KR20090049282A - Vacuum gate valve - Google Patents

Abstract

A vacuum gate valve is disclosed that opens and closes a fluid passage between a vacuum chamber and a vacuum pump. The vacuum gate valve of the present invention includes a valve body having a sliding space formed in a direction perpendicular to the fluid passage on an inner wall where the fluid passage is formed, a valve plate for opening and closing the fluid passage as it is advanced back and forth into the sliding space, and the valve plate. In the vacuum gate valve comprising a valve plate driving unit for driving, a sealing member for opening and closing the sliding space as the lifting and lowering in a direction parallel to the fluid passage, and a sealing member driving unit for driving the sealing member, the valve plate, It is elastically supported on the outer side of the upper surface and the lower surface so as to flow up and down in the sliding space, the lifting and lowering is limited by the inner wall surface of the valve body located on the upper and lower portions of the sliding space, the sealing member, The upper end surface is formed lower than the inner wall surface of the valve body which is located below the sliding space, the upper end The sealing material is provided in the. As a result, even when the pressure difference between the inlet and the outlet is large, or particularly a back pressure is applied, the valve functions smoothly.

Valve plate, sealing member, back pressure, elastic spring, compressed air inlet

Description

VACUUM GATE VALVE

The present invention relates to a vacuum gate valve, and more particularly to a vacuum gate valve for smoothly performing the opening and closing operation of the gate valve in the gate valve provided between the vacuum chamber and the vacuum pump.

Vacuum gate valves are used to maintain the vacuum of the vacuum chamber used in the semiconductor process. The fluid in the vacuum chamber discharged through the vacuum gate valve contains various by-products. These by-products are continuously attached to the link of the actuator for driving the valve plate of the gate valve or the inner wall of the housing in which the valve plate slides to prevent the forward and backward operation of the valve plate when the fluid is discharged, thereby opening and closing the space in which the valve plate slides. A sealing member was needed.

As a technology for the sealing member, the Republic of Korea Patent No. 0620726 (name of the invention: flow rate control valve), and the Republic of Korea Patent No. 0717865 for preventing the valve damage due to the pressure difference when the gate valve is suddenly opened in the patent (Name of the invention: improved anti-corrosion vacuum gate valve) and the like.

Looking at the technical configuration of the 'improved corrosion prevention vacuum gate valve' with reference to Figure 1 (open state) and Figure 2 (closed state), the fluid passage 110 is connected to the vacuum chamber and the vacuum pump is formed A housing 100 having a sliding space 130 penetrating the fluid passage 110 in an orthogonal direction; A valve plate 200 inserted into the sliding space 130 to open and close the fluid passage 110; A first actuator 400 driving the valve plate 200; A sealing member 500 that vertically moves in a direction parallel to the fluid passage 110 and opens and closes the sliding space 130; And a second actuator (600) for moving the sealing member (500) in a vertical direction. The second actuator (600) includes a second for moving the sealing member (500) in a upward direction. A hollow first body 610 having a compressed air inlet formed therein; and a third compressed air inlet for moving the sealing member 500 downward; a fluid is moved from the vacuum chamber to the vacuum pump at an upper end thereof; It comprises; a hollow second body 620 is formed with one or more flow control grooves 625 to.

In particular, as shown in Figure 3, when opening the valve part of the fluid in the upper valve plate 200 is discharged to the lower through the flow control groove 625 it is possible to prevent the valve damage due to the sudden opening of the valve There is a main feature of the invention in this respect. That is, when the valve is normally closed, the pressure of the vacuum pump side is higher than the vacuum chamber side pressure, so that the valve plate 200 is pushed upward by the pressure difference, thereby maintaining the airtightness.

In addition, since the elastic plate 240 is provided at the upper end of the valve plate 200 and the valve plate 200 descends by the elastic force when the sealing member 500 descends while the valve is closed, the valve plate 200 moves forward and backward. Another feature is that there is no interference with the housing 100.

However, the prior art has a problem in the following points.

First, when the valve is in an abnormal state except the normal case, that is, the inlet pressure is higher than the outlet pressure (hereinafter, this case is referred to as 'Back Pressure') valve plate ( As the 200 is pushed downward, the fluid in the vacuum chamber is discharged through the flow regulating groove 625, so there is a problem in that airtightness cannot be maintained.

Second, when the valve is normally closed, the valve plate 200 is forced upward by the pressure difference. In the state where the pressure difference is very large, the force pushing the valve plate 200 upward by the pressure difference is the elastic sphere. 240 is greater than the force pushing the valve plate 200 downward, even if the sealing member 500 is lowered in order to open the valve, the upper end of the valve plate 200 abuts the housing 100 to the valve plate ( The reverse of 200 may not be performed smoothly.

The present invention is to solve the problems of the prior art of the above-mentioned background, when the valve to open the pressure plate to reduce the pressure difference between the upper and lower valve plate to facilitate the reverse, at the same time abnormal back pressure in the closed state valve It is an object of the present invention to provide a vacuum gate valve having an improved structure of the sealing member so that the valve plate is kept airtight even if the valve plate is moved downward.

As described above, the vacuum gate valve of the present invention for solving the problems of the background art, the valve body is formed with a sliding space in the direction perpendicular to the fluid passage on the inner wall in which the fluid passage is formed, the fluid as it is advanced back and forth into the sliding space A valve plate for opening and closing a passage, a valve plate driving portion for driving the valve plate, a sealing member for opening and closing a sliding space as it moves up and down in a direction parallel to the fluid passage, and a sealing member driving portion for driving the sealing member. In the vacuum gate valve, the valve plate is elastically supported on the outer side of the upper surface and the lower surface so as to flow up and down in the sliding space, the valve plate is lifted by the inner wall surface of the valve body located in the upper and lower portions of the sliding space The lowering is limited, the sealing member, the upper surface of the lower when the lower sliding space Which is formed below the inner wall surface of the valve body, it characterized in that the sealing member is provided on its upper end.

In addition, the sealing material of the present invention is characterized in that the O-ring.

In addition, the sealing member driving means of the present invention is characterized in that it is composed of an elastic spring for applying an elastic force to the sealing member or a compressed air inlet for applying a compressive force to the sealing member.

In addition, at least one elastic spring is inserted between the upper portion of the sealing member and the valve body to lower the sealing member of the present invention, and the compressed air in the space between the lower portion of the sealing member and the valve body to lift the sealing member. Characterized in that the inlet is formed.

In addition, the elastic spring of the present invention is characterized in that the coil spring or the leaf spring is installed at equal intervals between at least three places between the upper portion of the sealing member and the valve body.

According to the vacuum gate valve of the present invention, the valve plate can be positioned in the center of the slide space even if the pressure difference between the fluid in the inlet and the outlet is large when the valve is opened, so that the valve is smoothly opened. Even when a back pressure is applied to the valve plate and the sealing member, the valve plate and the sealing member are in close contact with each other, as well as maintaining the airtightness of the valve.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 4 is a schematic configuration diagram showing an open state of the gate valve according to an embodiment of the present invention, Figure 5 is a cross-sectional view showing a state in which the valve plate entered the sliding space.

In the vacuum gate valve of the present invention, as shown in FIGS. 4 and 5, the sliding space 14 in the vertical direction of the fluid passage 11 and the fluid passage 11 is basically formed at the outer circumference of the fluid passage 11. An extended valve body 10, a valve plate 20 for opening and closing the fluid passage 11 as it is advanced back and forth within the sliding space 14, and a valve plate driver 40 for driving the valve plate 20. ), And a sealing member 50 for opening and closing the sliding space 14 and a sealing member driving part 60 for driving the sealing member 50 as the lifting and lowering in a direction parallel to the fluid passage 11.

Since this basic configuration is the same as the conventional technology described as the background art, the following description will focus on the configuration different from the prior art and its effects.

A characteristic configuration of the present invention has the following points.

(1) In the state where the valve plate 20 is inserted into the sliding space 14, the valve plate 20 may be moved up and down by the pressure difference in the fluid passage 11 or the lifting force of the sealing member 50. It is configured to be.

Specifically, the valve plate 20 is the spring 22 is elastically supported by the spring fastening member 21 on the outer side of the upper surface and the lower surface, respectively. Therefore, when an external force acts on the upper or lower surface of the valve plate 20, that is, a pressure difference occurs between the inlet 12 and the outlet 13 constituting the fluid passage 11, or the sealing member 50. When it rises, it is configured to be able to move up and down as it is stretched up or down by the spring 22. According to the embodiment of the present invention, as shown in FIG. 4, the valve plate 20 has a rectangular plate shape, and the spring 22 and the spring fastening member 21 are installed at four corners.

At this time, the valve plate 20 is limited by the rising and falling by the inner wall surface 15 of the valve body 10 which is located in the upper and lower portions of the sliding space (14). Therefore, the valve plate 20 is configured to move up and down in the sliding space 14 space by the valve plate driving part 40 and move up and down, that is, in the state inserted into the sliding space 14.

(2) When the sealing member 50 of the present invention is lowered to the lowest position, the upper end surface of the sealing member 50 is formed lower than the inner wall surface 15 of the valve body 10 located below the sliding space 14 It is in that.

This is when the pressure (hereinafter referred to as 'back pressure') in the direction of the valve plate 20 inserted into the sliding space 14, that is, in the inlet portion 12 toward the outlet portion 13 (hereinafter referred to as 'back pressure') To prepare. Specifically, when the valve plate 20 is to be opened in the state in which the reverse pressure is applied, the valve plate 20 is in close contact with the sealing member 50 at the lower portion, so that the valve plate 20 cannot be smoothly reversed, and if the valve plate 20 is Forcibly reversing) causes a breakdown of the valve due to a sudden pressure difference, so it is necessary to design for the case of such a back pressure.

When the sealing member 50 is lowered to the lowest position in such a state that the reverse pressure is applied, the inlet portion (10) is discharged as a small amount of fluid in the inlet portion 12 is discharged into the outlet portion 13 through the sliding space (14). As the pressure difference between 12 and the outlet part 13 is gradually reduced, the valve plate 20 is positioned at the center of the sliding space 14 by the elastic force, so that the reverse of the valve plate 20 is smoothly performed.

On the other hand, a sealing material is installed on the upper end of the sealing member 50. According to the embodiment of the present invention, the O-ring is used as the sealing material, but is not limited thereto. This is in order to maintain perfect air tightness by bringing the O-ring of the lower surface of the valve plate 20 and the sealing member 50 in close contact with the valve.

(3) The sealing member driving part 60 for raising and lowering the sealing member 50 may be constituted by an elastic spring 61 that exerts an elastic force, or may form a compressed air inlet 62 that is supplied from the outside. And these structures can be used in combination.

According to one embodiment of the present invention, the elastic spring 61 is inserted between the outer upper portion of the sealing member 50 and the valve body 10 as a configuration for lowering the sealing member 50, on the contrary, the sealing member 60 Compressed air inlet portion 62 is formed between the outer lower portion of the sealing member 50 and the valve body 10 as a configuration for raising (). Therefore, when compressed air is supplied to the compressed air inlet 62, the sealing member 50 is raised to be in close contact with the valve plate 20, and the elastic spring is not applied to the valve plate 20. The valve plate 20 is lowered by 61.

 Meanwhile, as shown in FIG. 5, the elastic spring 61 may be configured as one coil spring having a larger diameter than the fluid passage 11 between the outer upper portion of the sealing member 50 and the valve body 10. However, the present invention is not limited thereto.

According to another embodiment of the present invention, the plate spring 63 is installed at equal intervals between at least three places between the upper portion of the sealing member 50 and the valve body 10, and formed at the upper end of the plate spring 63. The holder 64 may be given an elastic force that lowers the sealing member 50. At this time, the reason for installing three or more leaf springs 63 is to apply an even force to the sealing member (50). 8 shows a state in which the six leaf springs 63 are installed at equal intervals.

9 illustrates a gate valve in which the leaf spring 63 is installed, and the left part of the valve valve 20 moves forward while the sealing member 50 is lowered by the elastic force of the leaf spring 63. The right part shows a state in which the compressed air is supplied to the compressed air inlet 62 while the valve plate 20 is reversed to overcome the elastic force of the leaf spring 63 and the sealing member 50 is raised.

Hereinafter, the opening / closing operation of a valve using a vacuum gate valve using one coil spring as the elastic spring 61 of the present invention configured as described above will be described with reference to FIGS. 6A to 6B and FIG. 5. For reference, even in the case of the gate valve using the leaf spring 63 as shown in FIG. 9, the opening and closing operation is the same as the description below, the description thereof will be omitted.

First, as shown in FIG. 6A, in the open state of the valve, compressed air is supplied to the compressed air inlet 62 so that the sealing member 50 is raised, and the upper end of the inner wall surface 15 of the upper portion of the slide space 14. In close contact with the slide space 14 to maintain a closed state.

Next, as shown in FIG. 6B, when the compressed air is blocked to close the valve, the sealing member 50 is lowered due to the elastic force of the elastic spring 61 to open the slide space 14.

Then, as shown in FIG. 6C, the valve plate 20 is advanced and inserted into the inner center of the slide space 14.

Finally, as shown in FIG. 6D, when compressed air is supplied to the compressed air inlet 62, the sealing member 50 rises to compress the upper elastic spring 61 and then the valve plate 20. By compressing the spring 22 installed on the outer surface of the upper surface to maintain the airtight of the fluid passage 11 to complete the closing operation of the valve.

At this time, the three arrows displayed at the bottom of the valve plate 20 indicate the direction of the force applied to the valve plate 20, which is usually connected to the inlet part 12 and the vacuum pump connected to the vacuum chamber (not shown) to maintain a vacuum state. This is due to the pressure difference between the outlet 13 connected (not shown).

Contrary to the above-mentioned valve closing operation, the valve opening operation proceeds in the order of Figs. 6D → 6C → 6B → 6A in contrast to the above operation. According to the present invention, even if a force acts from the bottom of the valve plate 20 to the upper portion as shown in FIG. Since it is discharged to the inlet 12 through the pressure difference between the outlet 13 and the inlet 12 is eliminated so that the valve plate 20 is located in the center of the sliding space. Therefore, the valve plate 20 can be reversed without any interference, so the valve is opened smoothly.

On the other hand, as shown in Figure 7a, due to the pressure difference between the inlet portion 12 and the outlet portion 13 back pressure greater than the elastic force of the spring 22 of the lower outer side of the valve plate 20 to the valve plate 20 When applied, the lower surface of the valve plate 20 is in close contact with the inner wall surface 15 under the slide space 14. However, as shown in FIG. 7B, as the sealing member 50 is lowered by the elastic spring 61 of the upper part of the sealing member 50, the high pressure fluid inside the inlet part 12 slides in the sliding space ( The pressure difference between the inlet 12 and the outlet 13 is eliminated as it is discharged into the outlet 13 through 14. Thereafter, as shown in FIG. 7C, the valve plate 20 is positioned at the center of the sliding space 14 by the elastic force of the spring 22 provided outside the lower surface of the valve plate 20. Therefore, the reverse of the valve plate 20 for the later opening of the valve can be made smoothly.

As described above, specific details for the implementation of the present invention are merely specific examples of the present invention, and various modifications may be made without departing from the scope of the technical idea of the present invention.

The vacuum gate valve of the present invention can be usefully used in the semiconductor and LCD equipment industry as a device accompanying a vacuum chamber.

1 is a cross-sectional view showing an open state of a conventional gate valve.

2 is a cross-sectional view showing a sealed state of a conventional gate valve.

Figure 3 is a cross-sectional view showing a state in which the fluid moves through the flow control groove when lowering the sealing member for opening in a closed state of the conventional gate valve.

4 and 5 are schematic configuration diagrams showing an open state of a gate valve according to an embodiment of the present invention, and a sectional view showing a state in which the valve plate is advanced into the sliding space.

6a to 6d are cross-sectional views showing the operation sequence of the gate valve according to an embodiment of the present invention.

7A to 7C are cross-sectional views showing an operation sequence when a back pressure is applied in a closed state of a gate valve according to an embodiment of the present invention.

8 and 9 are schematic configuration diagrams showing a state in which the leaf spring is installed between the upper portion of the sealing member and the valve body as another embodiment of the present invention, and the state in which the valve plate is advanced (left) and retracted into the sliding space ( Cross-sectional view of the right side).

<Description of Symbols for Main Parts of Drawings>

10: valve body

11: fluid passage

12: inlet

13: outlet

14: sliding space

15: inner wall surface

20: valve plate

21: spring fastening member

22: spring

30: link member

40: valve plate driving part

50: sealing member

60: sealing member drive unit

61: elastic spring

62: compressed air inlet

63: leaf spring

Claims (5)

A valve body having a sliding space formed in a direction perpendicular to the fluid passage on the inner wall where the fluid passage is formed, a valve plate for opening and closing the fluid passage as it is advanced back and forth into the sliding space, a valve plate driving portion for driving the valve plate, and In the vacuum gate valve comprising a sealing member for opening and closing the sliding space as the lifting and lowering in a direction parallel to the fluid passage, and a sealing member driving unit for driving the sealing member, The valve plate is elastically supported at the outside of the upper surface and the lower surface so as to flow up and down in the sliding space, the lifting and lowering is limited by the inner wall surface of the valve body located on the upper and lower portions of the sliding space, The sealing member, the lower end of the vacuum gate valve is characterized in that the upper surface is formed lower than the inner wall surface of the valve body located below the sliding space, the sealing material is provided on the upper end. The method according to claim 1, The sealing material is a vacuum gate valve, characterized in that the O-ring. The method according to claim 1, The sealing member driving means is a vacuum gate valve, characterized in that composed of an elastic spring for applying an elastic force to the sealing member or a compressed air inlet for applying a compressive force to the sealing member. The method according to claim 3, At least one elastic spring is inserted between the upper end of the sealing member and the valve body to lower the sealing member, and the compressed air inlet is formed in the space between the lower end of the sealing member and the valve body to raise and lower the sealing member. Vacuum gate valve. The method according to claim 4, The elastic spring is a vacuum gate valve, characterized in that the coil spring or a leaf spring is installed at at least three places between the upper portion of the sealing member and the valve body at equal intervals.

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