KR20070033129A - Apparatus for washing chuck for wafer - Google Patents

Abstract

A chuck cleaning apparatus for a wafer is provided to remove impurity remaining on slots and a cleaning liquid residing on a chuck by cleaning the chuck comprised of a vertical unit and a horizontal unit and forming a cleaning unit on an opposite position with respect to the slots. A conveying unit(100) elevates and includes a slot(114) and a chuck(110). The slot mounts a wafer. The chuck has a horizontal unit supporting the slot at its side. A bath(200) is installed on a lower portion of the conveying unit and includes an inner cleaning tub(210) and an outer storing tub(220). An upper portion of the inner cleaning tub is opened. The inner cleaning tub is filled with a cleaning liquid. The outer storing tub collects the overflow cleaning liquid. A cleaning unit(120) is installed on an upper portion of the bath. The cleaning unit cleans a foreign substance formed on the chuck to spray the cleaning liquid. A gas spraying nozzle(140) is formed on a supporting unit and sprays nitrogen gas to remove the cleaning liquid remaining on the chuck. A mover(300) moves a side of the supporting unit upwardly and downwardly.

Description

Apparatus for washing chuck for wafer}

1 is a process flowchart schematically showing an etching process by a wet etching apparatus of the prior art.

2 is a view schematically showing an apparatus for cleaning a transfer part of a wet etching apparatus of the prior art.

3 is a perspective view schematically showing a chuck cleaning apparatus for a wafer according to the present invention.

4 is a cross-sectional view schematically showing the side of FIG.

5 is a side view schematically showing the side of FIG.

FIG. 6 is an enlarged partial view of A of FIG. 5.

7 is a state diagram showing the operation of the transfer unit of FIG.

<Explanation of symbols for the main parts of the drawings>

100: transfer unit 110: chuck

113: horizontal portion 114: slot

120: cleaning unit 121: supply pipe

122: injection nozzle 140: gas injection nozzle

200: bath 210: internal cleaning tank

212 bulkhead 213 cleaning supply pipe

220: external storage tank 222: drain pipe

300: flow part 302: screw

304: switch 306: wire

308: fixing nut 310: motor

312: through hole

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a chuck cleaning apparatus for a wafer, and more particularly, to remove foreign substances (DIW, chemical) formed in a chuck in a semiconductor manufacturing process, a DI injection nozzle and N ₂ are disposed on an upper portion of a cleaning tank. The present invention relates to a wafer chuck cleaning device for cleaning a rising chuck with a gas nozzle.

In general, with the higher integration of semiconductor devices, the technology for cleaning wafers is becoming more diversified and more important in semiconductor manufacturing processes.

In particular, in the manufacturing process of a semiconductor device having a fine structure, not only particles attached to the wafer after the wafer cleaning process, but also foreign matters (DIW, chemical), static electricity, watermarks, line particles, etc. Since the process has a great influence, the necessity of the wafer drying process is further increased.

Therefore, in the semiconductor manufacturing process, a cleaning process is performed on the surface of the wafer using chemical or pure water (DIW) before and after each step.

When the semiconductor device is manufactured, the photoresist coating and etching processes are performed on the surface of the wafer several times, and the surface of the wafer may be contaminated by foreign matter during the photoresist coating and etching processes.

Therefore, it can be said that the cleaning process is performed on the wafer in order to remove the foreign matter that is a pollution source.

In the cleaning process, a plurality of wafers are inserted into a slot in a cleaning tank containing chemical liquid to remove foreign substances by the flow of the chuck.

This washing process is performed by a wet washing apparatus equipped with a series of apparatuses including a washing tank and a chemical liquid supply pipe.

In the wafer cleaning process using the wet cleaning apparatus, the etching rate of the foreign matter on the wafer surface is somewhat different depending on the type and composition ratio of the chemical liquid, but it is usually closely related to the flow rate distribution of the chemical liquid in the cleaning tank.

FIG. 1 is a process flowchart schematically illustrating an etching process by a wet etching apparatus of the prior art, and FIG. 2 is a view schematically illustrating an apparatus for cleaning a transfer part of the wet etching apparatus of the prior art.

1 to 2, a chemical bath 10 for etching a wafer into which a solution is stored and injected, cleaning baths 20 and 30 in which a rinse liquid is contained to wash the wafer, and remaining on the surface of the wafer It consists of a drying tank 40 for removing the washing liquid, and a transfer unit 1 for sequentially transferring the wafer.

In the above, the chuck is lowered into the bath 60 in which the cleaning liquid 50 is contained by the transfer unit 1 to remove impurities from the chuck 2.

However, the transfer unit is provided with a wafer in each process tank during the process of the chuck formed with a slot for receiving the wafer, the foreign matter is deposited on the chuck and the slot there is an inconvenient problem that the chuck should be periodically cleaned.

In addition, the impurities formed in the chuck and remaining in the narrow space of the slots for loading the wafer are not easily removed.

In addition, there is a problem in that the chuck that does not completely remove impurities may chuck the wafer and contaminate the wafer.

The present invention has been invented to solve the problems of the prior art as described above, to provide a chuck cleaning device for a wafer that can easily clean the top of the bath containing the cleaning liquid for cleaning the chuck.

In order to achieve the above object, the present invention includes a transfer unit, a chuck, a cleaning unit, a gas injection nozzle, a bath, and a flow unit.

In order to achieve the above object, the present invention is configured to be lowered and lowered in the transfer part and the transfer part including a chuck configured to be raised and lowered, the slot for loading the wafer and the horizontal portion for supporting the slot on one side, A bath consisting of an internal cleaning tank filled with a cleaning liquid and an external storage tank for recruiting overflowing cleaning liquid and an upper portion of the bath, the cleaning portion is sprayed to clean foreign substances formed in the chuck, and the cleaning liquid remaining on the chuck is removed. It is characterized in that it comprises a gas injection nozzle which is injected to the nitrogen gas and configured to the support and the flow unit for flowing up and down one side of the support.

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

3 is a perspective view schematically showing a chuck cleaning apparatus for a wafer according to the present invention, Figure 4 is a cross-sectional view schematically showing the side of FIG.

In one embodiment of the present invention, the chuck cleaning apparatus for the wafer includes a transfer unit 100, the chuck 110, the cleaning unit 120, the gas injection nozzle 140, the bath 200, the flow unit 300. .

3 to 4, the bath 200, the cleaning unit 120, and the gas injection nozzle 140 are configured to clean the chuck 110 of the transfer unit 100 used in the wet etching apparatus. .

In the bath 200, the upper part is opened and is composed of an internal cleaning tank 210 and an external storage tank 220, the transfer unit 100 is configured at the top.

In addition, the internal cleaning tank 210 is connected to a cleaning liquid supply pipe 213 connected to a pump (not shown) configured at one side thereof, and supplies the cleaning liquid 50 to the internal cleaning tank 210 through the cleaning liquid supply pipe 213. do.

In addition, the external storage tank 220 is a drain pipe 222 is installed on the lower side, after receiving the washing liquid 50 overflows from the internal cleaning tank 210 and drains to the outside through the drain pipe 222.

Here, the internal cleaning tank 210 may be configured as a container having one opening 211, but preferably, a plurality of internal cleaning tanks are formed at the center of the internal cleaning tank 210 in order to use a small amount of the cleaning liquid 50. The partition 212 is formed.

The cleaning unit 120 and the gas injection nozzle 140 are configured to be adjacent to the opening 211 of the upper portion of the internal cleaning tank 210, the cleaning unit 120 is a supply pipe 121 in the longitudinal direction of the opening 211. ) Is configured.

In addition, the supply pipe 121 is installed to be adjacent to the slots 114 formed in each chuck 110, respectively.

The supply pipe 121 has a plurality of injection holes 122 are formed in a position facing the slots 114, and the deionized water is injected through the injection hole (122).

On the other hand, the first support portion 130a is coupled to one side of the upper portion of the opening 211, and the second support portion 130b is coupled to the position opposite to the first support portion 130a, and the first support portion 130a and the second support portion 130a are coupled to each other. The support part 130b protrudes to a position higher than the supply pipe 121, and a plurality of gas injection nozzles 140 are formed in the first support part 130a and the second support part 130b.

In the gas injection nozzle 140, nitrogen gas N ₂ is injected, and one end of the first support part 130a and the second support part 130b is connected.

In addition, a flow part 300 for allowing the rear of the second support 130b to flow at a predetermined angle is configured at one side of the rear surface of the second support 130b and one side of the upper surface of the inner cleaning tank 210.

In the above, the gas injection nozzle 140 is provided with a pair in each side with respect to the chuck 110 in which the slots 114 are formed.

The chuck 110 includes a plurality of vertical parts 111 and 112 connected in a vertical direction with the transfer part 100 and a horizontal part 113 connecting the vertical parts 111 and 112.

The horizontal portion 113 includes a first horizontal portion 113a and a second horizontal portion 113b, and slots 114 are formed to accommodate a plurality of wafers.

In addition, the vertical portions 111 and 112 are constituted by a pair of first vertical portions 111a and 111b and a pair of second vertical portions 112a and 112b.

In the above, the first horizontal portion 113a connects the lower ends of the pair of first vertical portions 111a and 111b, and the second horizontal portion 113b connects the lower ends of the pair of second vertical portions 112a and 112b. It has a structure to connect.

Therefore, the slots 114 for loading the edges of the wafer are formed at the lower ends of the first horizontal portion 113a and the second horizontal portion 113b to face each other at a predetermined distance from each other due to the size of the wafer.

In addition, a pair of gas injection nozzles 140 are respectively installed in both directions with respect to the first horizontal part 113a, and another pair of gas injection nozzles 140 are centered on the second horizontal part 113b. It is installed in both directions.

FIG. 5 is a side view schematically showing the side of FIG. 3, FIG. 6 is a partially enlarged view of part A of FIG. 5, and FIG. 7 is a state diagram showing the operation of the transfer unit.

5 to 7, when descending to the internal cleaning tank 210 to clean the chuck 110, the foreign matter is attached, the horizontal portion (111, 112) and the slot 114 is formed with a predetermined time elapsed ( Impurities in 113 are removed.

Next, when a predetermined time elapses, when the chuck 110 is raised to the upper portion of the inner cleaning tank 210, the washing unit formed on the opening 211 is composed of a plurality of pure water (DIW) supplied through the supply pipe of the washing unit. Injected from the injection hole 122 is to intensively clean the slots 114 formed in the horizontal portion (113).

Next, while the chuck 110 is raised and lowered, the gas injection nozzle 140 sprays nitrogen gas (N ₂ ) while the horizontal portion 113 is being cleaned, thereby drying the chuck 110.

In the process of removing the foreign substances of the chuck 110 and the lower horizontal portion 113 in the liquid is sprayed in the cleaning unit 120 is formed in a droplet shape by the surface tension of the chuck 110, the gas injection nozzle ( Water droplets are not completely removed even when nitrogen gas is injected from 140).

Therefore, the flow part 300 is fixed to the lower surface of the second support part 130b to remove the water droplets formed on the chuck 110 and the horizontal part 113, and one side is fixed to the inner cleaning tank 210.

The flow unit 300 includes a motor unit 310 electrically connected to the wire 306 and a switch 304 that controls the motor unit 310 on the front surface and includes a rising, lowering, and on / off function. The upper surface of the motor unit 310, the screw 302 is configured to be rotatable.

The screw is cylindrical in shape and has a thread shape on the outer surface from top to bottom, and rotates by the operation of the motor part 310 to raise or lower the second support part 130b coupled to the other end of the screw, and select the switch 304. Thus, the motor 310 may operate to stop the second support 130b at a desired position.

The fixing nut 308 is coupled to the lower side of the second support portion 130b and coupled to the screw 302 to flow the second support portion 130b by the rotation of the screw 302, and the upper portion of the fixing nut 308. Through holes 312 into which the screw 302 is inserted are formed.

The through hole 312 is a space in which the screw 302 protrudes above the fixing nut 308 when the screw 302 is rotated to lower the second support 130b.

In addition, the through hole 312 inserts the fixing nut 308 and when the screw 302 is rotated to raise and lower the second support part 130b, the screw 302 protruding above the fixing nut 308 is inserted. It is a space.

Therefore, the gas support nozzle 140 configured at the first support 130a and the second support 130b is operated at a predetermined angle by the operation of the flow unit 300 configured at the second support 130b. Ascending to the gas injection nozzle 140 is formed a slope.

Nitrogen gas injected from the gas injection nozzle 140 inclined at a predetermined angle in the chuck 110 is raised to the horizontal portion 113 of the chuck 110 and the lower portion as the chuck 110 passes through the gas injection nozzle 140. The resulting droplets flow from the front to the rear, and the droplets merge with each other to increase in size, and the droplets of increased size are separated from the chuck 110 and the horizontal portion 113 because their weight is heavier than the surface tension.

As described above, according to the present invention, when the gas injected from the gas injection nozzle inclined at a predetermined angle passes through the gas injection nozzle while the chuck rises, the water droplets formed in the corresponding horizontal part of the chuck and the lower part are forward to rearward. When flowing in, the water droplets are increased in size and removed from the chuck and the horizontal portion is effective.

In addition, at the same time as cleaning the chuck consisting of the vertical portion and the horizontal portion, the cleaning portion is provided in a position opposite to the slots are sprayed into the narrow space of the slots, it is effective to remove the impurities remaining in the slots more effectively.

In addition, the rinsing slot and slotted chuck are cleaned in the bath filled with the cleaning solution, the slots formed in the chuck are intensively removed from the washing section injecting deionized water to remove fine impurities, and then nitrogen gas is injected through the gas injection nozzle. It is effective in removing the cleaning liquid remaining in the chuck.

As a result, it is possible to improve the added value of the product configured using the present invention to improve the merchandise and quality of the product, as well as to have the effect to give reliability.

As described above, although described with reference to a preferred embodiment of the present invention, those skilled in the art will be variously modified without departing from the spirit and scope of the invention described in the claims below. And that it can be changed.

Claims (6)

A transfer part including a chuck configured to move upward and downward and include a slot for loading a wafer and a horizontal part supporting the slot; A bath disposed below the transfer part and configured to include an internal cleaning tank in which an upper portion thereof is opened and a cleaning liquid is filled, and an external storage tank collecting overflowing cleaning liquid; A cleaning unit installed on the bath and cleaning the foreign matter formed in the chuck by spraying the cleaning liquid; A gas injection nozzle configured to support a nitrogen gas and to support the cleaning solution remaining in the chuck; And Chuck cleaning device for a wafer, characterized in that it comprises a flow portion for flowing one side of the support portion up and down. The chuck cleaning apparatus for a wafer according to claim 1, wherein the cleaning unit is configured between the bath and the gas injection nozzle. The apparatus of claim 1, wherein the flow unit comprises a motor unit electrically connected to the flow unit; A switch configured on the front of the motor unit and including a rising, lowering, and on-off function; And The motor unit is operated by the operation of the switch, the upper surface of the wafer chuck cleaning apparatus comprising a screw configured to be rotatable by the drive of the motor unit. 4. The screw of claim 3, wherein the screw has a cylindrical shape on the outer surface from top to bottom, rotates by driving of the motor part, and raises or lowers the second support part coupled to the other end to rotate the gas injection nozzle at an angle. Chuck cleaning device for a wafer, characterized in that to maintain the slope of the. The method of claim 1, wherein the support portion is formed of a first support portion in the front and a second support portion in the rear, the lower side of the second support portion is coupled to the screw, and includes a fixing nut for flowing the second support portion by the rotation of the screw Chuck cleaning device for a wafer, characterized in that. 6. The chuck cleaning method according to claim 5, further comprising a through hole formed to insert the fixing nut and to insert a screw protruding above the fixing nut when the screw rotates to raise and lower the second support. Device.

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