KR20170021410A - Chucking System for Process Chamber Using Mask - Google Patents

Abstract

The present invention relates to a chucking system to supplement that a glass substrate processed in a processing chamber is sagged by self-weight. According to the present invention, a chucking system installed in a chamber to perform a deposition or etching process on a lower surface of the glass substrate by using a mask comprises: a holding unit placed on an upper side of the glass substrate having the mask placed on a lower side thereof, holding the glass substrate with magnetic force to lift the mask and the glass substrate, and cooling the glass substrate; and a chucking unit to hold a part of the glass substrate in order to prevent a part of the glass substrate held by the holding unit from being sagged by the self-weight. Since a region of the glass substrate receiving force held by the holding unit is overlapped with at least a part of the region of the glass substrate receiving the force held by the chucking unit, deformation of a large glass substrate caused by sagging due to the self-weight of the glass substrate is restricted while a process is performed to the large glass substrate, so product defect due to the deformation of the glass substrate can be reduced or inhibited.

Description

[0001] The present invention relates to a chucking system for a process chamber using a mask,

The present invention relates to a chucking system for a process chamber using a mask, and more particularly, to a chucking system for a process chamber in which a mask is used to process a glass substrate, To a chucking system for a process chamber using a mask.

Generally, in producing a display device, a variety of deposition processes are performed on a glass substrate. Particularly, as the size of the glass substrate and the self-load of the glass substrate are increasing, Since a glass substrate having a large area and large surface area has a large self-load, deformation due to the glass substrate stuck may occur during various processes.

The glass substrate is likely to be deformed due to deflection because it is in a relatively high temperature state during various processes. Therefore, there is a great need to supplement the large-area glass substrate so that deformation due to deflection does not occur even during the process in the process chamber.

Various techniques for suppressing or preventing the warpage of the glass substrate have been proposed. Among these conventional technologies, Korean Patent No. 10-1208262 (the name of the invention: glass inspection apparatus, hereinafter referred to as prior art 1) .

According to the prior art 1, a technique is disclosed in which air is injected onto a glass substrate so as to prevent deformation due to deflection of the glass substrate in the process of transferring the glass substrate for inspecting the glass substrate.

However, according to the prior art 1, it is difficult to uniformly spread the air over the entire surface of the glass substrate, and there is a problem in that a portion of the substrate may be distorted due to unbalanced air pressure.

In the case of the prior art 1, since the technique of raising the glass substrate upward by air pressure at the lower side of the glass substrate, when the upper side of the substrate is held and a process such as pattern formation is performed on the lower side of the substrate, 1, there is a problem that the technology using air pressure can not be applied.

SUMMARY OF THE INVENTION The object of the present invention is to solve the above-mentioned problems of the prior art, and an object of the present invention is to provide a glass substrate having a large area, which can be supplemented to prevent the glass substrate from being sagged downward due to its own load, And a chucking system for a process chamber to be used.

According to an aspect of the present invention, there is provided a chucking system for a process chamber using a mask, including: a chucking system provided in a chamber for performing a deposition or etching process on a lower surface of a glass substrate using a mask; And a holding member for holding the glass substrate by using a magnetic force so as to lift the mask and the glass substrate and for holding the glass substrate by cooling the glass substrate, )part; And a chucking unit for holding a part of the glass substrate so that a part of the glass substrate held by the holding unit is not subject to self-load, wherein the holding unit comprises: A magnet plate for holding the glass substrate using a magnetic force from above the glass substrate; And a cooling plate provided below the magnet plate and cooling the glass substrate held by the magnet plate from above, wherein the chucking portion includes a first plate formed on a part of the cooling plate, A chucking plate positioned within the chucking hole for holding a portion of the glass substrate so as not to be sagged; And a chucking rod located in a second chucking hole formed in a part of the magnet plate, the chucking rod being coupled to the chucking plate and supporting the chucking plate so that the chucking plate can hold the glass substrate. Wherein a diameter of the chucking plate having a circular shape is smaller than an inner diameter of the first chucking hole and is larger than an inner diameter of the second chucking hole, And may be formed as one feature.

According to another aspect of the present invention, there is provided a chucking system for a process chamber using a mask, including: a chucking system provided in a chamber for performing a deposition or etching process on a lower surface of a glass substrate using a mask; And a holding member for holding the glass substrate by using a magnetic force so as to lift the mask and the glass substrate and for holding the glass substrate by cooling the glass substrate, )part; And a chucking part for holding a part of the glass substrate so that a part of the glass substrate held by the holding part is not sagged by a self-load, wherein the holding part receives a force to be held by the holding part The region of the glass substrate and the region of the glass substrate which receives the force held by the chucking portion overlap each other at least in part.

Here, the holding unit may include: a magnet plate for holding the glass substrate on the upper side of the glass substrate located on the lower side of the mask using a magnetic force; And a cooling plate provided below the magnet plate and cooling the glass substrate held by the magnet plate from the upper side.

Furthermore. Wherein the chucking portion includes a chucking plate positioned in a first processing hole formed in a portion of the cooling plate and holding the portion of the glass substrate so as not to be squeezed; And a chucking rod located in a second chucking hole formed in a portion of the magnet plate, the chucking rod being coupled to an upper side of the chucking plate and supporting the chucking plate so that the chucking plate can hold the glass substrate. May be another feature of the present invention.

Here, the chucking rod may further include a steel use stainless steel (SUS)

를 포함하여 이루어진 것을 또 하나의 특징으로 할 수도 있다. Here, the chucking plate

May be another feature of the present invention.

Here, the magnet plate may include a metal plate made of a magnetic material magnetized by an external magnetic field; And a magnet provided above the metal plate to generate a magnetic field.

Further, a plurality of magnets may be disposed on the upper surface of the metal plate so that a magnetic field may be generated evenly on at least a part of the lower side of the metal plate.

Here, the first chucking hole is formed at the center portion of the cooling plate, the second chucking hole is formed at the center portion of the magnet plate, and the central portion of the glass substrate is not sagged by its own load The chucking plate may hold another feature.

A plurality of the first choking holes are formed in the cooling plate, and a plurality of the second choking holes are formed in the magnet rate. In each of the first and second choking holes, And that the chucking rod is located.

Here, the force that the chucking plate holds a part of the glass substrate is an electrostatic force so that a part of the glass substrate is not deposited.

Here, the chucking plate may have a circular shape, and the outer diameter of the chucking plate may be smaller than or equal to the inner diameter of the chucking hole formed in the magnet plate.

Here, the chucking plate may have a circular shape, and the outer diameter of the chucking plate may be smaller than or equal to the inner diameter of the chucking hole formed in the cooling plate.

The chucking system for a process chamber using the mask according to the present invention can suppress the deformation of a glass substrate caused by deflection of a large-area glass substrate by its own load while a process is performed on a large- , It is possible to suppress the generation of defective products and to improve the production efficiency.

1 is a cross-sectional perspective view schematically illustrating a chucking system for a process chamber using a mask, in accordance with an embodiment of the present invention.
2 is a cross-sectional perspective view schematically illustrating a magnet plate in a chucking system for a process chamber using a mask, in accordance with an embodiment of the present invention.
3 is a schematic cross-sectional view of a cooling plate in a chucking system for a process chamber using a mask, in accordance with an embodiment of the present invention.
Figures 4 and 5 are cross-sectional views schematically illustrating cross-sectional views of a chucking system for a process chamber using a mask, in accordance with an embodiment of the present invention.
Figure 6 is a cross-sectional view schematically illustrating another aspect of the chucking system for a process chamber using a mask, in accordance with an embodiment of the present invention.
7 is a cross-sectional view schematically illustrating a chucking system for a process chamber using a mask, according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view schematically illustrating a chucking system for a process chamber using a mask according to an embodiment of the present invention, and FIG. 2 is a perspective view of a magnet plate in a chucking system for a process chamber using a mask, 3 is a plan view schematically illustrating a cooling plate in a chucking system for a process chamber using a mask according to an embodiment of the present invention and Figs. 4 and 5 are cross- Sectional view schematically showing a cross-sectional view of a chucking system for a process chamber using a mask, and Fig. 6 is a cross-sectional view schematically illustrating another aspect of a chucking system for a process chamber using a mask, according to an embodiment of the present invention.

1 to 5, a chucking system for a process chamber using a mask according to an embodiment of the present invention includes: a chucking unit provided in a process chamber for performing a deposition or etching process on a lower surface of a glass substrate using a mask, System 200 includes a holding unit 200 and a chucking unit 100. [

The holding part 200 is located on the upper side of the glass substrate 10 on which the mask 300 is located. The holding unit 200 is provided on the lower surface of the glass substrate 10 by using a magnetic force so that the mask 300 and the glass substrate 10 can be lifted from the upper side of the glass substrate 10, Hold. Further, the glass substrate 10 is cooled so as to suppress the temperature rise of the glass substrate 10 and to lower the temperature of the glass substrate 10.

The chucking part 100 holds a part of the glass substrate 10 so that a part of the glass substrate 10 held by the holding part 200 is not sagged downward due to its own load.

In other words, since the glass substrate 10 held and lifted by the holding unit 200 has a large self-load, it may cause a deflection phenomenon in a part thereof. In order to prevent or suppress such a sagging phenomenon, Thereby holding a part of the glass substrate 10.

The chucking part 100 and the holding part 200 will be described in more detail as follows.

First, the holding part 200 includes a magnet plate 210 and a cooling plate 220.

The magnet plate 210 is a plate for forming a magnetic field on the upper side of the glass substrate 10 located below the mask 300 to hold the glass substrate 10 by using a magnetic force.

The magnet plate 210 may be formed of a single magnet plate (not shown), and an embodiment including the metal plate 212 and the magnet 211 as shown in FIG. 2 is also possible.

The metal plate 212 is a plate made of a magnetic material material magnetized by an external magnetic field.

It is preferable that the magnet 211 forms a magnetic field and can draw a metallic material or the like by magnetic force and a plurality of magnets 211 are disposed on the upper surface of the metal plate 212. That is, it is preferable that a plurality of magnets 211 are disposed on the upper side of the metal plate 212 so that a magnetic field can be uniformly generated at at least a part of the lower side of the metal plate 212.

It is not easy to manufacture a large magnet plate 210 corresponding to a large-sized glass substrate 10. It is also possible to form a single magnet plate 210 by arranging a plurality of magnets 211 on a large metal plate 212 It is.

2, when a plurality of magnets 211 are disposed on one metal plate 212, the magnetic force is uniformly distributed throughout the mask 300 located below the glass substrate 10, It is also preferable that the plurality of magnets 211 are disposed at equal intervals from each other.

In this way, a single magnet plate 210 can be formed by disposing a plurality of magnets 211 on one metal plate 212.

The cooling plate 220 is provided on the lower side of the magnet plate 210. And the glass substrate 10 held by the magnet plate 210 is cooled from above.

The cooling plate 220 is preferably made of a material having high thermal conductivity. As shown in FIG. 3, it is preferable that a cooling pipe 222 is disposed inside the cooling plate 220.

It is preferable that the cooling tube 222, through which the refrigerant flows, is arranged so as to evenly pass through the inside of the cooling plate 220 as shown in FIG. 3 for even cooling over the entirety of the cooling plate 220 Do. The refrigerant is drawn into the inlet of the cooling pipe 222 and cooled uniformly while the cooling plate 220 is passing through the cooling pipe 222. Thereafter, the refrigerant flows out to the outlet and flows to the cooler (not shown).

The cooling plate 220 is cooled evenly over the entire surface of the glass substrate 300 in contact with the upper surface of the glass substrate 300.

It is preferable that the cooling plate 220 has a first chucking hole 225 formed therein so that the chucking unit 100 can hold a part of the glass substrate 10.

The magnet plate 210 is preferably formed with a second hooking hole 215 so that the chucking part 100 can hold a part of the glass substrate 10.

A detailed description of the first and second choking holes 225 and 215 formed on the cooling plate 220 and the magnet plate 210 will be omitted in the following description of the chucking rod 110 and the chucking plate 215 of the chucking unit 100, Will be described with reference to FIG.

Next, the chucking unit 100 will be described.

The chucking part 100 holds a part of the glass substrate 10 so that a part of the glass substrate 10 held by the holding part 200 is not sagged by its own load and the chucking rod 110 and the chucking plate (120).

The chucking rod 110 is engaged with the chucking plate 120 above the chucking plate 120 as referenced in FIG. And supports the chucking plate 120 so that the chucking plate 120 can hold the glass substrate 10.

The chucking rod 110 preferably includes a steel use stainless steel (SUS) material.

The chucking rod 110 coupled with the chucking plate 120 is located inside the first and second chucking holes 225 and 215 and supports the chucking plate 120.

A chucking plate 120 coupled with the chucking rod 110 and supported by the chucking rod 110 is located within the first chucking hole 225 formed in a portion of the cooling plate 220. And holds a part of the glass substrate 10 so as not to sag.

For this purpose, it is preferable that the cooling plate 220 is provided with a first chucking hole 225 and the magnet plate 210 is provided with a second chucking hole 215. The first and second choking holes 225 and 215 may be formed at the center of the cooling plate 220 and the magnet plate 210, respectively.

The first and second hooking holes 225 and 215 may be formed so as to communicate with each other and may be formed so that the center axes of the first and second hooking holes 225 and 215 coincide with each other desirable.

4 and 5, when the first and second hooking holes 225 and 215 are formed in a circular shape, the first and second hooking holes 225, It is preferable that it is formed larger than the inner diameter.

FIGS. 4A to 4C and FIGS. 5A to 5C show various exemplary embodiments of the first hooking hole 225 having an inner diameter larger than that of the second hooking hole 215. FIG. 4 and 5, if the first hooking hole 225 is formed to be larger than the inner diameter of the second hooking hole 215, the shape of the cross section of the first hooking hole 225 is the same as that shown in FIG. 4 There are many possible forms as well.

The chucking plate 120 located in the first chucking hole 225 formed to be larger than the inner diameter of the second choking hole 215 is formed to be larger than the inner diameter of the second chucking hole 215, Is preferably formed. When the outer diameter of the chucking plate 120 is larger than the inner diameter of the second handling hole 215, the holding by the magnetic force of the magnet plate 210 and the holding by the chucking plate 120 in a part of the glass substrate overlap So that the glass substrate 10 can be held while the sagging of the glass substrate 10 is further suppressed.

From a slightly different point of view, it can be explained as follows.

The first and second choking holes 225 and 215 may be rectangular holes rather than circular holes. In this case, the chucking plate 120 may also be a rectangular plate.

If the shape is not circular, it can be explained as a region where a force acts on the glass substrate 10 and the mask 300.

In FIG. 6, reference numeral A1 denotes a region held by the electrostatic force of the chucking plate 120. FIG. And reference symbol A2 denotes a region held by the magnetic force of the magnet plate 210. [ Reference numeral A12 denotes an area where the area held by the electrostatic force of the chucking plate 120 overlaps with the area held by the magnetic force of the magnet plate 210. [

The area of the glass substrate (that is, the area A1 held by the electrostatic force of the chucking plate 120) subjected to the force held by the holding part and the area of the glass substrate which receives the force held by the chucking part At least a portion of the region A12 where the electrostatic force and the magnetic force act in a superimposed manner exists between the region A11 held by the magnetic force of the plate 210 and the region A2 held by the magnetic force of the plate 210. [

The region A12 in which the electrostatic force and the magnetic force overlap each other is present between the region A1 held by the electrostatic force of the chucking plate 120 and the region A2 held by the magnetic force of the magnet plate 210 It is possible to hold the glass substrate 10 while further suppressing the sagging of the glass substrate 10.

In other words, when the magnet plate 210 holds the mask 300 on the lower side of the glass substrate 10 by magnetic force, magnetic force is applied to the portion of the mask 300 located on the vertically lower portion of the second handling hole 215 It is difficult to work. The vertically lower portion A1 of the glass substrate 10 to which the chucking plate 120 contacts is held by the chucking plate 120 with an electrostatic force.

Therefore, the region A2 where the magnetic force acts on the magnet plate 210 and the region A1 where the electrostatic force acts on the chucking plate 120 are overlapped with each other.

Since there is a region A12 which is held by the magnet plate 120 and the chucking plate 120 in a redundant manner while the deflection of the glass substrate 10 is compensated by the chucking plate 120, The degree of suppression of deflection is increased.

If the chucking plate 120 and the chucking rod 110 alone are provided, it is preferable that the chucking unit 100 hold the center portion of the glass substrate 10. Therefore, as shown in FIGS. 2 and 3, The first and second chucking holes 225 and 215 are preferably formed at the central portion of the magnet plate 220 and the magnet plate 210, respectively.

When the first and second chucking holes 225 and 215 are formed and the chucking unit 100 is positioned on the first and second chucking holes 225 and 225, 120 can be held.

The chucking plate 120 is held in contact with a portion of the upper side of the glass substrate 10 so that a part of the glass substrate 10 is not sagged downward. When the first and second chucking holes 225 and 215 are formed at the center of the cooling plate 220 and the magnet plate 210, a part of the glass substrate 10 held by the chucking plate 120 is in the center It becomes a site.

4 and 5, the upper part of the glass substrate 10 to which the chucking plate 120 is in contact is formed in the vertical lower part inside the first handling hole 225 formed in the cooling plate 220 Quot; refers to the portion of the glass substrate 10 on which the glass substrate 10 is formed.

It is preferable that the force that the chucking plate 120 holds a part of the glass substrate 10 is an electrostatic force so that a part of the glass substrate 10 is not deposited.

The chucking plate 120 may have a rectangular shape, but may have a circular shape as shown in the drawings.

When the chucking plate 120 has a circular shape, as shown in FIGS. 4 and 5, it is preferable that the outer diameter of the chucking plate 120 is larger than the inner diameter of the second chucking hole 215 formed in the magnet plate 210 Do.

The outer diameter of the chucking plate 120 is preferably smaller than or equal to the inner diameter of the first chucking hole 225 formed in the cooling plate 220.

과 같은 세라믹 소재를 포함하여 이루어진 형태도 가능하며, 이 또한 바람직하다. The chucking plate 120

Or a ceramic material such as a ceramic material.

The chucking plate 120 and the chucking rod 110 can be moved as follows to hold the glass substrate 10.

The chucking rod 110 supporting the chucking plate 120 moves from the upper side to the lower side to allow the chucking plate 120 to hold the glass substrate 10. The glass substrate 10 is held by the magnet plate 210 with the chucking rod 110 and the chucking plate 120 separated from the glass substrate 10 as shown in FIG. Then, as shown in FIG. 5, the chucking plate 120 and the chucking rod 110 are lowered to come into contact with a part of the glass substrate 10. Then, the chucking plate 120 holds a part of the glass substrate 10.

The embodiment as shown in FIG. 7 is also applicable to the chucking system as described above.

7 is a cross-sectional view schematically illustrating a chucking system for a process chamber using a mask, in accordance with an applied embodiment of the present invention.

7, the mask 300 is provided on the lower surface of the large-sized glass substrate 10. However, unlike the above-described example, the cooling plate 220 is provided with a plurality of And a plurality of second handling holes 215 are formed in the magnet plate 210. A plurality of first and second processing holes 225 and 215 are formed in the magnet plate 210, Embodiments in which the chucking plate 120 and the chucking rod 110 are located are also possible.

When a plurality of chucking rods 110 and a plurality of chucking plates 120 are provided in one chucking system as shown in FIG. 7, when one chucking rod 110 and one chucking plate 120 are provided It is possible to more effectively compensate for deflection of the large-area glass substrate 10, which is preferable.

In this way, in order to prevent a part of the glass substrate held by the magnet plate in the process chamber from being sagged by its own load, each of the plurality of lift modules may be supported against a part of the glass substrate, The glass substrate is supported with elasticity while minimizing the occurrence of damage such as scratches on the lower surface of the glass substrate. And, while the glass substrate is being transferred by the substrate transfer robot hand, the sagging of the glass substrate is prevented or suppressed by the lift module.

As described above, according to the present invention, a chucking system for a process chamber using a mask is a chucking system for a glass substrate, which is caused by deflection of a large-area glass substrate by its own load while a process for a large- It is possible to suppress the generation of defective products and to improve the production efficiency.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is to be understood that the scope of the present invention is to be construed as being limited only by the embodiments, and the scope of the present invention should be understood as the following claims and their equivalents.

110: chucking rod 120: chucking plate
210: Magnet plate 220: Cooling plate
211: Magnet 215: Second processing hole
222: cooling pipe 225: first processing hole
300: mask 10: glass substrate

Claims (13)

1. A chucking system provided in a chamber for performing a deposition or etching process on a lower surface of a glass substrate using a mask,
A holding unit for holding the glass substrate by using a magnetic force so as to lift the mask and the glass substrate and for cooling the glass substrate, the mask being positioned on a lower side of the glass substrate, ; And
And a chucking part for holding a part of the glass substrate so that a part of the glass substrate held by the holding part is not squeezed by its own load,
Wherein,
A magnet plate for holding the glass substrate on the upper side of the glass substrate located on a lower side of the mask using a magnetic force; And
And a cooling plate provided below the magnet plate for cooling the glass substrate held by the magnet plate from above,
The chucking portion
A chucking plate located in a first handling hole formed in a part of the cooling plate and holding a part of the glass substrate so as not to be sagged; And
A chucking rod located in a second chucking hole formed in a part of the magnet plate, the chucking rod being coupled to an upper side of the chucking plate and supporting the chucking plate so that the chucking plate can hold the glass substrate; / RTI >
The first choking hole is formed larger than the inner diameter of the second choking hole,
Wherein the diameter of the chucking plate having a circular shape is smaller than the inner diameter of the first chucking hole but larger than the inner diameter of the second chucking hole. 1. A chucking system provided in a chamber for performing a deposition or etching process on a lower surface of a glass substrate using a mask,
A holding unit for holding the glass substrate by using a magnetic force so as to lift the mask and the glass substrate and for cooling the glass substrate, the mask being positioned on a lower side of the glass substrate, ; And
And a chucking part for holding a part of the glass substrate so that a part of the glass substrate held by the holding part is not squeezed by its own load,
Characterized in that the region of the glass substrate which receives the force held by the holding portion and the region of the glass substrate which receives the force held by the chucking portion overlap at least in part. . 3. The method of claim 2,
Wherein,
A magnet plate for holding the glass substrate on the upper side of the glass substrate located on a lower side of the mask using a magnetic force; And
And a cooling plate provided below the magnet plate for cooling the glass substrate held by the magnet plate from above. 2. The chucking system according to claim 1, The method of claim 3,
The chucking portion
A chucking plate located in a first handling hole formed in a part of the cooling plate and holding a part of the glass substrate so as not to be sagged; And
A chucking rod located in a second chucking hole formed in a portion of the magnet plate and coupled to the chucking plate and supporting the chucking plate so that the chucking plate can hold the glass substrate; Wherein the chucking system comprises: a substrate; The method according to claim 1 or 4,
Wherein the chucking rod comprises a steel use stainless steel (SUS). The method according to claim 1 or 4,
The chucking plate

And < RTI ID = 0.0 >
A chucking system for a process chamber using a mask. The method according to claim 1 or 4,
The magnet plate may include:
A metal plate made of a magnetic material magnetized by an external magnetic field; And
And a magnet provided on the upper surface of the metal plate and generating a magnetic field. 8. The method of claim 7,
Wherein a plurality of magnets are disposed above the metal plate so that a magnetic field can be uniformly generated in at least a part of the lower side of the metal plate. The method according to claim 1 or 4,
Wherein the first chucking hole is formed at a center portion of the cooling plate, the second chucking hole is formed at a center portion of the magnet plate,
Characterized in that the chucking plate holds the center portion of the glass substrate so that it is not sagged by its own load. The method according to claim 1 or 4,
Wherein a plurality of the first choking holes are formed in the cooling plate, a plurality of the second choking holes are formed in the magnet rate,
Wherein the chucking plate and the chucking rod are located in each of the first and second chucking holes. The method according to claim 1 or 4,
Wherein the force that causes the chucking plate to hold a portion of the glass substrate is an electrostatic force so that a portion of the glass substrate is not deposited. 5. The method of claim 4,
The chucking plate has a circular shape,
Wherein the outer diameter of the chucking plate is larger than the inner diameter of the second chucking hole formed in the magnet plate. 5. The method of claim 4,
The chucking plate has a circular shape,
Wherein the outer diameter of the chucking plate is smaller than the inner diameter of the first chucking hole formed in the cooling plate.

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