around the central axis to form the first extension part ( 31a) and the second expansion part 31b may include a first hooking part 214a and a second hooking part 214b, respectively. In this case, the distance between the first expansion part 31a and the first clasp 214a and the distance between the second extension part 31b and the second clasp 214b may be formed to be different from each other. For example, as shown in FIG. 5, the thickness of the second hooking part 214b is thicker than that of the first hooking part 214a so that there is a gap between the second extension part 31b and the second hooking part 214b. The distance may be smaller than the distance between the first expansion part 31a and the first hanging part 214a. Accordingly, when the driving shaft 30 rises, the second expansion part 31b is caught by the second hooking part 214b, and rotational moment may be generated in the first disk 21 in a counterclockwise direction. However, since the thickness of the second extension 31b is thicker than the first extension 31a, the distance between the second extension 31b and the second hooking portion 214b is larger than that of the first extension 31a. It is not limited to being smaller than the distance between the first hooking parts 214a, and the structure may be variously modified. For example, the thickness of the first expansion part 31a is thicker than that of the second expansion part 31b, so that the distance between the first expansion part 31a and the first hooking part 214a is reduced. ) and the second hooking portion 214b may be formed smaller than the distance between them. When the distance between the first extension part 31a and the first hooking part 214a is smaller than the distance between the second extension part 31b and the second hooking part 214b, the driving shaft 30 will rise. When the first expansion part 31a is caught by the first hooking part 214a, rotational moment may be generated in the first disk 21 in a clockwise direction.

In addition, when the extension part 31 pushes the first disk 21 to close the gate passage 10c, a downwardly convex curved surface 31c may be formed on a bottom surface in contact with the first disk 21 . Since the bottom surface of the extension part 31 is formed as a curved surface 31c, when the drive shaft 30 presses the first disk 21, the center point of the first disk 21 is pressed, and accordingly, the first disk ( As 21) is pressed downward, a uniform sealing force is imparted, so that the gate passage 10c can be effectively sealed.

The above-described first inclined surface 212 and the second inclined surface 222 form an inclined surface inclined downward or upward along the moving direction of the drive shaft 30, and at least one of the first disk 21 and the second disk 22 One coupling hole 215 to which the fixing pin 23 is coupled may be formed of a long hole extending in the vertical direction. Hereinafter, the first inclined surface 212 forms an inclined surface inclined upward along the moving direction of the drive shaft 30, and the second inclined surface 222 forms an inclined surface inclined downward along the moving direction of the driving shaft 30. And, the structure in which the coupling hole 215 is formed in the first disk 21 will be described with more emphasis.

The first inclined surface 212 may form an inclined surface inclined upward from the lower part toward the upper part, and the second inclined surface 222 may form an inclined surface inclined downward from the upper part toward the lower part and contact each other. The first disk 21 is formed of a long hole in which a coupling hole 215 to which a fixing pin 23 is coupled extends in the vertical direction, and the coupling hole 215 is connected to the first valve surface 211 and 1 may penetrate between the inclined surfaces 212 in the horizontal direction. In the second disk 22, a fixing groove 223 to which a fixing pin 23 is coupled is formed in a circular shape, and the fixing groove 223 is recessed in the second inclined surface 222 and has a screw thread on the inner peripheral surface. It can be formed and screwed with the fixing pin 23. The first inclined surface 212 and the second inclined surface 222 each form an inclined surface and come into surface contact with each other, the coupling hole 215 is made of a long hole extending in the vertical direction, and the fixing groove 223 is a fixing pin 23 ), the second disk 22 can be moved from the first disk 21. More specifically, when the first disk 21 moves downward on the gate passage 10c and is supported inside the housing 10, the second disk 22 has a second inclined surface 222 that is aligned with the first inclined surface 212. The second valve face 221 moves horizontally by moving along and may seal the outflow passage 10b. In addition, when the gate unit 20 moves up and down on the gate passage 10c, the lower end of the second disk 22 is lowered than the first disk 21 due to its own weight, so that the first disk 21 The overlapping thickness of the and the second disk 22 may be partially reduced to minimize contact between the first disk 21 and the second disk 22 and the seat ring 11 . That is, in the gate unit 20, the overlapping thickness of the first disk 21 and the second disk 22 is greater when closing the gate passage 10c than when opening the gate passage 10c, and because of this, , It is possible to prevent damage to the seat ring 11 by reducing interference with the seat ring 11 when the gate unit 20 moves while effectively sealing the gate passage 10c.

Hereinafter, the operation of the gate valve 1 will be described in more detail with reference to FIGS. 6 to 8 .

6 to 8 are operation diagrams for explaining the operation of the gate valve.

In the gate valve 1 according to the present invention, since the surface where the first disk 21 and the second disk 22 come into contact with each other forms an inclined surface, when the first disk 21 moves downward on the gate passage 10c, The second disk 22 not only moves horizontally to seal the inflow passage 10a or the outflow passage 10b, but also when the first disk 21 moves up and down, the second disk 22 is lowered down along the inclined surface to remove the Since the overlapped thickness of the first disk 21 and the second disk 22 is partially reduced, contact between the first disk 21 and the second disk 22 and the seat ring 11 can be minimized. In addition, when the drive shaft 30 pulls the first disc 21 upward to open the gate passage 10c, the point of force acting on the first disc 21 is spaced apart from the central axis of the drive shaft 30 to open the first disc 21. Since rotational moment is generated in (21), the pressure of the fluid applied to the first disk 21 or the second disk 22 can be dispersed, and accordingly, the first disk 21 can be lifted with little force. Therefore, it is possible to prevent an overload of the drive unit for operating the drive shaft 30 . In addition, since a downwardly convex curved surface 31c is formed on the lower surface of the drive shaft 30, a uniform sealing force is applied as the first disk 21 is pressed downward, thereby effectively sealing the gate passage 10c. .

6 is a view showing an operation when the gate unit closes the gate passage, FIG. 7 is a view showing an operation when the gate unit opens the gate passage, and FIG. 8 is a view showing an operation when the drive shaft pulls the first disk It is a view showing a state in which rotational moment is generated in the first disk when it is opened.

First, referring to FIG. 6 , when the driving unit lowers the drive shaft 30 downward, the first disk 21 connected to the drive shaft 30 and the second disk 22 connected to the first disk 21 are integrally formed. It is lowered into the gate passage 10c. At this time, since the lower end of the second disk 22 is lowered lower than the first disk 21 by its own weight, the overlapping thickness of the first disk 21 and the second disk 22 is partially reduced, thereby reducing Because of this, when the first disk 21 and the second disk 22 are lowered into the gate passage 10c, they do not come into contact with the seat rings 11 disposed on both sides of the gate passage 10c, and thus the seat ring 11 scratches, etc. are prevented. When the driving shaft 30 is lowered downward, as shown in FIG. supported

When the driving shaft 30 is further lowered downward in a state where the lower end of the second disk 22 touches the inner surface of the housing 10 and is supported, as shown in FIG. 6(b), the first disk 21 The lower end of the housing 10 is also supported in contact with the inner surface. Even when the lower end of the first disc 21 touches the inner surface of the housing 10 and is supported, when the drive shaft 30 is further lowered downward, the extension part 31 presses the center point of the first disc 21 to make it uniform. At the same time as applying a sealing force, the second inclined surface 222 of the second disk 22 moves along the first inclined surface 212 so that the second valve surface 221 moves horizontally and seals the outflow passage 10b. can do. That is, since the first valve face 211 seals the inflow passage 10a and the second valve face 221 seals the outflow passage 10b to close the gate passage 10c, outflow occurs from the inflow passage 10a. The flow of fluid to the flow path 10b is restricted.

Subsequently, referring to FIG. 7 , when the drive unit lifts the drive shaft 30 upward, the first disk 21 and the second disk 22 are also raised. At this time, as shown in FIG. 8 , the distance between the second extension part 31b and the second hooking part 214b is greater than the distance between the first extension part 31a and the first hooking part 214a. Since the second expansion part 31b is small and caught on the second hooking part 214b first, a rotational moment is generated in the first disk 21 in a counterclockwise direction, and as a result, the fluid applied to the first disk 21 Since the pressure is dispersed, the first disk 21 can be lifted with little force. When the driving shaft 30 lifts the first disk 21, the second inclined surface 222 of the second disk 22 moves along the first inclined surface 212 by its own weight, so that the lower end of the first disk 21 It is in a lowered state, and because of this, the overlapping thickness of the first disk 21 and the second disk 22 is partially reduced, so that it can move upward without contacting the seat ring 11. As the gate passage 10c is opened by lifting the first disk 21 and the second disk 22, fluid may flow from the inflow passage 10a to the outflow passage 10b.

Although the embodiments of the present invention have been described with reference to the accompanying drawings, those skilled in the art to which the present invention pertains can be implemented in other specific forms without changing the technical spirit or essential features of the present invention. you will be able to understand Therefore, the embodiments described above should be understood as illustrative in all respects and not limiting.

1: gate valve
10: housing 10a: inflow passage
10b: outflow passage 10c: gate passage
10d: guide passage 11: seat ring
20: gate unit 21: first disk
211: first valve surface 212: first inclined surface
213: coupling groove 214: hanging part
214a: first hooking part 214b: second hooking part
215: coupling hole 22: second disk
221: second valve surface 222: second inclined surface
223: fixing groove 23: fixing pin
30: drive shaft 31: extension
31a: first extension 31b: second extension
31c: curved surface

Claims (3)

a housing having an inflow passage and an outflow passage formed on both sides thereof and a gate passage formed between the inflow passage and the outflow passage;
A gate unit that slides inside the housing to open and close the gate passage, and
In the gate valve including a drive shaft penetrating the housing, one end connected to the gate unit and the other end connected to a drive unit outside the housing to slide the gate unit in a vertical direction,
The gate unit,
A first valve surface sealing any one of the inflow passage and the outflow passage, a first disk having a first inclined surface formed on a rear surface of the first valve surface and a coupling groove to which the driving shaft is coupled;
A second valve surface for sealing the other one of the inflow passage and the outflow passage, and a second inclined surface in contact with the first inclined surface are formed on the rear surface of the second valve surface and coupled to the first disc with a fixing pin. contains 2 discs,
When the drive shaft pulls the first disc to open the gate passage, a force point acting on the first disc is spaced apart from the central axis of the drive shaft to generate a rotational moment in the first disc;
When the central axis of the drive shaft passes through the central point of the first disk and pushes the first disk to close the gate passage, a rotational moment is not generated in the first disk. According to claim 1,
The first inclined surface and the second inclined surface form an inclined surface inclined downward or upward along the moving direction of the drive shaft,
At least one of the first disk and the second disk is composed of a long hole in which a coupling hole to which the fixing pin is coupled extends in a vertical direction,
When the first disk moves downward on the gate flow passage, the second disk moves along the first inclined surface so that the second valve surface closes the inflow passage or the outflow passage. . According to claim 2,
In the gate unit, the overlapping thickness of the first disk and the second disk is greater when closing the gate passage than when opening the gate passage.

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