KR102172722B1 - Sealing capsule for inspecting extreme ultra violet lithography pellicle - Google Patents

Abstract

The present invention relates to a capsule used to protect a pellicle for ultra-ultraviolet lithography during inspection of a pellicle for ultra-ultraviolet lithography used as a dustproof film when manufacturing a semiconductor device. The present invention forms an inner space in which a pellicle for ultra-ultraviolet lithography is accommodated by a top plate having an opening in the center, a top panel window installed in the opening of the top plate and having an antireflection coating layer formed thereon, and the top plate A lower plate having a plurality of vacuum holes formed on the bottom surface to adsorb and fix the pellicle frame of the pellicle for ultraviolet lithography and a vacuum auxiliary device mounting groove formed on at least one side thereof, and a vacuum auxiliary device mounting groove of the lower plate, and vacuum And a vacuum auxiliary device having a gas outlet connected to the generator and a first flow path connected to the gas outlet, and the lower plate includes a pellicle for ultra-ultraviolet lithography having a second flow path connecting the first flow path and the vacuum holes. Provide capsules used for testing. When the capsule used for the inspection of the pellicle for ultra-ultraviolet lithography according to the present invention is used, it is possible to minimize damage to the pellicle film of the pellicle for ultra-ultraviolet light during the inspection process. In addition, even if the pellicle film is damaged, it is possible to prevent particles of the pellicle film from scattering and contaminating the inspection apparatus.

Description

Sealing capsule for inspecting extreme ultra violet lithography pellicle {Sealing capsule for inspecting extreme ultra violet lithography pellicle}

The present invention relates to a capsule used to protect a pellicle for ultra-ultraviolet lithography during inspection of a pellicle for ultra-ultraviolet lithography used as a dustproof film when manufacturing a semiconductor device.

In the case of patterning a semiconductor wafer or a liquid crystal substrate in the manufacture of a semiconductor device or a liquid crystal panel, a method called photolithography is used. In photolithography, a mask is used as the original plate for patterning, and the pattern on the mask is transferred to a wafer or a substrate for liquid crystal. If dust adheres to the mask, light is absorbed or reflected by the dust, and thus the transferred pattern is damaged, leading to a problem that the performance or yield of a semiconductor device or a liquid crystal panel is deteriorated. Therefore, these operations are usually performed in a clean room, but since dust also exists in this clean room, a method of attaching a pellicle has been performed to prevent dust from adhering to the mask surface. In this case, the dust does not directly adhere to the surface of the mask, but adheres to the pellicle film. During lithography, since the focus is aligned on the pattern of the mask, there is an advantage that the dust on the pellicle is out of focus and is not transferred to the pattern.

Gradually, the required resolution of the exposure apparatus for semiconductor manufacturing is increasing, and in order to realize the resolution, the wavelength of the light source is becoming shorter and shorter. Specifically, the UV light source is gradually shorter in wavelength from ultraviolet g-rays (436), I-rays (365), KrF excimer lasers (248), and ArF excimer lasers (193) to ultra-ultraviolet (EUV, extreme UltraViolet, 13.5 nm). Is losing. Development of new light sources, resists, masks and pellicles is indispensable in order to realize such an exposure technology using ultra-ultraviolet rays. That is, the conventional organic pellicle film has a problem in that it is difficult to be used in a pellicle for ultra-ultraviolet rays because its physical properties are changed by an exposure light source having high energy and its life is short. Various attempts are being made to solve this problem.

The production of pellicles is usually carried out in a super clean room, and the produced pellicles are stored in a pellicle case, and the transmittance measurement and foreign matter inspection are performed before product shipment. In addition, even after wearing, foreign matter inspection is performed before opening the case and attaching it to the mask or after attaching it to the mask.

However, since the pellicle film of such an ultra-ultraviolet pellicle is an ultra-thin film having a thickness of several tens of nm, and has a length and width of about 6 inches, there is a problem that it can be easily damaged in the process of inspecting foreign substances attached to the surface of the pellicle film.

That is, the process of opening the pellicle storage case, the process of mounting the pellicle on the moving table of the inspection device, the vibration applied during the movement of the pellicle while it is fixed on the moving table of the inspection device, and maintaining a positive pressure inside the inspection device. In order to do so, there is a problem that the pellicle can be easily damaged due to the flow of air supplied to the inspection device, pressure or vibration applied during the process of overturning the pellicle for inspection of the opposite surface of the pellicle membrane.

In addition, although the conventional pellicle film is simply torn, if the pellicle film of the pellicle for ultra-ultraviolet rays is damaged, particles constituting the film may scatter and stick to the inspection device, which may cause a fatal problem.

Registered Patent 10-1738887 Registered Patent 10-1807396 Patent Publication 10-2017-0085118

The present invention is to solve the above problems, and provides a capsule used for inspection of a pellicle for ultra-ultraviolet lithography that seals a pellicle for ultra-ultraviolet rays in a low vacuum state so that the pellicle for ultra-ultraviolet rays can be inspected in a sealed state. It is aimed at.

In order to achieve the above object, the present invention,

A top plate with an opening formed in the center,

An upper plate window installed in the opening of the upper plate and having an antireflection coating layer formed thereon,

Combined with the upper plate to form an inner space in which a pellicle for ultra-ultraviolet lithography is accommodated, and a plurality of vacuum holes formed on the bottom surface to adsorb and fix the pellicle frame of the pellicle for ultra-ultraviolet lithography and a vacuum formed on at least one side A lower plate on which an auxiliary device mounting groove is formed,

It is installed in the vacuum auxiliary device mounting groove of the lower plate, and includes a vacuum auxiliary device having a gas outlet connected to the vacuum generator and a first flow path connected to the gas outlet,

The lower plate is provided with a capsule used for inspection of a pellicle for ultra-ultraviolet lithography in which a second flow path connecting the first flow path and the vacuum holes is formed.

In addition, a capsule used for inspection of a pellicle for ultra-ultraviolet lithography is provided, further comprising a lower panel window having an opening formed in the center of the lower panel, installed in the opening of the lower panel, and having an antireflection coating layer formed thereon.

In addition, the vacuum auxiliary device includes a body portion and a suction portion extending from one side surface of the body portion, being fitted into the vacuum auxiliary device mounting groove, and having the first flow path,

The capsule further includes a vacuum vent bush coupled to the vacuum auxiliary device,

The vacuum vent bush has a first channel extending in a transverse direction in which both ends are blocked by a second wall surface opposite to the first wall, and is connected to the first channel at an angle, and the first channel and the suction port of the vacuum generator are connected. A second channel to connect is formed,

The vacuum vent bush further includes a piston that moves linearly between the first wall surface and the second wall surface along the first channel and has a through hole formed in a center thereof,

A third channel extending in a horizontal direction to a height different from that of the first channel is formed in the suction part of the vacuum auxiliary device,

A fourth channel connecting the first channel and the third channel is formed in the vacuum vent bush,

When the piston contacts the first wall surface, the connection portion between the first channel and the second channel is closed, and when the piston contacts the second wall surface, the connection portion between the first channel and the fourth channel is closed. It provides a capsule used for inspection of pellicles for lithography.

In addition, a fifth channel connected to the first channel is formed in the vacuum vent bush, and when the piston contacts the first wall surface, the connection portion of the first channel and the fifth channel is closed. Provide capsules used for testing.

In addition, a capsule used for inspection of a pellicle for ultra-ultraviolet lithography is formed with an inclined incision so as to push the piston toward the second wall by colliding with the gas introduced through the fifth channel at the end of the first wall side of the piston Provides.

In addition, a capsule used for inspection of a pellicle for ultra-ultraviolet lithography is provided, in which a chamber in communication with the third channel is formed in the suction part, and a suction plate, which is a porous plate, is disposed on an open upper surface of the chamber.

In addition, the suction plate provides a capsule used for inspection of a pellicle for ultra-ultraviolet lithography, which is a porous ceramic.

In addition, the first flow path provides a capsule used for inspection of a pellicle for ultra-ultraviolet lithography connected to the fourth channel.

In addition, the first wall surface provides a capsule used for inspection of a pellicle for ultra-ultraviolet lithography including a magnet for applying a magnetic force to the piston in a direction in which the piston and the first wall surface become closer.

In addition, the second wall surface provides a capsule used for inspection of a pellicle for ultra-ultraviolet lithography including a magnet for applying a magnetic force to the piston in a direction in which the piston and the second wall surface are close.

In addition, a vacuum indicator having a pair of arms fixed to the indicator mounting portion of the vacuum vent bush so as to be rotatable by a hinge pin, and a pair of ball shaft plungers fixed to one end of the pair of arms, respectively, is further provided. Includes,

The ball shaft plunger includes a barrel, a ball shaft disposed in the barrel, and a compression spring having one end disposed in the barrel and the other end coupled to the arm,

The ball shaft plunger is installed in a through hole penetrating a wall surface between the indicator installation part and the first channel,

The ball-shaped end of the ball shaft is disposed inside the first channel, and when the piston passes under the ball shaft, the ball shaft rises and an ultra-ultraviolet ray that rotates the arm connected to the compression spring of the ball plunger. It provides a capsule used for inspection of pellicles for lithography.

In addition, the vacuum auxiliary device and the vacuum vent bush provide a capsule used for inspection of a pellicle for ultra-ultraviolet lithography that is integral.

When the capsule used for the inspection of the pellicle for ultra-ultraviolet lithography according to the present invention is used, it is possible to minimize damage to the pellicle film of the pellicle for ultra-ultraviolet light during the inspection process. In addition, even if the pellicle film is damaged, it is possible to prevent particles of the pellicle film from scattering and contaminating the inspection apparatus.

In addition, capsules used for inspection of pellicles for ultra-ultraviolet lithography have the advantage of being able to replace the pellicle case. In addition, since the pellicle case is not opened during the inspection process, there is an advantage in that the process of opening the pellicle case can be reduced.

1 is a perspective view of a capsule used for inspection of a pellicle for ultra-ultraviolet lithography according to an embodiment of the present invention.
2 is an exploded perspective view of a capsule used for inspection of the pellicle for ultra-ultraviolet lithography shown in FIG. 1.
3 is a perspective view showing an example of a pellicle for ultra-ultraviolet lithography.
4 and 5 are cross-sectional views illustrating a part of a state in which a capsule used for inspection of the pellicle for ultra-ultraviolet lithography shown in FIG. 1 is mounted in a vacuum generator.
6 is a perspective view of the piston shown in FIGS. 4 and 5.
7 is a plan view showing a state in which the upper plate of the capsule used for inspection of the pellicle for ultra-ultraviolet lithography shown in 1 is removed.
8 is a partially enlarged cross-sectional view of FIG. 5.
9 is a view showing the ball plunger shown in FIG. 2.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. The following embodiments are provided as examples in order to sufficiently convey the spirit of the present invention to those skilled in the art. Therefore, the present invention is not limited to the embodiments described below and may be embodied in other forms. In addition, in the drawings, the width, length, thickness, etc. of the component may be exaggerated for convenience. The same reference numbers throughout the specification denote the same elements.

1 is a perspective view of a capsule used for inspection of a pellicle for ultra-ultraviolet lithography according to an embodiment of the present invention. 2 is an exploded perspective view of a capsule used for inspection of the pellicle for ultra-ultraviolet lithography shown in FIG. 1. 1 and 2, the capsule 100 used for the inspection of the pellicle for ultra-ultraviolet lithography according to an embodiment of the present invention includes an upper panel 10, an upper panel window 20, a lower panel 30, and a lower panel. It includes a window 40, a vacuum auxiliary device 50, a vacuum vent bush 60 and a ball plunger 80.

The capsule 100 serves to seal and protect the pellicle 1 for ultra-ultraviolet lithography in a low vacuum state during the inspection of the pellicle 1 for ultra-ultraviolet light lithography.

3 is a perspective view showing an example of a pellicle for ultra-ultraviolet lithography. As shown in FIG. 3, the pellicle 1 for ultra-ultraviolet lithography includes a pellicle film 2 and a pellicle frame 5. The pellicle frame 5 includes a frame portion 3 including a pair of long sides and a pair of short sides, and a fixture 4 coupled to each of the pair of long sides of the frame portion 3. Two fixtures 4 are combined on one long side. The pellicle 1 for ultra-ultraviolet lithography is installed on a photo mask by coupling the fixture 4 to a stud installed on the photo mask.

Referring again to Figs. 1 and 2, the capsule 100 used for inspection of the pellicle for ultra-ultraviolet lithography will be described. The upper plate 10 is a rectangular plate and has an opening 11 formed in the center. Alignment grooves (not shown) are formed in the lower corners of the upper plate 10.

The upper panel window 20 is installed in the opening 11 of the upper panel 10. The upper window 20 may be made of glass having an antireflection coating layer formed thereon. The upper window 20 serves as a path through which light irradiated from the inspection optical system and light reflected from the pellicle film 2 pass when inspecting the upper surface of the pellicle film 2 of the pellicle 1 for ultra-ultraviolet lithography.

The lower plate 30 is a generally rectangular plate. The lower plate 30 is combined with the upper plate 10 to form an inner space in which the pellicle 1 for ultra-ultraviolet lithography is accommodated. An opening 31 is formed in the center of the lower plate 30. A circumferential portion 32 protruding in the direction of the upper plate 10 is formed around the lower plate 30. Alignment pins 33 are installed at the corners of the circumferential portion 32. When the alignment pins 33 are inserted into the alignment grooves formed at the corners of the upper plate 10, the upper plate 10 and the lower plate 30 are coupled. The circumferential portion 32 of the lower plate 30 is in contact with the lower surface of the upper plate 10. A pellicle 1 for ultra-ultraviolet lithography is disposed in a space surrounded by the lower surface of the upper plate 10, the inner surface of the circumferential portion 32, and the upper surface of the lower plate 30.

The bottom surface of the lower plate 30 is formed with a concave seating groove 35 through which the fixture 4 of the pellicle frame 5 can be seated. The seating groove 35 is formed almost the same as the shape of the fixture 4. In addition, at least one vacuum hole 36 is formed in the seating groove 35. The vacuum hole 36 serves to adsorb the fixture 4 of the pellicle frame 5 placed on the lower plate 30 and fix it to the seating groove 35.

In addition, a vacuum auxiliary device mounting groove 37 is formed on both sides of the lower plate 30 to mount the vacuum auxiliary device 50. The vacuum auxiliary device mounting groove 37 is formed long along the side of the lower plate 30. The upper portion 38 at the end of the inner space side of the capsule 100 of the vacuum auxiliary device mounting groove 37 is open. Accordingly, the vacuum auxiliary device mounting groove 37 communicates with the inner space of the capsule 100.

The lower panel window 40 is installed in the opening 31 of the lower panel 30. Like the upper window 20, the lower window 40 may be made of glass having an antireflection coating layer formed thereon. The lower window 40 becomes a passage through which light irradiated from the inspection optical system passes during inspection of the lower surface of the pellicle film 2 and the inner surface of the pellicle frame 5 of the pellicle 1 for ultra-ultraviolet lithography. Since the lower panel window 40 is provided, there is no need to inspect the pellicle 1 for ultra-ultraviolet lithography after being separated from the capsule 100 and turned over, and the capsule 100 is immediately turned over to the lower surface of the pellicle film 2 and the pellicle frame. (5) can be inspected inside.

The vacuum auxiliary device 50 is installed in the vacuum auxiliary device mounting grooves 37 on both sides of the lower plate 30. The vacuum auxiliary device 50 extends from one side of the body portion 51 and the body portion 51 to which the vacuum generator 8 is docked, and is fitted into the vacuum auxiliary device mounting groove 37 of the lower plate 30. It includes a suction part (55). A first through hole 511 and a second through hole 512 to which the vacuum vent bush 60 are coupled are formed in the body part 51.

4 and 5 are cross-sectional views showing a part of a state in which a capsule used for inspection of the pellicle for ultra-ultraviolet lithography shown in FIG. 1 is mounted in a vacuum generator.

As shown in FIGS. 4 and 5, the vacuum vent bush 60 includes a main body 61 and a first protrusion 62 and a second protrusion 63 protruding from the main body 61. The first protrusion 62 is fitted into the first through hole 511 of the vacuum assist device 50, and the second protrusion part 63 is fitted into the second through hole 512 of the vacuum assist device 50. The pin-shaped suction port 9 of the vacuum generator 8 is also fitted in the first through hole 511.

A first channel 611 is formed in the body portion 61 of the vacuum vent bush 60 in the horizontal direction. Both ends of the first channel 611 are blocked by the first wall surface 617 and the second wall surface 618. The first wall surface 617 and the second wall surface 618 may be formed of a permanent magnet. A cylindrical piston 64 capable of sliding along the first channel 611 is disposed in the first channel 611. The piston 64 moves along the first channel 611 between the first wall surface 617 and the second wall surface 618.

6 is a perspective view of the piston shown in FIGS. 4 and 5. As shown in Fig. 6, a through hole 641 is formed in the center of the piston 64. A cutout 642 cut in a diagonal direction is formed at an upper portion of the right end of the piston 64. The depth of the cut-out portion 642 is not deep, so that the through-hole 641 is not exposed through the cut-out portion 642.

The outer circumferential surface of the piston 64 is in close contact with the inner surface of the first channel 611. Accordingly, gas does not flow between the outer peripheral surface of the piston 64 and the inner surface of the first channel 611. The gas flowing through the first channel 611 flows through the through hole 641 of the piston 64.

A second channel 612 connecting the first channel 611 and the fin-shaped suction port 9 is formed at the right end of the first channel 611. The second channel 612 is connected to the first channel 611 in an angle. In this embodiment, the second channel 612 is perpendicular to the first channel 611. When the right end of the piston 64 is in close contact with the first wall 617, the portion where the second channel 612 and the first channel 611 are connected is blocked by the piston 64.

In addition, a fifth channel 615 connecting the first channel 611 and the gas injection port 7 of the gas injection device 6 is formed at the right end side of the first channel 611. The gas injection device 6 serves to supply high-purity nitrogen or the like into the capsule. The fifth channel 615 is connected to the first channel 611 in an angle. In this embodiment, the fifth channel 615 is perpendicular to the first channel 611. When the right end of the piston 64 is in close contact with the first wall surface 617, the portion where the fifth channel 615 and the first channel 611 are connected is also blocked by the piston 64.

A third channel 551 is formed in the suction part 55 of the vacuum auxiliary device 50 in the horizontal direction. The third channel 551 is formed in a horizontal direction at a height different from that of the first channel 611. In addition, a chamber 552 is formed at the left end of the third channel 551. The chamber 552 communicates with the third channel 551. The chamber 552 is formed long along the width direction of the suction part 55. The upper surface of the chamber 552 is open, and a suction plate 553 is installed on the open upper surface. The suction plate 553 faces the inner space of the capsule 100 through the open upper portion 38 of the end of the vacuum assist device mounting groove 37. The suction plate 553 may be made of a porous ceramic having micropores.

A fourth channel 614 connecting the first channel 611 and the third channel 551 is formed on the left end side of the first channel 611 of the vacuum vent bush 60. The fourth channel 614 is connected to the first channel 611 in an angle. In addition, the fourth channel 614 is connected to face the third channel 551. When the left end of the piston 64 is in close contact with the second wall surface 618, the portion where the first channel 611 and the fourth channel 614 are connected is blocked by the piston 64.

7 is a plan view showing a state in which the upper plate of the capsule used for inspection of the pellicle for ultra-ultraviolet lithography shown in FIG. 1 is removed.

As shown in FIG. 7, a pair of first flow paths 519 are further connected to the fourth channel 614. The pair of first flow paths 519 extend from the fourth channel 614 in the width direction of the vacuum auxiliary device 50, respectively. In addition, the fourth channel 614 and the distal end of the first flow path 519 communicate with the second flow path 39 formed in the lower plate 30. The second flow path 39 connects the vacuum hole 36 of the lower plate 30 and the first flow path 519.

In addition, a vacuum indicator 70 is installed on the vacuum vent bush 60. The vacuum indicator 70 serves to display the pressure state of the inner space of the capsule 100 so that it can be checked from the outside.

8 is a partially enlarged cross-sectional view of FIG. 5. As shown in FIG. 8, the vacuum indicator 70 has a central portion rotatably fixed by a hinge pin 72, a pair of arms 71a, 71b and a pair of ball shafts that generally cross each other in an X-shape. It includes plungers 73a and 73b. The arms 71a and 71b are rotatably installed in the indicator mounting portion 65 formed concave on the upper surface of the vacuum vent bush 60.

Ball shaft plungers (73a, 73b) are barrels (732a, 732b), ball shafts (731a, 731b) disposed in the barrels (732a, 732b) and compression springs (733a, 733b) partially disposed in the barrels (732a, 732b). ). The ball shaft plungers 73a and 73b are installed in the through hole 619 penetrating the wall surface between the indicator mounting portion 65 and the first channel 611. At this time, about half of the ball-shaped ends of the ball shafts 731a and 731b enter the inside of the first channel 611. Further, opposite ends of the compression springs 733a and 733b of the ball shaft plungers 73a and 73b are coupled to one end of the arms 71a and 71b. Accordingly, when the ball shafts 731a and 731b rise, the arms 71a and 71b rotate, and the opposite end of the end to which the compression springs 733a and 733b are coupled descends.

Balls at the ends of the ball shafts 731a and 731b of the pair of ball shaft plungers 73a and 73b are disposed inside the first channel 611 at regular intervals. Therefore, as shown in Fig. 8, when the piston 64 is in close contact with the first wall surface 617, the right ball shaft 731a rises, and as a result, the arm 71a connected to the right ball shaft 731a ) Rotates counterclockwise around the hinge pin 72.

On the contrary, when the piston 64 is in close contact with the second wall surface 618, the ball shaft 731b on the left rises, and the arm 71b connected to the ball shaft 731b on the left is centered on the hinge pin 72. It rotates clockwise.

Therefore, depending on the positions of the arms 72a and 71b, it can be seen whether the inside of the capsule 100 is in a low vacuum state or in a state in which the vacuum is destroyed. That is, when the left arm 71a is lowered relative to the upper portions of the arms 72a and 71b, the vacuum is in a low vacuum state, and when the right arm 71b is lowered, the vacuum is discarded.

As shown in FIG. 2, the ball plunger 80 is installed on the lower surface of the upper plate 10. The ball plunger 80 may be installed at the same position as the vacuum hole 36 of the lower plate 30 on a plane.

When the fixture 4 of the pellicle frame 5 is adsorbed to the lower plate 30 by the vacuum hole 36 in the lower plate 30, the ball plunger 80 removes the fixture 4 of the pellicle frame 5 By pressing in the direction of the lower plate 30, the fixture 4 of the pellicle frame 5 is in close contact with the seating groove 35 of the lower plate 30. Therefore, when the vacuum generator 8 is docked to the vacuum auxiliary device 50 of the capsule 100 and the vacuum generator 8 is operated, between the fixture 4 of the pellicle frame 5 and the seating groove 36 This can prevent gas from leaking by creating a gap.

In addition, when the capsule 100 is moved or flipped in a state where adsorption is not performed well for some reason, the pellicle 1 is fixed to prevent the pellicle 1 from being damaged.

9 is a view showing the ball plunger shown in FIG. 2. As shown in Fig. 9, the ball plunger 80 is disposed between the ball 82 and the bottom surface of the barrel 81 and the ball 82 fitted in the barrel 81 and the barrel 81 of a cylindrical shape ( 82 includes a coil spring 83 that applies an elastic force to the ball 82 in a direction away from the bottom surface of the barrel 81. The upper part of the barrel 81 is closed so that the ball 82 does not come off.

Hereinafter, the action of the capsule used for inspection of the pellicle for ultra-ultraviolet lithography will be described.

First, the pellicle 1 for ultra-ultraviolet lithography is seated on the lower plate 30 of the capsule 100 used for inspection of the pellicle for ultra-ultraviolet lithography. At this time, the fixture 4 of the pellicle 1 is placed in the seating groove 35. And the upper plate 10 is coupled to the lower plate 30.

Next, when the vacuum generator 8 is operated with the piston 64 in close contact with the second wall surface 618, gas is discharged through the pin-shaped suction port 9. Then, a gas flow occurs from the inside of the first channel 611 to the right, and the pressure on the right side of the first channel 611 is lower than the pressure on the left side. When the pressure difference becomes more than the attractive force between the permanent magnet and the piston 64, the piston 64 starts to move to the right.

When the piston 64 starts to move to the right, the connecting portion of the fourth channel 614 and the first channel 611 that was blocked by the piston 64 is opened. Then, the suction plate 553, the chamber 552, the third channel 551, the fourth channel 614, the first channel 611, the through hole 641 of the piston 64, the first channel 611 , The path connecting the second channel 612 and the pin-shaped inlet 9 is also opened.

Accordingly, the air in the inner space of the capsule 100 is discharged to the pin-shaped inlet 9 along this path, so that the internal pressure of the capsule 100 is lowered.

In addition, it is formed as a path connecting the fourth channel 614, the first flow path 519, the second flow path 39, and the vacuum hole 36 at the same time. Therefore, the fixture 4 of the pellicle frame 5 is in close contact with the seating groove 35.

The piston 64 continues to move to the right, and as shown in FIG. 5, when the piston 64 is in close contact with the first wall 617, the first channel 611 and the second channel ( 612) is closed. Then, the air in the inner space of the capsule 100 used for the inspection of the pellicle for ultra-ultraviolet lithography cannot be discharged through the gas outlet 511.

Therefore, the pressure in the inner space of the capsule 100 is automatically adjusted to an appropriate low vacuum state. If the degree of vacuum is too low, there is a fear that the pellicle 1 for ultra-ultraviolet lithography may be torn. The piston 64 is kept in close contact with the first wall surface 617 by a magnetic force between the piston 64 and the magnet of the first wall surface 617.

And at this time, by the piston 64, the right ball shaft 731a rises, and as a result, the arm 71a connected to the right ball shaft 731a rotates counterclockwise around the hinge pin 72. Thus, it can be confirmed that it is in a vacuum state because it goes down.

Next, when it is necessary to break the vacuum inside the capsule 100, the gas injection port 7 of the gas injection device 6 is opened to a fifth state while the piston 64 is in close contact with the first wall surface 617. After making close contact with the channel 615, the gas injection device 6 is operated to inject a high-purity gas such as nitrogen.

When gas is injected through the fifth channel 615, pressure is applied to the incision 642 cut diagonally of the piston 64. When the pressure increases compared to the magnetic force between the piston 64 and the first wall 617, the piston 64 moves to the left along the first channel 611.

Then, the suction plate 553, the chamber 552, the third channel 551, the fourth channel 614, the first channel 611, the through hole 641 of the piston 64, the first channel 611 , A path connecting the fifth channel 615 and the gas inlet 7 is opened.

Accordingly, the nitrogen gas injected through the gas injection port 7 is injected into the capsule 100, thereby increasing the internal pressure of the capsule 100.

In addition, it is simultaneously opened to a path connecting the fourth channel 614, the first flow path 519, the second flow path 39, and the vacuum hole 36. Accordingly, the fixture 4 of the pellicle frame 5 is in a state in which it can be separated from the seating groove 35.

The piston 64 continues to move to the left, and as shown in FIG. 4, when the piston 64 is in close contact with the second wall surface 618, the first channel 611 and the fourth channel ( 614) is closed. Then, nitrogen cannot be supplied to the inner space of the capsule 100 used for inspection of the pellicle for ultra-ultraviolet lithography anymore. Therefore, it is possible to prevent the pressure in the inner space of the capsule 100 used for inspection of the pellicle for ultra-ultraviolet lithography from being excessively high.

And at this time, by the piston 64, the left ball shaft 731b rises, and as a result, the arm 71b connected to the left ball shaft 731b rotates clockwise around the hinge pin 72 , As it goes down, it can be confirmed that the vacuum is destroyed.

Even if the vacuum is destroyed, the pellicle 1 is fixed to the seating groove 35 by the ball plunger 80 until the upper plate 10 and the lower plate 30 are separated.

The above-described embodiments are merely describing preferred embodiments of the present invention, and the scope of the present invention is not limited to the described embodiments, and those skilled in the art within the scope of the technical spirit and claims of the present invention Various changes, modifications, or substitutions may be made by this, and such embodiments are to be understood as being within the scope of the present invention.

For example, although it has been described that the vacuum vent bush 60 is coupled to the vacuum assist device 50, the vacuum assist device and the vacuum vent bush may be integrally formed.

100: capsule used for inspection of pellicle for ultra-ultraviolet lithography
10: top
20: top window
30: lower plate
40: lower window
50: vacuum aid
60: vacuum vent bush
70: vacuum indicator
80: ball plunger

Claims (12)

A top plate with an opening formed in the center,
An upper plate window installed in the opening of the upper plate and having an antireflection coating layer formed thereon,
Combined with the upper plate to form an inner space in which a pellicle for ultra-ultraviolet lithography is accommodated, and a plurality of vacuum holes formed on the bottom surface to adsorb and fix the pellicle frame of the pellicle for ultra-ultraviolet lithography and a vacuum formed on at least one side A lower plate on which an auxiliary device mounting groove is formed,
It is installed in the vacuum auxiliary device mounting groove of the lower plate and includes a vacuum auxiliary device having a gas outlet connected to the vacuum generating device and a first flow path connected to the gas outlet,
A capsule having a second flow path connecting the first flow path and the vacuum holes formed on the lower plate,
The vacuum auxiliary device includes a body portion and a suction portion extending from one side of the body portion, being fitted into the vacuum auxiliary device mounting groove, and having the first flow path,
The capsule further includes a vacuum vent bush coupled to the vacuum auxiliary device,
The vacuum vent bush has a first channel extending in a transverse direction in which both ends are blocked by a second wall surface opposite to the first wall, and is connected to the first channel at an angle, and the first channel and the suction port of the vacuum generator are connected. A second channel to connect is formed,
The vacuum vent bush further includes a piston that moves linearly between the first wall surface and the second wall surface along the first channel and has a through hole formed in a center thereof,
A third channel extending in a horizontal direction at a height different from that of the first channel is formed in the suction part of the vacuum auxiliary device,
A fourth channel connecting the first channel and the third channel is formed in the vacuum vent bush,
When the piston contacts the first wall surface, the connection portion between the first channel and the second channel is closed, and when the piston contacts the second wall surface, the connection portion between the first channel and the fourth channel is closed. Capsules used for inspection of pellicles for lithography. The method of claim 1,
An opening is formed in the center of the lower plate,
A capsule installed in the opening of the lower plate and used for inspection of a pellicle for ultra-ultraviolet lithography further comprising a lower panel window having an antireflection coating layer formed thereon. delete The method of claim 1,
In the vacuum vent bush, a fifth channel connected to the first channel is formed, and when the piston contacts the first wall, the connection part between the first channel and the fifth channel is closed, for inspection of a pellicle for ultra-ultraviolet lithography. Capsules used. The method of claim 4,
A capsule used for inspection of a pellicle for ultra-ultraviolet lithography, in which an inclined incision is formed so that the gas introduced through the fifth channel collides with the end of the piston on the first wall side to push the piston toward the second wall. The method of claim 1,
A capsule used for inspection of a pellicle for ultra-ultraviolet lithography in which a chamber in communication with the third channel is formed in the suction part, and a suction plate, which is a porous plate, is disposed on an open upper surface of the chamber. The method of claim 6,
The suction plate is a capsule used for inspection of a pellicle for ultra-ultraviolet lithography, which is a porous ceramic. The method of claim 1,
The first flow path is a capsule used for inspection of a pellicle for ultra-ultraviolet lithography connected to the fourth channel. The method of claim 1,
The first wall surface is a capsule used for inspection of a pellicle for ultra-ultraviolet lithography comprising a magnet for applying a magnetic force to the piston in a direction in which the piston and the first wall surface are close. The method of claim 1,
The second wall surface is a capsule used for inspection of a pellicle for ultra-ultraviolet lithography comprising a magnet for applying a magnetic force to the piston in a direction in which the piston and the second wall surface are close. The method of claim 1,
Further comprising a vacuum indicator having a pair of arms fixed to the indicator mounting portion of the vacuum vent bush so as to be rotatable by a hinge pin, and a pair of ball shaft plungers each fixed to one end of the pair of arms, ,
The ball shaft plunger includes a barrel, a ball shaft disposed in the barrel, and a compression spring having one end disposed in the barrel and the other end coupled to the arm,
The ball shaft plunger is installed in a through hole penetrating a wall surface between the indicator mounting portion and the first channel,
The ball-shaped end of the ball shaft is disposed inside the first channel, and when the piston passes under the ball shaft, the ball shaft rises and the arm connected to the compression spring of the ball shaft plunger rotates. A capsule used for inspection of pellicles for ultraviolet lithography. The method of claim 1,
A capsule used for inspection of a pellicle for ultra-ultraviolet lithography in which the vacuum auxiliary device and the vacuum vent bush are integrated.

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