KR102133238B1 - Vacuum Chamber And Gate Structure Using Linear Stage - Google Patents

Abstract

The present invention relates to a vacuum chamber and a gate structure using a linear stage. The vacuum chamber comprises: a process chamber which creates a vacuum environment inside a housing by forming a housing opening portion on a front upper portion to enable a sample to enter and exit therethrough; a door unit including a door base which includes a door flange inserted into the housing opening portion and a door opening portion corresponding to the housing opening portionand is coupled to the outside of the housing opening portion and a door which is coupled to the outside of the door base to open and close the door opening portion; a holder unit which includes a holder having the sample loaded on an upper surface thereof and a holder flange formed on an outer circumferential surface of the holder to correspond to the door flange and is provided in the housing; and a transfer unit which transfers a first shaft slider to a first shaft so that the first shaft slider and the holder flange coupled to move the holder unit up and down can be in contact with or separated from the door flange. Therefore, space utilization in the process chamber can be increased.

Description

{Vacuum Chamber And Gate Structure Using Linear Stage}

The present invention relates to a gate structure using a vacuum chamber and a linear stage.

The vacuum chamber refers to a device including a space maintained in a vacuum state, and examples thereof include a semiconductor manufacturing device, a scanning electron microscope (SEM), and a mass spectrometer.

In general, such vacuum chambers include a process chamber in which a vacuum environment is created for manufacturing, processing, inspection, analysis, and the like, and a load lock chamber and a gate valve to maintain the vacuum environment of the process chamber when samples are brought into or out of the process chamber. It includes.

As a related art, there is a vacuum chamber disclosed in Korean Patent Registration No. 10-1531632.

1 is a perspective view showing a conventional vacuum chamber, Figure 2 is an exploded perspective view showing a gate valve structure of a conventional vacuum chamber.

1 and 2, a conventional vacuum chamber is provided with a load lock chamber 20 on a process chamber 10 and an opening 31 on which a sample is carried in or out of the process chamber 10, and a vertical cylinder It includes a driving means such as 330 and the rotating medium 340, and is provided between the process chamber 10 and the load lock chamber 20, and includes a gate valve 300 that opens and closes the opening.

More specifically, in the conventional vacuum chamber, a transfer means for bringing in or taking out a sample into the process chamber 10 and a driving means for opening and closing the gate valve 300 are respectively installed outside the process chamber 10.

Due to this, the conventional vacuum chamber has a problem that the manufacturing cost is increased due to the configuration of the load lock chamber 20, the gate valve 300 and the like or the transfer or driving means included in the configuration, and the mounting space of other parts is limited. have.

In addition, the conventional vacuum chamber is not suitable for miniaturization due to its relatively complicated structure, and there is a problem in that maintenance such as washing is not easy.

Republic of Korea Registered Patent Publication No. 10-1531632 (Announcement date 2015.06.29)

An object of the present invention is to provide a vacuum chamber that maintains the vacuum state of the process chamber by a transfer unit installed in the process chamber without using a load lock chamber or a gate valve as being devised to solve the above-mentioned problems. .

In addition, it is an object of the present invention to provide a vacuum chamber that is suitable for miniaturization and easy to disassemble and combine with a relatively simple structure for maintenance such as washing.

In order to solve the above problems, the present invention provides a vacuum chamber that serves as a gate valve through a transfer unit and a holder unit.

More specifically, the vacuum chamber according to the present invention includes a process chamber for forming a vacuum environment inside the housing by forming a housing opening in which a sample enters and exits the front upper part.

In addition, the vacuum chamber includes a door flange that is inserted inside the housing opening and a door opening corresponding to the housing opening, and a door base coupled to the outside of the housing opening and a door base coupled to the outside of the door base to open and close the door opening. It includes a door unit including a door.

In addition, the vacuum chamber is a holder on which the sample is loaded on the upper surface and a holder flange corresponding to the door flange is formed on the outer circumferential surface of the holder, and the holder unit and the holder unit provided inside the housing are coupled to move up and down. It includes a transfer unit for transferring the first axis slider to the first axis so that the one-axis slider and the holder flange contact or separate from the door flange.

In addition, according to the linear reciprocating motion by the first axis slider, the holder unit moves upward and downward by cam guides formed on both sides and cam members formed on both sides of the lower portion of the housing opening.

In addition, the door flange and the holder flange are each formed with a downwardly inclined surface, and the holder flange can press the door flange by linear movement of the first axis slider.

In addition, each of the door flange and the holder flange is formed in a horizontal plane to the movement direction of the first axis slider, and the holder unit moves upward so that the holder flange can press the door flange.

In addition, the cam guide is formed with a movement preventing portion to limit linear movement of the first axis of the holder unit.

In addition, a sealing member may be provided on either side of a surface where the holder flange and the door flange are in contact.

In addition, the first axis slider may be formed of at least one permanent magnet and a bush on each of the upper portion, the bottom of the holder unit may be formed of a metal that reacts to magnetic force, and may include a bush hole into which the bush is inserted.

In addition, the transfer unit may transfer the holder unit in a second axis direction perpendicular to the first axis.

More specifically, the transfer unit includes a slider base coupled to an inner bottom surface of the housing, including a second shaft stator and a second shaft linear guide respectively installed in a second shaft encoder and a second shaft encoder formed on one side. do.

In addition, the transfer unit extends in the first axis direction to the first axis stator and the first axis linear guide and the first axis scale and the second axis mover formed in the lower side and the second axis extension in the second axis direction, respectively. And a second axis slider that linearly moves in a second axis direction relative to the slider base, including a second axis scale installed and a second axis linear block coupled to the second axis linear guide so as to be movable. .

In addition, the transfer unit includes a first axis mover and a first axis encoder respectively formed on one side and a first axis linear block coupled to the first axis linear guide so as to be movable on the second axis slider. And a first axis slider that linearly moves in a relatively first axis direction.

Further, the second shaft encoder and the second shaft stator may respectively penetrate the bottom surface of the housing and be coupled to the slider base.

The vacuum chamber according to the present invention can be implemented at a relatively low cost by not using a load lock chamber or a gate valve to maintain a vacuum state in the process chamber when the sample is brought in or out, and can utilize space in the process chamber. Can be improved.

In addition, the vacuum chamber according to the present invention is suitable for miniaturization with a relatively simple structure, and it is possible to improve maintenance such as washing.

In addition to the above-described effects, the concrete effects of the present invention will be described together while describing the specific matters for carrying out the invention.

1 is a perspective view showing a conventional vacuum chamber.
Figure 2 is an exploded perspective view showing a gate valve structure of a conventional vacuum chamber.
3 is an exploded perspective view of a vacuum chamber according to an embodiment of the present invention.
4 is a perspective view showing a process chamber according to an embodiment of the present invention.
5A and 5B are perspective views respectively showing closed and opened states of a door unit according to an embodiment of the present invention.
6A and 6B are perspective views each showing a holder unit according to an embodiment of the present invention.
7 is a bottom view of the holder unit according to an embodiment of the present invention.
8 is a perspective view of a transfer unit according to an embodiment of the present invention.
9 is an exploded perspective view of a transfer unit according to an embodiment of the present invention.
10A and 10B are front and bottom views, respectively, of a first slider according to an embodiment of the present invention.
11 a and b are front and bottom views, respectively, of a second slider according to an embodiment of the present invention.
12A and 12B are diagrams each showing a transfer state of a holder unit in a vacuum chamber according to an embodiment of the present invention.
13A and 13B are views each showing a transport state of a holder unit in a vacuum chamber according to an embodiment of the present invention.

Hereinafter, some embodiments of the present invention will be described in detail through exemplary drawings. It should be noted that in adding reference numerals to the components of each drawing, the same components have the same reference numerals as possible, even if they are displayed on different drawings. In addition, in describing embodiments of the present invention, when it is determined that detailed descriptions of related well-known configurations or functions interfere with understanding of the embodiments of the present invention, detailed descriptions thereof will be omitted.

In addition, in describing the components of the embodiments of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are only for distinguishing the component from other components, and the nature, order, or order of the component is not limited by the term. When a component is described as being "connected", "coupled" or "connected" to another component, the component may be directly connected to or connected to the other component, but another component between each component It should be understood that may be "connected", "coupled" or "connected".

3 is an exploded perspective view of a vacuum chamber according to an embodiment of the present invention.

Referring to FIG. 3, the vacuum chamber according to the present invention includes a process chamber 100, a door unit 200, a holder unit 300, and a transfer unit 400.

4 is a perspective view showing a process chamber according to an embodiment of the present invention.

Referring to FIG. 4, the process chamber 100 is coupled to the housing 110 on which the housing opening 111 is formed, where the sample is brought in or taken out from the front side, and the housing 110 is coupled to the outside of the housing 110. It includes a vacuum pump 120 for creating a vacuum environment in the interior space and a vacuum valve 130 for controlling the vacuum environment.

More specifically, the vacuum pump 120 and the vacuum valve 130 are preferably formed on the side surfaces of the housing 110, respectively, and the vacuum valve 130 has a housing opening 111 that requires sealing to maintain a relatively vacuum environment. ) Can be installed around.

Accordingly, it is possible to relatively quickly detect and control that the vacuum environment is changed due to leakage or the like that may occur when a sample is carried in or out through the housing opening 111.

In addition, the housing 110 may be separated into a housing body 110a and a housing cover 110b, and an external environment and sealing may be performed between the housing body 110a and the housing cover 110b by a sealing member. do.

In addition, the process chamber 100 may further include a window on the rear side and the opposite side on which the vacuum pump 120 is installed to observe the inside of the housing 110.

In addition, the process chamber 100 includes a cam member 140 under the housing opening 111.

The cam member 140 includes two cam blocks 142 to which at least one or more cam followers 141 are coupled, and is symmetrically installed on both sides of the housing opening 111 so that the cam followers 141 face each other. .

5A and 5B are perspective views each showing a closed and open state of a door unit according to an embodiment of the present invention.

Referring to FIG. 5, the door unit 200 includes a door flange 211 inserted into the housing opening 111 and a door opening 212 through which samples are brought in or out, and outside the housing opening 111. It includes a door 220 to be coupled to the door base 210 and the door 220 that is hinged to the door base 210 to open and close the door opening 212 upward.

Accordingly, the vacuum chamber according to the present invention is a structure in which the door unit 200 is coupled to the housing 110 upwards, and thus it is possible to facilitate maintenance such as washing inside the housing 110.

In addition, a sealing member may be provided outside of the housing opening 111 to which the door base 210 is coupled to prevent leakage due to coupling between the door base 210 and the housing 110.

In addition, a sealing member may be provided on a surface of the door 220 in close contact with the door base 210 to close the door opening 212 to prevent leakage between the door 220 and the door base 210.

In addition, a sealing member is provided between the upper surface of the door base 210 and the bottom surface of the corresponding door 210 to prevent leakage between the door 220 and the door base 210 when the door 220 is closed. have.

In addition, the door 220 may further include a window through which the inside of the housing 110 can be observed.

6A and 6B are perspective views each showing a holder unit according to an embodiment of the present invention.

7 is a bottom view of the holder unit according to an embodiment of the present invention.

6 and 7, the holder unit 300 is formed with a holder 310 for loading a sample on the upper surface and a holder flange 311 corresponding to the door flange 211 on the outer peripheral surface of the holder 310. It is provided inside the housing 110.

In addition, the holder unit 300 may further include a cam guide 312 corresponding to the cam member 140 on both sides and two bush holes 313 on the bottom surface, and all or part of the bottom surface is attached to the magnet. It is preferably formed of a metal that can be attached.

The holder flange 311 may have a tapered surface that is inclined downward to the front as shown in FIG. 6A. Accordingly, the door flange 211 also has a tapered surface that is inclined downward to the front so as to correspond to the holder flange 311 on which the tapered surface is formed.

Further, the holder flange 311 may be formed as a flat surface as shown in FIG. 6B. Accordingly, the door flange 211 is also formed as a flat surface to correspond to the holder flange 311 on which the flat surface is formed.

8 and 9 are perspective and exploded perspective views of a transfer unit according to an embodiment of the present invention, respectively.

10A and 10B are front and bottom views, respectively, of a first slider according to an embodiment of the present invention.

11A and 11B are front and bottom views of a second slider according to an embodiment of the present invention, respectively.

8 to 11, the transfer unit 400 includes a first axis slider 410 and a second axis slider 420 and a base 430 installed in the housing 110.

The transfer unit 400 includes a second shaft stator 431 and a second shaft linear guide 432 which are respectively installed in a second shaft direction and a second shaft encoder 433 formed on one side. (110) The slider base 430 coupled to the inner bottom surface and the first axis stator 421 and the first axis linear guide 422 and the first axis scale 423 respectively extending in the first axis direction and installed at the upper portion And a second axis mover 424 formed on one side of the lower portion and a second axis scale 425 extending in the second axis direction and a second axis linearly coupled to the second axis linear guide 432 to be movable. A second axis slider 420 linearly moving in a second axis direction relative to the slider base 430, including a block 426, and a first axis mover 413 and a first axis encoder respectively formed on one side. A straight line in the first axis relative to the second axis slider 420, including 414 and a first axis linear block 415 coupled so as to be movable on the first axis linear guide 422 below. It includes a first axis slider 410 to exercise.

More specifically, the second shaft encoder 433 and the second shaft stator 431 formed on the slider base 430 are preferably coupled to the slider base 430 through the bottom surface of the housing 110, respectively. Do. In addition, the second axis linear guide 432 is preferably formed of at least two or more.

In addition, the second axis slider 420 linearly moves in the second axis direction along the second axis linear guide 432 by the current flow between the second axis stator 431 and the second axis mover 424. .

Further, the second axis slider 420 may be controlled by a second axis scale 425 coupled to the lower portion and a second axis encoder 433 fixedly installed on the slider base 430.

In addition, it is preferable that the first axis linear guide 422 is formed of at least two, and the first axis scale 423 and the second axis scale 425 are respectively the first axis encoder 414 and the second. It is formed at a position corresponding to the shaft encoder 433.

In addition, the first axis slider 410 linearly moves in the first axis direction along the first axis linear guide 422 by the current flow between the first axis stator 421 and the first axis mover 413. .

In addition, the first axis slider 410 may be controlled by a first axis encoder 414 coupled to a side surface and a first axis scale 423 fixed to the second axis slider 420.

In addition, the first shaft slider 410 includes at least one permanent magnet 411 on the upper portion and two bushes 412 inserted into the bush hole 313, respectively, so that the holder unit 300 is made. It is stably coupled so that it can be moved up and down based on the 1-axis slider 410.

12A and 12B are views showing a transport state of the holder unit when the door flange 211 and the holder flange 311 are respectively formed to be inclined downward in the vacuum chamber according to an embodiment of the present invention. to be.

Referring to Figure 12, in the vacuum chamber according to the present invention, when the door flange 211 and the holder flange 311 are respectively formed with a tapered surface inclined downward in front, the operation method will be described as follows.

In the process chamber 100, a vacuum environment is created inside the housing 110 by the vacuum pump 120 and the vacuum valve 130. At this time, the holder unit 300 is located on the rear side of the interior of the housing 110 based on the door unit 200, as shown in Fig. 12A, it is defined as a neutral state.

Meanwhile, the holder unit 300 is transferred to the door unit 200 side by the transfer unit 400 in order to input the sample to the process chamber 100 for analysis or manufacturing.

More specifically, the holder unit 300 is linearly moved in the first axis by the first axis slider 410 so that the holder flange 311 can contact the door flange 211.

Accordingly, the tapered surface of the holder flange 311 and the tapered surface of the door flange 211 are in close contact, and the door flange sealing member 211a is provided between the contact surface of the holder flange 311 and the door flange 211. Is sealed.

At this time, the holder unit 300 is fixed by the movement preventing portion 312a formed on the cam follower 141 and the cam guide 312 in a state in which the holder flange 311 and the door flange 211 are sealed.

That is, the vacuum chamber according to the present invention can perform the role of a conventional gate valve by using a linear stage that is the first axis slider 410 as described above.

More specifically, as the holder unit 300 moves in the first axis, the cam follower 141 is in close contact with the cam guide 312, based on the first axis slider 410 by the shape of the cam guide 312. When the sealing of the holder flange 311 and the door flange 211 is completed by being separated from the upper surface of the first axis slider 412 upward and the transfer of the holder unit 300 is completed, the upper surface of the first axis slider 412 is formed. To settle down.

That is, the movement preventing portion 312a is formed in a'^' shape, and when the sealing of the holder flange 311 and the door flange 211 is completed, the cam guide 412 is fitted in the center of the movement preventing portion 312a. It is maintained in a state to fix the holder unit 300.

Accordingly, in the vacuum chamber according to the present invention, the sealing of the holder flange 311 and the door flange 211 can be maintained even when the power supply is stopped.

In addition, the vacuum chamber according to the present invention when the sample is loaded on the holder 310 by opening the door 220, as described above, the holder flange 311 and the door flange 211 are sealed so that the inside of the housing 110 A vacuum environment is maintained.

Accordingly, the vacuum chamber according to the present invention replaces the role of the gate valve with the holder unit 300 and the transfer unit 400 as described above, so that the gate valve and the configuration for driving the gate valve can be omitted. 100) The interior space utilization is improved.

Thereafter, the holder unit 300 returns to the neutral state by the first axis slider 410 when the sample 220 is loaded on the holder 310 and the door 220 is closed as described above.

At this time, the holder unit 300 can be finely adjusted by the first axis slider 410 and the second axis slider 420 so that inspection, analysis, etc. can be performed by a probe, a vision inspector, a manufacturing device, etc. Inspection, analysis, and manufacturing can be easily accomplished.

Meanwhile, FIGS. 13A and 13B are diagrams each showing a transport state of the holder unit when the door flange 211 and the holder flange 311 are respectively formed on a flat surface in a vacuum chamber according to an embodiment of the present invention. to be.

In the vacuum chamber according to the present invention with reference to FIG. 13, when the door flange 211 and the holder flange 311 are formed to be flat surfaces, sealing of the door flange 211 and the holder flange 311 is performed. Is as follows.

The holder unit 300 is linearly moved in the first axis by the first axis slider 410 so that the holder flange 311 can contact the door flange 211 in a neutral state.

At this time, while the holder unit 300 moves in the first axis, the cam follower 141 is in close contact with the cam guide 312, and the cam guide 312 has an upper side based on the first axis slider 410 by the shape. As a result, the door flange 211 and the holder flange 311 are sealed by being separated from the upper surface of the first axis slider 412.

More specifically, the holder unit 300 is spaced apart from the upper surface of the first axis slider 410 by the upper moving portion 312b formed in the cam guide 312, the door flange 211 and the holder flange 311 The sealing is done.

At this time, the upper moving portion 312b is preferably formed as an inclined surface between linear sections having different heights by converting linear motion to vertical motion.

In addition, the holder unit 300 further includes a movement preventing portion 312a on the cam guide 312 so that the holder unit 300 is first in a state where the door flange 211 and the holder flange 311 are sealed. It can be prevented from being moved to the axis.

On the other hand, as described above, when the holder unit 300 moves in a neutral state, the holder unit 300 and the self-weight of the holder unit 300 and the permanent magnet 411 installed on the upper surface of the first axis slider 410 The top surface of the first axis slider 410 is in close contact.

The above-described preferred embodiments of the present invention are disclosed for the purpose of illustration, and those skilled in the art will appreciate various modifications, changes, and additions within the spirit and scope of the present invention. It should be considered that the addition is within the scope of the following claims.

100. Process Chamber
110. Housing
110a. Housing body
110b. Housing cover
111. Housing opening
120. Vacuum pump
130. Vacuum valve
140. Cam member
141.Cam Follower
142. Cam Block
200. Door unit
210. Door base
211.Door flange
212. Door opening
211a. Door flange sealing member
220. Door
300. Holder unit
310. Holder
311. Holder Flange
312.Cam Guide
312a. Movement prevention part
312b. Upper mobile part
313.Bushhole
400. Transfer unit
410. 1st axis slider
411.Permanent Magnet
412. Bush
413. 1st axis mover
414. 1st axis encoder
415. 1st axis linear block
420. 2nd axis slider
421. 1st axis stator
422. 1st axis linear guide
423. 1st axis scale
424. 2nd axis mover
425. 2nd axis scale
426. 2nd axis linear block
430. Slider base
431. 2nd stator
432. 2nd axis linear guide
433. 2nd axis encoder

Claims (10)

A process chamber for forming a vacuum environment inside the housing by forming a housing opening in which a sample enters and exits the front upper part;
A door unit including a door flange inserted inside the housing opening and a door opening corresponding to the housing opening, and a door base coupled to the outside of the housing opening and a door coupled to the outside of the door base to open and close the door opening. ;
A holder unit on which a sample is loaded on an upper surface and a holder flange corresponding to the door flange is formed on the outer peripheral surface of the holder, and a holder unit provided inside the housing; And
A vacuum chamber including a; a transfer unit for transferring the first axis slider to the first axis so that the holder axis is coupled to be movable up and down and the holder flange is in contact with or separated from the door flange.
According to claim 1,
A vacuum chamber in which the holder unit moves upward and downward by a cam guide formed on both sides of the holder unit and a cam member formed on both sides of the lower portion of the housing according to the linear reciprocating motion by the first axis slider.
According to claim 2,
Each of the door flange and the holder flange is formed to face downwardly inclined,
A vacuum chamber in which the holder flange presses the door flange by linear movement of the first axis slider.
According to claim 2,
Each of the door flange and the holder flange is formed in a plane horizontal to the movement direction of the first axis slider,
A vacuum chamber in which the holder unit moves upward and the holder flange presses the door flange.
The method of claim 3 or 4,
The cam guide is formed with a movement preventing portion to limit the movement of the first axis of the holder unit in a vacuum chamber.
The method of claim 3 or 4,
A vacuum chamber having a sealing member on one side of a surface where the holder flange and the door flange are in contact.
According to claim 2,
At least one permanent magnet and a bush are formed on the first axis slider, respectively.
The bottom surface of the holder unit is formed of a metal responsive to magnetic force, and a vacuum chamber including a bush hole into which the bush is inserted.
According to claim 2,
The transfer unit is a vacuum chamber for transferring the holder unit in a second axis direction perpendicular to the first axis.
The method of claim 8,
The transfer unit
A slider base coupled to an inner bottom surface of the housing, including a second shaft stator and a second shaft linear guide extending in the second shaft direction and a second shaft encoder formed on one side;
The first axis stator and the first axis linear guide and the first axis scale and the second axis mover formed on the lower side and the second axis extended in the second axis direction are respectively installed on the upper side in the first axis direction. A second axis slider that linearly moves in a second axis direction relative to the slider base, including a second axis linear block coupled to the scale and the second axis linear guide to be movable;
A first axis direction relative to the second axis slider, including a first axis linear block formed on one side and a first axis linear block coupled to the first axis linear guide so as to be movable on the first axis linear guide. Vacuum chamber comprising a first axis slider that linearly moves.
The method of claim 9,
The second shaft encoder and the second shaft stator respectively penetrate the bottom surface of the housing and are coupled to the slider base.

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