KR20120019707A - A gate valve - Google Patents

Abstract

PURPOSE: A gate valve is provided to easily return a fluid path sealing member to a slide space of a first actuator when opening a fluid path closed with the fluid path sealing member. CONSTITUTION: A gate valve comprises a housing(130), a fluid path sealing member(140), a first actuator(150), an anti-corrosion sealing member(160), and a second actuator(170). The housing has a fluid path(110) connected to an inlet part(111) and an outlet part(112) and a slide space(120) bored in a direction perpendicular to the fluid path. The fluid path sealing member is inserted in the slide space in order to open and close the fluid path. The first actuator transfers the fluid path sealing member within the slide space. The anti-corrosion sealing member vertically moves in the fluid path when the fluid path sealing member closes the fluid path in order to raise the fluid path sealing member to the inlet part and open/close the slide space. The second actuator drives the anti-corrosion sealing member up and down.

Description

A gate valve

The present invention relates to a gate valve, and more particularly to a gate valve that can be easily returned to the slide space during the opening operation in a state in which the fluid passage sealing member for opening and closing the fluid passage in the fluid passage closed state It is about.

In general, since semiconductors require high precision, high cleanliness and special manufacturing techniques are required. For this reason, the semiconductor device is manufactured in a vacuum state that can completely block the contact of foreign matter contained in the air, and the vacuum working area of the semiconductor manufacturing apparatus and the sealing technology between the atmosphere also affect the quality of the semiconductor product.

Therefore, the gate valve, which is installed between the chamber in which the semiconductor element integration process is performed and the vacuum pump that sucks air in the chamber, plays an important role because the gate valve that opens and closes the transfer of suction power of the vacuum pump to the chamber plays an important role. Efforts to maintain this problem has also emerged as an important problem, and in order to solve the above problems, Patent No. 10-0717865 discloses an improved anti-corrosion vacuum gate valve.

Hereinafter, a conventional gate valve will be described with reference to the accompanying drawings.

1 to 3 is a view showing a conventional gate valve.

As shown in Figures 1 to 3, the conventional gate valve, the fluid passage 10 is formed between the chamber and the vacuum pump is formed, the slide space 20 through the fluid passage 10 in the orthogonal direction Is formed in the housing 30, the fluid passage sealing member 40 inserted into the slide space 20 to open and close the fluid passage 10, and the first actuator 50 for driving the fluid passage sealing member 40. A second actuator for vertically moving in a direction parallel to the fluid passage 10 and moving the anti-corrosion sealing member 60 to open and close the slide space 20 and moving the anti-corrosion sealing member 60 in a vertical direction. And 70.

Here, the fluid passage sealing member 40 is coupled to the first actuator 50 is coupled to the upper end of the frame 41 for moving the slide space 20 is sealed plate 42 for opening and closing the fluid passage 10 The seal plate 42 is elevated by a predetermined distance in accordance with the vertical movement of the anti-corrosion sealing member 60 to completely seal the fluid passage (10). In addition, the second actuator 70 moves the first hollow body 71 and the anti-corrosion sealing member 60 formed therein with a compressed air inlet for moving the anti-corrosion sealing member 60 upward. The compressed air inlet is formed to move and prevents damage to the valve due to sudden opening of the valve through the hollow second body 72 having at least one flow control groove 72a for moving the fluid from the vacuum chamber to the vacuum pump. do.

However, in the conventional gate valve as described above, when the fluid passage sealing member 40 opens the fluid passage 10, the pressure inside the inlet of the fluid passage 10 is greater than the pressure inside the outlet (vacuum at the outlet side). By the operation of the pump), the sealing plate 42 is pushed downward to be in close contact with the second body 72 in which the flow control groove 72a is formed, the slide space 20 by the first actuator 50 When moving to the fluid passage sealing member 40 is a problem that can not be smoothly backed to the slide space 20 by the interference with the second body (72).

In addition, as described above, when the fluid passage sealing member 40 does not smoothly retract to the slide space 20 and the opening of the fluid passage 10 is not made, the operation of the components is caused, thereby precisely controlling the gas supply. This cannot be done, which in turn lowers the productability of the semiconductor device or wafer.

Accordingly, an object of the present invention is to provide an interference preventing roller during an opening operation in a state in which the fluid passage is closed through a plurality of interference prevention rollers arranged vertically in a vertical direction to the plate of the fluid passage sealing member which opens and closes the fluid passage within the fluid passage. It is to provide a gate valve that allows the slide along the lower wall of the slide space can be easily returned to the slide passage the fluid passage sealing member.

Meanwhile, the object of the present invention is not limited to the above-mentioned objects, and other objects not mentioned can be clearly understood by those skilled in the art from the following description.

According to the present invention, a housing having a fluid passage connected to the inlet connected to the chamber and the outlet connected to the vacuum pump and a slide space penetrating the fluid passage perpendicularly; A fluid passage sealing member inserted into the slide space to open and close the fluid passage; A first actuator for moving the fluid passage sealing member in the slide space; The anti-corrosion sealing member is provided on the lower side of the fluid passage so that the fluid passage sealing member vertically moves the fluid passage space when the fluid passage sealing is closed, thereby elevating the fluid passage sealing member to be in close contact with the inlet and simultaneously opening and closing the slide space. ; And a second actuator for driving the corrosion preventing sealing member up and down; The fluid passage sealing member may include a plate that moves the slide space and opens and closes the fluid passage according to the operation of the first actuator; A shaft extending from one side of the plate and connected to a first actuator and receiving a driving force of the first actuator to move the plate to a slide space; A frame provided on the plate; A plurality of traveling rollers provided horizontally in the left and right directions on the left and right frames of the frame of the plate so as to stably slide along the left and right walls of the slide space; And a plurality of anti-interference rollers provided at an end of the left and right frames of the frame of the plate and vertically perpendicularly to the plate in the rear frame so as to stably slide along the lower wall or the upper and lower wall of the slide space. do.

Therefore, according to the present invention, through the plurality of interference prevention rollers vertically arranged in the vertical direction to the plate of the fluid passage sealing member for opening and closing the fluid passage, the interference prevention roller slides during the opening operation in the state in which the fluid passage is closed The fluid passage sealing member can be easily returned to the slide space on the first actuator side by sliding along the lower wall of the space.

In addition, by forming a pressure adjusting hole in the corrosion-proof sealing member for sealing the slide space of the fluid passage sealing member for opening and closing the fluid passage in the fluid passage to suppress the occurrence of pressure difference between the fluid passage and the slide space particles in the slide space This can be prevented from entering.

In addition, the heating member is provided on the flange of the fluid passage sealed by the fluid passage sealing member to prevent particles from being deposited by heat provided to the fluid passage sealing member to optimize the performance of the valve.

On the other hand, the effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the description of the claims.

1 to 3 show a conventional gate valve;
4 is a perspective view showing a gate valve according to a preferred embodiment of the present invention;
5 to 7 are perspective cross-sectional views, side cross-sectional views, and perspective views showing the upper wall of the slide space, respectively, showing the gate valve of FIG. 4; And
8 to 10 are a plan view and a side cross-sectional view of the upper wall of the slide space opened showing the state when the fluid passage is closed and opened in the gate valve of FIG. 4, respectively.

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

4 is a perspective view showing a gate valve according to a preferred embodiment of the present invention, FIGS. 5 to 7 are perspective cross-sectional views, side cross-sectional views, and perspective views showing the upper side walls of the slide space, respectively, showing the gate valve of FIG. 8 to 10 are plan and side cross-sectional views, respectively, in which the upper wall of the slide space showing the state when the fluid passage is closed and opened in the gate valve of FIG. 4 is opened.

As shown in Figure 4 to 10, the gate valve according to a preferred embodiment of the present invention, the inlet 111 is connected to the chamber (not shown) and the outlet 112 is connected to the vacuum pump (not shown) A housing 130 having a fluid passage 110 having a) and a slide space 120 penetrating orthogonal to the fluid passage 110, and inserted into the slide space 120 to open and close the fluid passage 110. The fluid passage sealing member 140, the first actuator 150 for moving the fluid passage sealing member 140 in the slide space 120, the lower portion of the fluid passage 110 is provided in the fluid passage sealing member ( When the fluid passage 110 is closed, the fluid passage 110 vertically moves to close the fluid passage sealing member 140 so that the fluid passage sealing member 140 is brought into close contact with the inlet 111, and at the same time, the slide space 120 is opened and closed. The anti-sealing member 160 and the corrosion-resistant sealing member 160 are vertically And a second actuator (170) to.

On the other hand, the gate valve is in an oblique direction inclined to communicate the fluid passage 110 and the slide space 120 from the outside of the corrosion-proof sealing member 160 to the inside of the upper portion of the corrosion-resistant sealing member 160. When the fluid passage 110 is opened and closed so that the fluid in the fluid passage 110 and the slide space 120 is pumped by a vacuum pump to generate a pressure difference between the fluid passage 110 and the slide space 120 It is preferable to further include a pressure adjusting hole 180 to suppress.

In addition, the gate valve is provided on a flange (unsigned) of the fluid passage 110 to which the inlet 111 is coupled to heat the body of the fluid passage 110 to heat the fluid passage sealing member 140. It is preferable to further include a heating member (not shown) to allow the transfer to suppress the deposition of particles.

The fluid passage 110 is connected to the inlet 111 connected to the chamber on one side, the outlet 112 connected to the vacuum pump on the other side, the fluid flowing from the chamber is discharged to the vacuum pump It is a passage.

In addition, the fluid passage 110 has an O-ring (unsigned) at a portion which comes into contact with the upper end of the anti-corrosion sealing member 160 when the anti-corrosion sealing member 160, which will be described later, moves upward to close the slide space 120. ) Is preferably formed.

The slide space 120 is formed by penetrating the fluid passage 110 in an orthogonal direction to move the fluid passage sealing member 140 for sliding the opening and closing of the fluid passage 110.

The fluid passage sealing member 140 is a thin plate that opens and closes the inlet 111 of the fluid passage 110 while moving the slide space 120. The fluid passage sealing member 140 slides according to the operation of the first actuator 150 described later. The plate 141 which moves the space 120 and opens and closes the fluid passage 110, is provided on an upper side of the plate 141 and has a diameter larger than the inner diameter of the inlet 111, and the plate 141 is an inlet ( O-ring member (not shown) for sealing the inlet 111 when in close contact with the 111, is extended from one side of the plate 141 is connected to the first actuator 150 and the driving force of the first actuator 150 Shaft 143 for moving the plate 141 into the slide space 120, the frame 144 is provided on the left and right and rear edges of the plate 141, the frame 144 of the plate 141 On the left and right frame 144a of the plate 141 End portions of the left and right frames 144a of the plurality of traveling rollers 145 and the frame 144 of the plate 141 to be slid along the left and right walls 121 of the slide space 120 to be stable. The plurality of interference prevention rollers 146 are provided on the rear frame 144b in a vertical direction to the plate 141 in a vertical direction so as to reliably slide along the lower wall 122 or the upper and lower walls of the slide space 120. Include.

Here, the plate 141 has a size and shape corresponding to the slide space 120 formed in the fluid passage 110, the frame by a fixing means (not shown) and an elastic member (not shown) 144 is always provided with a force in a downward direction relative to the frame 144.

Therefore, in the fluid passage sealing member 140 as described above, the plate 141 moves the slide space 120 toward the fluid passage 110 in accordance with the driving of the first actuator 150 described later. Here, the movement of the plate 141, the plurality of traveling rollers 145 and the lower wall 122 of the slide space 120 to be slidably slid along the left and right side walls 121 of the slide space 120. It is made easier by a plurality of anti-interference rollers 146 to be reliably sliding along.

At the same time, the upper surface of the plate 141 is raised by an elastic member (not shown) with respect to the frame 144 in accordance with the upward driving of the anti-corrosion sealing member 160 described later to be in close contact with the inlet 111. And the inlet 111 is sealed by the O-ring member (unsigned) of the plate 141.

Thereafter, when the inlet 111 of the fluid passage 110 is closed by the plate 141 of the fluid passage sealing member 140, the corrosion preventing sealing member 160 described below is driven downward. The upper surface of the 141 is in close contact with the inlet 111, at this time, the plate 141 is the slide space toward the first actuator 150 in accordance with the drive of the first actuator 150. 120 is moved. Here, the movement of the plate 141, the plurality of traveling rollers 145 and the lower wall 122 of the slide space 120 to be slidably slid along the left and right side walls 121 of the slide space 120. It is made easier by a plurality of anti-interference rollers 146 to be reliably sliding along.

At this time, the plurality of anti-interference rollers 146, the plate 141 is described later due to the pressure difference between the inlet 111 and the outlet 112 during the lower driving of the anti-corrosion sealing member 160. Even if the second actuator 172 is in close contact with the upper end of the second body 172 and interference occurs with the second body 172, the interference preventing roller 146 is driven in the slide space 120 when the first actuator 150 is driven. By sliding along the lower wall 122, the plate 141 may smoothly retreat to the slide space 20 on the side of the first actuator 150, through which the fluid passage 110 may be smoothly opened and the gas may be smoothly moved. It is possible to improve the productability of the semiconductor device or wafer by allowing the supply to be accurately controlled. In addition, it is possible to reduce the manufacturing cost of the corresponding components by omitting the formation of the flow control groove on the upper end of the second body 172 of the second actuator 170, which will be described later.

The first actuator 150 is connected to the plate 141 of the fluid passage sealing member 140 through the shaft 143 to allow the plate 141 to slide the slide space 120. There may be an automatic or manual type for controlling the operation of forward / reverse of the drive shaft (not shown) connected to the 143, and in the case of the automatic type, it is preferable that the pneumatic type is operated by compressed air. The pneumatic actuator includes a compressed air inlet (not shown), a cylinder (not shown), a drive shaft (not shown), etc., through which compressed air is introduced, but a detailed description thereof will be omitted. Here, the first actuator 150 may be further provided with a recognition means such as an indicator so as to easily recognize the drive of the actuator from the outside.

The anti-corrosion sealing member 160 is provided at a lower side of the fluid passage 110 to vertically move the space of the fluid passage 110 according to the driving of the second actuator 170 to close the fluid passage sealing member 140. Is opened and closed to be in close contact with the inlet 111 and at the same time to open and close the slide space 120 formed inside the fluid passage 110, the form may be configured in a variety of shapes, but simply the fluid passage 110 Protruding hole for allowing the body 161 to be vertically moved in accordance with the air inlet and outlet of the cylindrical body 161 to be fitted inside and the second actuator 170 described later in the center or lower portion of the body 161 ( 162, and the compressed air from the rising air inlet (not shown) and the falling compressed air inlet (not shown) of the second actuator 170, which will be described later, on the upper and lower portions of the protrusion 162, respectively. The body 161 is raised or lowered by entering and exiting .

Here, the anti-corrosion sealing member 160 allows the air to flow from the descending compressed air inlet 174 so that the body 161 moves downward, but when the force is not applied from the outside by its own weight Free fall is also possible.

The second actuator 170 has an upward compressed air inlet (not shown) and a downward compressed air inlet (not shown), respectively, on the upper and lower portions of the protrusion 162 of the anti-corrosion sealing member 160. Compressed air is introduced through the body 161 to vertically move the inside of the fluid passage 110. The first body 171 and the second body 172 are largely coupled to each other so as to be coupled to each other. The body 171 is provided with an elevated compressed air inlet (not shown), and the second body 172 is provided with a lowered compressed air inlet (not shown) and the lowering of the protrusion 162 of the corrosion preventing sealing member 160. Guide grooves 172a for guiding the movement are formed.

Therefore, according to the second actuator 170, the corrosion preventing sealing member 160 may be moved up or down to enable opening and closing of the fluid passage 110 through the plate 141.

The pressure adjusting hole 180 is formed in an oblique direction inclined toward the inner side from the outside of the body 161 on the body 161 of the anti-corrosion sealing member 160, the opening and closing of the fluid passage 110 It is possible to suppress the pressure difference between the fluid passage 110 and the slide space 120 by allowing the fluid in the fluid passage 110 and the slide space 120 to be pumped by the vacuum pump, through the fluid passage 110 When the fluid in the chamber is pumped by the vacuum pump, the air in the slide space 120 is also pumped through the fluid passage 110 so that the fluid passage 110 and the slide space 120 always have the same air pressure state. Particles, which are reaction products generated on the chamber side, can be suppressed from flowing into the slide space when the vacuum pump is pumped.

Here, the second actuator 170 is preferably further provided with a rapid exhaust valve (not shown) so that the body 161 of the corrosion-proof sealing member 160 is moved quickly, the rapid exhaust valve (not shown) When the body 161 is moved downward through the fluid), the fluid in the second actuator 170 is quickly discharged to the outside to enable the rapid movement of the body 161.

The heating member (not shown) is provided on the flange (not shown) of the fluid passage 110 to which the inlet 111 is coupled to heat the body of the fluid passage 110 to the fluid passage sealing member 140. In order to suppress the deposition of particles by allowing heat to be transferred to the heater, a heater (not shown) installed at regular intervals in the form of a coil in a flange (not shown) so that the entire body of the fluid passage 110 is heated, and the Located outside the slide space 120 of the outer housing 130 of the flange (not shown) includes a power supply means (not shown) for supplying operating power to the heater (not shown).

Since the heater (not shown) and the power supply means (not shown) have a known configuration, a detailed description thereof will be omitted.

Therefore, according to the heating member (not shown), the plate of the fluid passage sealing member 140 sealing the inlet 111 of the fluid passage 110 by heating the flange (unsigned) of the fluid passage 110 Heat may be transferred to 141 to suppress deposition of reaction products generated by the gas reaction of the fluid on plate 141. That is, the plate 141 prevents the plate 141 from being moved to the slide space 120 in a state in which the reaction product or foreign matter of the fluid is concentrated on the plate 141 while the inlet 111 of the fluid passage 110 is closed. Deterioration, leakage, malfunction, etc., and the productivity of the semiconductor can be improved.

Here, the heating member (not shown) has been described that the inlet 111 of the fluid passage 110, that is, the plate 141 is provided only in the flange (not shown) in close contact, the fluid passage 110 Heating coils (not shown) may be provided throughout the entire wall.

Hereinafter, with reference to the drawings will be described the operation and effect of the gate valve according to a preferred embodiment of the present invention.

First, the process when the gate valve is closed is as follows.

First, as shown in FIGS. 8 to 10, the anti-corrosion sealing member 160 is vertically lifted along the fluid passage 110 by the second actuator 170 to be in close contact with the inlet 111. In the state in which the fluid passage 110 is opened while the slide space 120 is blocked through the process, the plate 141 slides toward the fluid passage 110 in response to the driving of the first actuator 150. 120 is moved.

In this case, the plate 141 is slid along the lower walls 122 of the plurality of traveling rollers 145 and the slide space 120 to slide along the left and right side walls 121 of the slide space 120. Sliding in the slide space 120 more easily by a plurality of anti-interference roller 146.

Thereafter, the upper surface of the plate 141 is raised by an elastic member (not shown) with respect to the frame 144 in accordance with the upward driving of the anti-corrosion sealing member 160 to be in close contact with the inlet 111 and the plate ( The inlet 111 is sealed by the O-ring member (not shown) of 141.

In this case, the slide space 120 is a plate in close contact with the lower portion of the fluid passage 110, that is, the inlet 111 by the pressure adjusting hole 180 formed in the upper portion of the corrosion preventing sealing member 160. It has the same air pressure as the lower space of 141.

On the other hand, the process when the gate valve is opened as follows.

First, as shown in FIGS. 8 to 10, the second actuator 170 in a state in which the inlet 111 of the fluid passage 110 is sealed by the plate 141 of the fluid passage sealing member 140. The anti-corrosion sealing member 140 vertically raised along the fluid passage 110 is vertically lowered, and the first actuator 150 is driven so that the plate 141 is positioned on the first actuator 150 side. The plate 141 moves the slide space 120 toward the first actuator 150 side.

In this case, the plate 141 is slid along the lower walls 122 of the plurality of traveling rollers 145 and the slide space 120 to slide along the left and right side walls 121 of the slide space 120. Sliding in the slide space 120 more easily by a plurality of anti-interference roller 146.

That is, the plurality of anti-interference rollers 146, the plate 141 is the second due to the pressure difference between the inlet 111 and the outlet 112 during the lower driving of the anti-corrosion sealing member 160. Although the interference with the second body 172 is in close contact with the upper end of the second body 172 of the actuator 170, the anti-interference roller 146 is the lower wall of the slide space 120 when the first actuator 150 is driven. By sliding along 122, the plate 141 may be smoothly retracted to the slide space 20 on the side of the first actuator 150.

In addition, when the fluid passage sealing member 140 is in close contact with the inlet 111 when the fluid passage 110 is opened in a closed state, the slide space 120 is the corrosion preventing sealing member 160 Vacuum pump because it has the same air pressure as the lower space of the lower portion of the fluid passage 110, that is, the lower portion of the plate 141 in close contact with the inflow portion 111 by the pressure adjusting hole 180 formed in the upper portion of the When the fluid in the chamber introduced into the inlet 111 by the fluid flow path 110 flows out to the outlet 112, the fluid does not flow into the slide space 120, but directly through the outlet 112. Since the particles are leaked out, particles are not introduced into the slide space 120.

Thereafter, when the fluid passage sealing member 140 moves the slide space 120 to move completely toward the first actuator 150, the corrosion preventing sealing member 160 is prevented by the second actuator 170. The fluid passage 110 is opened in a state in which the slide space 120 is blocked through a process of vertically moving along the fluid passage 110 and being in close contact with the inflow portion 111.

On the other hand, the fluid passage sealing member 140 for sealing the inlet 111 by a heating member (not shown) provided in the flange (not shown) of the fluid passage 110 when opening and closing the fluid passage 110. The flange (unsigned) is heated so that heat is transferred to the plate 141 of the substrate 141, thereby suppressing the deposition of the reaction product generated by the gas reaction of the fluid on the plate 141.

Therefore, according to the present invention as described above, through the plurality of interference prevention rollers 146 vertically arranged in the vertical direction to the plate 141 of the fluid passage sealing member 140 for opening and closing the fluid passage 110, The fluid passage sealing member 140 is the first actuator 150 by causing the interference preventing roller 146 to slide along the lower wall 122 of the slide space 120 during the opening operation in the state in which the fluid passage 110 is closed. Can be easily returned to the slide space (120) side.

In addition, the pressure passage hole 180 is formed in the anti-corrosion sealing member 160 that seals the slide space 120 of the fluid passage sealing member 140 that opens and closes the fluid passage 110. Pressure generation between the spaces 120 may be suppressed to prevent particles from flowing into the slide space 120.

In addition, a heating member (not shown) is provided on a flange (not shown) of the fluid passage 110 sealed by the fluid passage sealing member 140 to deposit particles by heat provided to the fluid passage sealing member 140. This can be done to optimize the performance of the valve.

While the preferred embodiments of the present invention have been described above with reference to the accompanying drawings, those skilled in the art to which the present invention pertains have various permutations and modifications without departing from the spirit or essential features of the present invention. It is to be understood that the present invention may be practiced in other specific forms, since modifications may be made. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive.

Claims (3)

Slide orthogonal to the fluid passage 110 and the fluid passage 110 connected to the inlet 111 connected to the chamber (not shown) and the outlet 112 connected to the vacuum pump (not shown) A housing 130 having a space 120;
A fluid passage sealing member 140 inserted into the slide space 120 to open and close the fluid passage 110;
A first actuator 150 for moving the fluid passage sealing member 140 in the slide space 120;
It is provided on the lower side of the fluid passage 110 when the fluid passage sealing member 140 is closed the fluid passage 110 to vertically move the space of the fluid passage 110, the fluid passage sealing member 140 is the inlet ( An anti-corrosion sealing member 160 which opens and closes in close contact with the 111 and simultaneously opens and closes the slide space 120; And
It includes a second actuator 170 for driving the corrosion preventing sealing member 160 up and down,
The fluid passage sealing member 140,
A plate 141 which moves the slide space 120 and opens and closes the fluid passage 110 according to the operation of the first actuator 150;
A shaft 143 extending from one side of the plate 141 and connected to the first actuator 150 and receiving the driving force of the first actuator 150 to allow the plate 141 to move the slide space 120. ;
A frame 144 provided on the plate 141;
A plurality of driving to be slidably along the left and right side wall 121 of the slide space 120 is provided in the left and right frame 144a of the frame 144 of the plate 141 horizontally in the left and right direction. Roller 145; And
The bottom wall 122 or the top and bottom of the slide space 120 is vertically provided on the end portions of the left and right frames 144a of the frame 144 of the plate 141 and vertically on the plate 141 in the rear frame 144b. A gate valve comprising a plurality of anti-interference rollers (146) to be reliably sliding along the side wall. According to claim 1, wherein the upper portion of the anti-corrosion sealing member 160 is formed in an oblique direction inclined toward the inner side from the outer side of the anti-corrosion sealing member 160, the fluid passage when opening and closing the fluid passage 110 It characterized in that it further comprises a pressure adjusting hole 180 to allow the fluid of the 110 and the slide space 120 is pumped by a vacuum pump to suppress the occurrence of a pressure difference between the fluid passage 110 and the slide space 120. Gate valve. According to claim 1, wherein the inlet 111 is provided on the flange (unsigned) of the fluid passage 110 is coupled to heat the body of the fluid passage 110 to heat the fluid passage sealing member 140 The gate valve further comprises a heating member (not shown) to be transmitted to suppress the deposition of particles.

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