JP4587113B2 - Static pressure gas bearing used in vacuum environment and gas recovery method of the static pressure gas bearing - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a static pressure gas bearing used in a vacuum environment and a gas recovery method for the static pressure gas bearing.
[0002]
[Prior art]
In a static pressure gas bearing used in a vacuum environment, it is desirable to provide a mechanism that provides an atmospheric pressure groove around the air pad and maintains the atmospheric pressure in the atmospheric pressure groove at atmospheric pressure.
The reason is that by providing an atmospheric pressure groove around the air pad, the design of the static pressure gas bearing for vacuum can be designed with the same design method as a normal static pressure gas bearing used in an atmospheric pressure environment. This is because it is possible to design the load capacity, rigidity, and the like.
Further, when the atmospheric pressure groove is not provided, all of the gas ejected from the air pad flows into the exhaust pump via the decompression groove, so that the burden on the exhaust pump is increased. In order to prevent this, it is effective to provide an atmospheric pressure groove.
[0003]
Therefore, as a mechanism for maintaining the pressure in the atmospheric pressure groove at atmospheric pressure, conventionally, an atmospheric piping is connected to the atmospheric pressure groove provided around the air pad, and the other end of the atmospheric piping is simply opened to the atmosphere outside the vacuum chamber. It had been.
[0004]
[Problems to be solved by the invention]
On the other hand, there arises a problem that the atmospheric pressure in the vacuum chamber increases as the moving body moves.
Japanese Patent Laid-Open No. 2000-346070 touches upon verification that the air adsorbed on the surface of the guide shaft is released into the vacuum by the movement of the moving body and the degree of vacuum is significantly reduced.
In Japanese Patent Laid-Open No. 2000-346070, when the gas released from the air pad adheres to the guide shaft and then the moving body moves and the surface is exposed, a large amount of gas molecules attached to the surface of the guide shaft are released to the outside. I found out that this is the cause. Then, it is proposed to perform a gas molecule adhesion amount reduction process such as coating the surface of the guide shaft with a material having a low gas molecule adhesion probability. As a result, it is possible to suppress the current situation in which the atmospheric pressure in the vacuum chamber increases as the moving body moves.
Then, the present inventors have started research and development of the available hydrostatic gas bearing in addition a vacuum degree of high environmental temperatures (about 10 ^{@ 5} Pa). In this research and development, even when a guide shaft that has been subjected to a treatment to reduce the amount of adhering gas molecules is adopted, it has been confirmed that a phenomenon in which the pressure inside the vacuum chamber rises with the movement of the moving body rarely occurs. It was.
Therefore, we pursued this cause and worked on further research and development to provide higher performance hydrostatic gas bearings.
For example, in the case of a semiconductor exposure apparatus, a vacuum chamber in which a static pressure gas bearing is mounted is usually installed in a clean room in which temperature and humidity are controlled.
In a static pressure gas bearing in which the atmospheric pressure groove inside the bearing is simply opened to the atmosphere outside the vacuum chamber via the atmospheric piping, the gas normally flows out from the bearing side to the atmospheric side, but it varies depending on the bearing clearance, etc. On the contrary, it has been found that gas may flow from the atmosphere side to the bearing side depending on the pressure balance of the atmospheric pressure groove.
[0005]
When gas flows backward from the atmosphere side to the bearing side in this way, air with a specific humidity flows into the bearing side through the atmospheric pressure groove, and a large amount of water molecules are adsorbed on the guide shaft surface. Will end up. When the moving body of the bearing starts moving in this state and the surface of the guide shaft on which water molecules are adsorbed is exposed to vacuum, the adsorbed water molecules are released into the vacuum environment. The atmospheric pressure will rise.
Even slightly the amount of water molecules adsorbed, if the pressure in the vacuum chamber is a high vacuum of about 10 ^{@ 5} Pa is observed as significant pressure rise. Such a phenomenon may cause failure of the light source unit or deterioration of exposure accuracy when such a pressure increase occurs in a bearing in an electron beam exposure apparatus, for example.
In particular, in a static pressure gas bearing used in a vacuum environment with a high degree of vacuum, it is necessary to manage so as to eliminate the cause of an increase in atmospheric pressure in the vacuum chamber.
[0006]
The present invention has been made to solve the above problems, and in a static pressure gas bearing used in a vacuum environment, the pressure in the atmospheric pressure groove inside the bearing in the vacuum environment is kept constant, and the atmospheric pressure groove Static pressure gas bearings used in a vacuum environment that can prevent the inflow of impurities such as moisture of the gas due to the backflow of external gas through the piping and prevent the vacuum degree of the vacuum environment from being lowered, and static It aims at providing the gas recovery method of a pressurized gas bearing.
[0007]
[Means for Solving the Problems]
In order to achieve the above object, in claim 1 of the present invention, a guide shaft and a moving body that moves along the guide shaft are provided in a vacuum chamber. The moving body includes a moving body and a guide shaft. An air pad that discharges gas supplied from the outside is formed in the gap, and an atmospheric pressure groove that collects the gas released into the gap and discharges it to the outside through a pipe around the air pad Further, a decompression groove is provided around the atmospheric pressure groove to collect a gas that could not be recovered in the atmospheric pressure groove and to discharge the gas to the outside through a pipe. In a static pressure gas bearing, the internal pressure is higher than the atmospheric pressure so that the gas recovered from the atmospheric pressure groove is discharged to the outside through the pipe so that the gas does not flow back into the atmospheric pressure groove from the outside. Pressure buffering channel Over the provided the atmospheric pressure groove, and the pressure buffering chamber, but is to have a hydrostatic gas bearing for use in a vacuum environment, characterized in that in communication.
[0008]
Accordingly, it is possible to prevent the inflow of impurities such as moisture of the gas due to the reverse flow of the external gas through the pipe to the atmospheric pressure groove inside the bearing, thereby preventing the deterioration of the vacuum environment.
In particular, in a static pressure gas bearing used in a vacuum environment with a high degree of vacuum, the present invention has a great effect.
[0009]
In order to achieve the above object, according to a second aspect of the present invention, the pressure buffering chamber includes a gas recovery port for connecting a pipe for recovering a gas from the atmospheric pressure groove, and an atmospheric pressure in the pressure buffering chamber. A gas supply port that connects a pipe for supplying gas by controlling the gas supply amount so that the pressure becomes a constant pressure higher than the atmospheric pressure, and a pipe that constantly releases the gas in the pressure buffer chamber to the outside A hydrostatic gas bearing for use in a vacuum environment according to claim 1, wherein a gas leak port is provided to connect the gas leak port.
[0010]
As a result, gas is always discharged outward from the gas leak port of the pressure buffering chamber, so that inflow of impurities from the outside into the pressure buffering chamber can be prevented.
That is, the inflow of impurities from the outside into the atmospheric pressure groove can be prevented, and therefore the vacuum environment can be prevented from being lowered.
[0011]
In order to achieve the above object, according to a third aspect of the present invention, the gas supplied into the pressure buffering chamber is high-purity nitrogen, which is used in a vacuum environment according to the second aspect. This is a static pressure gas bearing.
[0012]
As a result, even if gas flows into the atmospheric pressure groove from the pressure buffering chamber, gas in the atmosphere containing a large amount of moisture does not flow in, but high-purity nitrogen in the pressure buffering chamber flows in, reducing the vacuum environment There is no fear.
[0013]
In order to achieve the above object, according to claim 4 of the present invention, the gas supplied into the pressure buffering chamber is dry air. The static electricity used in a vacuum environment according to claim 2, This is a pressurized gas bearing.
[0014]
As a result, even if gas flows into the atmospheric pressure groove from the pressure buffering chamber, gas in the atmosphere containing a large amount of moisture does not flow in, and dry air in the pressure buffering chamber flows in, which may reduce the vacuum environment. Absent.
[0015]
In order to achieve the above object, in claim 5 of the present invention, gas is released from the air pad provided on the moving body to the gap between the guide shaft and the moving body, and from the atmospheric pressure groove provided around the air pad, A static pressure used in a vacuum environment in which the gas released into the gap is recovered, and further, the gas that cannot be recovered in the atmospheric pressure groove is recovered from the decompression groove provided around the atmospheric pressure groove. In the gas recovery method of the gas bearing, the atmospheric pressure groove and a pressure buffering chamber provided outside the static pressure gas bearing are communicated, and the atmospheric pressure in the pressure buffering chamber is constant higher than atmospheric pressure. A vacuum environment characterized by controlling the pressure so that the gas is always released from the pressure buffer chamber to the outside and the gas recovered from the atmospheric pressure groove is also discharged to the outside through the pressure buffer chamber. In is that a gas recovery method of the externally pressurized gas bearing to be used.
[0016]
As a result, gas is always released from the gas leak port of the pressure buffer chamber to the outside, preventing the inflow of impurities from the outside to the inside of the pressure buffer chamber, and releasing from the air pad from the atmospheric pressure groove inside the bearing. Gas can be recovered.
That is, when recovering the gas released from the air pad from the atmospheric pressure groove inside the bearing, it is possible to prevent the inflow of impurities from the outside into the atmospheric pressure groove, thus preventing the vacuum environment from being lowered.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 shows a static pressure gas bearing device 1 according to the present invention. The static pressure gas bearing device 1 includes a surface plate 3 and a static pressure gas bearing 4 in a vacuum chamber 2. The vacuum environment inside the vacuum chamber 2 in which the static pressure gas bearing 4 operates is required to be 10 ⁻³ to 10 ⁻⁴ Pa or less, and further, the operation is performed in a vacuum environment of about 10 ⁻⁵ Pa or less. The future is expected. The static pressure gas bearing 4 includes a guide shaft 5 and a moving body 6 that moves along the guide shaft 5. As shown in FIGS. 2 to 4, the moving body 6 is formed with an air pad 7 for releasing the gas supplied from the outside in the gap between the moving body 6 and the guide shaft 5. around 7 is provided with an atmospheric pressure groove 8 to release through the atmospheric pressure groove pipe 15 b to the outside to recover the gaseous release in the gap. In addition, a decompression groove 9 is provided around the atmospheric pressure groove 8 to collect the gas that could not be collected in the atmospheric pressure groove 8 and discharge it to the outside via a pipe. The atmospheric pressure groove 8, the atmospheric pressure groove pipe 15 b and the decompression groove 9 are provided on the moving body 6, but the decompression groove pipe is provided on the guide shaft 5 side. As shown in FIG. 3, the decompression groove 9 forms an exhaust connection groove 9 a that communicates with the decompression groove 9 in the vertical direction in the drawing. The guide shaft 5 has an exhaust hole 22 for recovering gas from the decompression groove 9 (including the exhaust connection groove 9a ) at a position facing the exhaust connection groove 9a in the vertical direction. Therefore, even if this moving body 6 moves within the range shown in FIG. 4B to FIG. 4C, the exhaust hole 22 covers the exhaust connection groove 9a. (Including the groove 9a ) can be exhausted.
[0018]
As described above, the amount of gas flowing into the vacuum chamber 2 is reduced by the atmospheric pressure groove 8 surrounding the air pad 7 of the static pressure gas bearing 4 and the labyrinth exhaust mechanism surrounding the atmospheric pressure groove 8. The amount is kept small so as not to affect the degree of vacuum. Depending on the required degree of vacuum of the operating environment, a plurality of decompression grooves 9 may be provided to further improve the gas recovery rate.
[0019]
Moreover, although the case where the piping for pressure reduction grooves was provided in the guide shaft 5 was shown, it can also be provided in the movable body 6. For example, in order to reduce the size of the moving body 6 and not to limit the moving distance of the moving body 6, it is preferable to provide the moving body 6 if the exhaust performance can be sacrificed to some extent. In this case, the vertical decompression groove 9 described above is not necessary.
However, since the gas is collected by the vacuum pump, the pipe diameter for the decompression groove is generally much larger than the pipe diameter connected to the air pad 7 or the atmospheric pressure groove 8. In this case, if a pipe for decompression groove is connected to the moving body 6, the pipe becomes a resistance and a vibration source, which may adversely affect high motion accuracy required for the moving body 6. Therefore, it is usually preferable to provide the pressure reducing groove pipe on the guide shaft 5 side.
In other words, considering the size and moving distance of the moving body 6 and the influence of the piping acting as a resistance on the moving body 6 when connecting the piping to the moving body 6, the piping for the decompression groove is moved to the moving body. It is good to decide whether to provide it on 6 or on the guide shaft 5.
[0020]
In FIG. 1, the piping and supply pump for supplying gas to the air pad 7, the decompression groove piping and the vacuum pump are omitted.
[0021]
Now, as shown in FIG. 1, the hydrostatic bearing device has an atmospheric pressure groove pipe 15a that discharges the gas recovered from the atmospheric pressure groove 8 to the outside through the atmospheric pressure groove pipe 15a. A pressure buffering chamber 10 is provided outside the vacuum chamber 2 so that the gas does not flow back to the atmospheric pressure groove 8.
The pressure buffer chamber 10 is provided with a gas recovery port 11, a gas supply port 12, and a gas leak port 13.
An atmospheric pressure groove pipe 15 a for recovering gas from the atmospheric pressure groove 8 is connected to the gas recovery port 11 through the introduction port 14 of the vacuum chamber 2.
Further, the gas supply port 15 is connected to a gas supply pipe 15a for supplying gas by controlling the gas supply amount so that the pressure in the pressure buffering chamber 10 becomes a constant pressure higher than the atmospheric pressure. is doing. And the pressure gauge 16 which measures the internal pressure of the chamber 10 for pressure buffering is provided, and the mass flow controller 17 is connected in the gas supply piping 15a. Then, a signal is sent from the pressure gauge 16 to the mass flow controller 17 via the signal cable 20 so as to control the gas supply flow rate so that the pressure inside the pressure buffering chamber 10 is about 10% higher than the atmospheric pressure. Thus, the flow rate of nitrogen flowing from the nitrogen cylinder 18 through the gas supply pipe 15a is controlled.
Further, the gas leak port 13 is connected to the outside a pipe for constantly releasing the gas in the pressure buffer chamber 10. It is preferable that the leak valve 19 provided in the pressure buffer chamber 10 is appropriately throttled and adjusted so that the flow rate of nitrogen flowing out from the leak valve 19 is about 5 to 10 liters / minute. As a result, the amount of nitrogen consumed can be kept low while preventing the inflow of air from the leak valve 19 to the pressure buffering chamber 10.
[0022]
The nitrogen supplied from the nitrogen cylinder 18 is high purity nitrogen so that the vacuum around the bearing does not decrease even if the gas in the pressure buffering chamber 10 flows backward into the atmospheric pressure groove 8. Is preferred. Note that high purity nitrogen is preferably 99.99% or more. In particular, when used in 10 ^@ 5 Pa approximately in a high vacuum, preferably to less than 99.9999%.
The gas supplied from the gas supply pipe 15a into the pressure buffer chamber 10 may be dry air. In this case, the dew point of the dry air is preferably set to −30 ° C. or lower so that the degree of vacuum does not decrease even if the gas in the pressure buffering chamber 10 flows back into the atmospheric pressure groove 8.
[0023]
Next, the gas recovery method of the static pressure gas bearing 4 used in the above-described vacuum environment will be described step by step.
First, high-pressure gas is discharged from the air pad 7 provided on the moving body 6 into the gap between the guide shaft 5 and the moving body 6. The moving body 6 and the guide shaft 5 are brought into a non-contact state by the static force of the released gas, so that the moving body 6 can move along the guide shaft 5 with almost no frictional resistance.
Next, the gas released into the gap is recovered from the atmospheric pressure groove 8 provided around the air pad 7.
At this time, the pressure in the pressure buffering chamber 10 provided outside the static pressure gas bearing 4 is controlled to a constant pressure higher than the atmospheric pressure (for example, 10% increase of the atmospheric pressure), and this pressure buffering chamber is controlled. The gas is always released from 10 to the outside, and the gas recovered from the atmospheric pressure groove 8 is also released to the outside through the pressure buffering chamber 10. As a result, the external atmosphere does not flow backward and flow into the atmospheric pressure groove 8.
Further, in order to reduce the gas released into the vacuum from the end of the moving body 6, the gas that could not be recovered in the atmospheric pressure groove 8 is recovered from the decompression groove 9 provided around the atmospheric pressure groove 8. .
[0024]
【The invention's effect】
In the present invention, the atmospheric pressure groove 8 and the atmosphere communicate only with the leak valve 19 provided in the pressure buffering chamber 10 according to the above configuration, but nitrogen of about 5 to 10 liters / minute is supplied from the leak valve 19. Since it flows out, the inflow of impurities from the atmosphere can be suppressed. Therefore, the gas flowing into the atmospheric pressure groove 8 is only the gas flowing in from the air pad 7 or nitrogen supplied from the nitrogen cylinder 18 via the pressure buffering chamber 10, so that the gas is released from the bearing due to the inflow of impurities. Problems such as an increase in the amount can be prevented.
That is, in the static pressure gas bearing 4 used in a vacuum environment, the pressure in the atmospheric pressure groove 8 inside the bearing in the vacuum environment is kept constant, and external gas is passed through the atmospheric pressure groove 8 through the atmospheric pressure groove pipe 15a. By preventing the inflow of impurities such as gas moisture due to the reverse flow, the vacuum degree in the vacuum environment can be prevented from lowering.
[Brief description of the drawings]
FIG. 1 is a perspective view showing a static pressure gas bearing device according to an embodiment of the present invention.
FIG. 2 is a perspective view showing a moving body according to an embodiment of the present invention.
3 is a plan view and a cross-sectional view showing the inside of the upper plate member of the movable body in FIG. 2. FIG.
4 is a cross-sectional view showing a relationship between a moving body and a guide shaft in FIG.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Static pressure gas bearing apparatus 2 Vacuum chamber 3 Surface plate 4 Static pressure gas bearing 5 Guide shaft 6 Moving body 6a Top plate 7 Air pad 8 Atmospheric pressure groove 9 Decompression groove 9a Exhaust connection groove 10 Pressure buffer chamber 11 Gas recovery port 12 Gas supply port 13 Gas leak port 14 Introduction port 15 Pipe 15a Gas supply pipe 15b Atmospheric groove pipe 16 Pressure gauge 17 Mass flow controller 18 Nitrogen cylinder 19 Leak valve 20 Signal cable 21 Screw hole 22 Exhaust hole

Claims (5)

A guide shaft and a moving body that moves along the guide shaft are provided in the vacuum chamber, and an air pad that discharges gas supplied from the outside to the gap between the moving body and the guide shaft is provided on the moving body. Forming and providing an atmospheric pressure groove around the air pad for collecting the gas released into the gap and releasing the gas to the outside through a pipe; and In a static pressure gas bearing used in a vacuum environment in which a decompression groove is provided that collects gas that could not be collected in the atmospheric pressure groove and is released to the outside via a pipe, the gas collected from the atmospheric pressure groove is In the pipe that discharges to the outside, there is provided a pressure buffer chamber in which the internal pressure is higher than the atmospheric pressure so that the gas does not flow back into the atmospheric pressure groove from the outside through this pipe, and the atmospheric pressure groove And the pressure buffering cha Bar and, but externally pressurized gas bearing for use in a vacuum environment, characterized in that in communication.   Gas is supplied to the pressure buffer chamber so that a gas recovery port for connecting a pipe for recovering the gas from the atmospheric pressure groove and a constant pressure higher than the atmospheric pressure in the pressure buffer chamber. A gas supply port for connecting a pipe for supplying gas by controlling the amount, and a gas leak port for connecting a pipe for constantly releasing the gas in the pressure buffer chamber to the outside are provided. The static pressure gas bearing used in a vacuum environment according to claim 1.   The static pressure gas bearing used in a vacuum environment according to claim 2, wherein the gas supplied into the pressure buffering chamber is high-purity nitrogen.   The hydrostatic gas bearing used in a vacuum environment according to claim 2, wherein the gas supplied into the pressure buffering chamber is dry air. Gas is released from the air pad provided on the moving body into the gap between the guide shaft and the moving body, and the gas released into the gap is recovered from the atmospheric pressure groove provided around the air pad. In a gas recovery method of a static pressure gas bearing used in a vacuum environment by recovering a gas that could not be recovered in the atmospheric pressure groove from a decompression groove provided around the groove, the atmospheric pressure groove, The pressure buffer chamber provided outside the hydrostatic gas bearing is communicated, and the pressure in the pressure buffer chamber is controlled to a constant pressure higher than the atmospheric pressure. A gas recovery method for a static pressure gas bearing for use in a vacuum environment, wherein the gas is discharged and the gas recovered from the atmospheric pressure groove is also discharged to the outside through the pressure buffer chamber.

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