JP2009129997A - Surface treatment apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a surface treatment apparatus capable of preventing or suppressing the leakage and diffusion of treatment gas to the outside of a system. <P>SOLUTION: On a surface 33 facing a workpiece W at a nozzle section, a blowout port 31 for blowing out treatment gas and a suction port 34 are formed. An edge at a side opposite to the side of the blowout port 31 in the suction port 34 is retracted to an upper side (the opposite side in the direction of a facing surface) of the edge at the side of the blowout port 31, and a second surface section 33b outside the suction port 34 is retracted to an upper side (the opposite side in the direction of a facing surface) of a first surface part 33a between the suction port 34 and the blowout port 31. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an apparatus for performing a surface treatment by spraying a processing gas on a workpiece and sucking and discharging the gas after the spraying.

For example, in the nozzle part of the surface treatment apparatus of Patent Document 1, an injection port and a suction port are opened on the surface facing the object to be processed. A processing gas is injected from the injection port and comes into contact with the object to be processed, so that surface treatment is performed. The treated gas is sucked from the suction port.
JP-A-9-92493

In many cases, the processing gas contains a corrosive or toxic component. For this reason, if the diffusion of the processing gas is allowed, each member is corroded and a safety problem is caused. In particular, when continuous processing is performed in-line using a roller conveyor, a moving stage, or the like, leakage from the processing chamber is likely to occur, and corrosion of the drive system, piping system, housing, etc. is a problem. Leakage outside the system can be prevented as much as possible by making the processing chamber hermetically sealed and performing single-wafer processing, but it takes time to put in and out the workpiece and slows down the production rate.
The present invention has been made in view of the above circumstances, and an object of the present invention is to prevent or suppress the diffusion and leakage of the processing gas to the outside of the processing chamber without sealing the processing chamber. The object is to provide a nozzle structure suitable for processing.

The present invention has been proposed in view of the above circumstances, and is an apparatus for spraying a processing gas onto an object to be processed to perform surface treatment,
A nozzle portion facing a processing position where a workpiece is to be disposed is provided, and a nozzle port for jetting the processing gas toward the processing position and a suction port for sucking the gas are arranged in the nozzle portion. The edge of the suction port opposite to the jet port side is recessed from the edge of the jet port side to the opposite side of the facing direction.
Accordingly, it is possible to easily draw the atmospheric gas outside the nozzle portion, and it is possible to prevent or suppress the processing gas from leaking and diffusing outside the system due to the drawing flow of the atmospheric gas. Therefore, it is possible to facilitate continuous processing of the object to be processed and thus in-line processing.

The surface of the nozzle portion facing the processing position is a first surface portion between the jet port and the suction port, and a second surface opposite to the first surface portion across the suction port. It is preferable to have a portion.
The second surface portion may be recessed to the opposite side of the facing direction from the first surface portion. As a result, it is possible to facilitate the drawing of the external atmospheric gas, and it is possible to reliably prevent or suppress the leakage and diffusion of the processing gas.

It is preferable that the second surface portion protrudes toward the processing position as it goes to the side opposite to the ejection port side.
Accordingly, a diffuser can be formed between the second surface portion and the object to be processed, and leakage and diffusion of the processing gas can be prevented or suppressed more reliably by the diffuser effect.

It is preferable that an inert jet port for jetting an inert gas toward the processing position is provided on the side of the nozzle portion opposite to the jet port side from the suction port. As a result, a gas curtain made of an inert gas can be formed, and the gas curtain can more reliably prevent the processing gas from leaking to the outside.
It is preferable that a tip portion of the inert jet port is inclined with respect to the facing direction so as to go to the suction port. Thus, the external atmospheric gas can be reliably drawn in by the ejector effect when the inert gas is ejected, and the leakage and diffusion of the processing gas can be prevented or suppressed more reliably.
It is preferable that a tip portion of the inert jet port is opened on a side opposite to the suction port side from the second surface portion in a surface facing the processing position of the nozzle portion. Thereby, a throat is formed between the surface portion (throat surface) between the inert jet port and the second surface portion on the surface facing the processing position of the nozzle portion and the processing object. It is possible to reduce the static pressure of the gas passing through the throat, further facilitating the drawing of the external atmospheric gas, and more reliably preventing or suppressing the leakage and diffusion of the processing gas.

It is preferable that another suction part is provided so as to face the nozzle part across the processing position. Thereby, the processing gas which has flowed to the back side of the processing position can be sucked and discharged by the suction portion.
It is preferable that the object to be processed is moved by the moving means so as to pass between the nozzle part and the suction part. Thereby, a to-be-processed object can be processed continuously.

It is preferable to further include a processing housing in which the processing position is arranged and at least a portion on the processing position side of the nozzle portion faces. Thereby, the processing gas can be confined to some extent in the processing housing, and the diffusion of the processing gas can be suppressed.
It is preferable that the moving means includes a drive unit disposed outside the processing housing and a transmission unit that directly or indirectly transmits power of the drive unit to the object to be processed. Thereby, corrosion of the drive part can be prevented.

It is preferable to further include an outer peripheral housing that surrounds the processing housing, and an exhaust section that sucks and exhausts between the outer peripheral housing and the processing housing.
As a result, even if the processing gas leaks from the processing housing, it can remain in the outer peripheral housing so as not to leak to the outside, and can be sucked and discharged by the exhaust section.

  According to the present invention, the processing gas can be prevented or suppressed from leaking and diffusing out of the system.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 shows a surface treatment apparatus 1 used in an island etching process in a liquid crystal panel production line. The workpiece W is a non-alkali glass substrate for a liquid crystal panel. As shown in FIG. 2, the glass substrate W has a quadrangular shape. The dimension of the glass substrate W in the longitudinal direction (left-right direction in FIGS. 1 and 2) is, for example, 1300 mm, and the dimension in the lateral direction (vertical direction in FIG. 2) is, for example, 1100 mm. On the surface (upper surface) of the glass substrate W, an amorphous silicon layer (not shown) is formed by CVD. This amorphous silicon layer is etched by a surface treatment apparatus.

  As shown in FIG. 1, the surface treatment apparatus 1 includes a double housing 10 and moving means 20. The double housing 10 includes a processing housing 11 that defines a processing chamber 11 a therein, and an outer peripheral housing 12 that surrounds the processing housing 11.

Openings 11 b are provided in the left and right walls of the processing housing 11, respectively. The glass substrate W can be carried in and out through the opening 11b.
The distance from the upper edge of the opening 11b to the upper surface of the glass substrate W when the glass substrate W passes through the opening 11b is set to, for example, about 5 mm. Moreover, the distance from the lower surface of the ceiling part of the process housing 11 to the upper surface of the glass substrate W is about 20 mm, for example.
The distance between the left wall of the processing housing 11 and the left end surface of the nozzle head 30 described later, and the distance between the right wall of the processing housing 11 and the right end surface of the nozzle head 30 described below are each 300 mm, for example. Yes.

  Openings 12 a are respectively provided in the left and right walls of the outer peripheral housing 12. The opening 12 a is located at the same height as the opening 11 b of the processing housing 11. The glass substrate W can be carried in and out through the opening 12a. An exhaust duct 13 (exhaust part) is provided on one side of the outer peripheral housing 12. The exhaust duct 13 can suck and exhaust between the outer peripheral housing 12 and the processing housing 11. A fan filter unit 14 is provided on the ceiling of the outer peripheral housing 12.

  As shown in FIG.1 and FIG.2, the moving means 20 is comprised by the floating air stage. The floating air stage 20 is disposed on each of the left and right outer sides of the outer peripheral housing 12 and the inner side of the outer peripheral housing 12. For example, the floating air stage 20 on the left side of the outer housing 12 is for carrying in the workpiece W, and the floating air stage 20 on the right side of the outer housing 12 is for carrying out the workpiece W. These floating air stages 20 are positioned at heights that match the openings 12 a and 11 b of the double housing 10. The floating air stage 20 inside the outer peripheral housing 12 passes through the processing housing 11 to the left and right through the openings 11 b on both the left and right sides of the processing housing 11.

As shown in FIG. 2, the floating air stage 20 is provided with a plurality (for example, five) of air ejection portions 21. These air ejection portions 21 extend in a straight line from side to side and are arranged at intervals in the front and rear directions.
The width of the air ejection part 21 is 120 mm, for example, and the pitch in the front-rear direction of the air ejection part 21 is 295 mm, for example.

As shown in FIG. 1, a floating air supply port 22 is provided at the bottom of the floating air stage 20. An air supply source 2 outside the outer peripheral housing 12 is connected to a floating air supply port 22 via a floating air supply path 2a.
The air supply source 2 pumps pressurized clean dry air (CDA) to the floating air supply path 2a. This clean dry air is introduced from the floating air supply port 22 into an air passage (not shown) in the floating air stage 20 and is ejected upward from a number of small holes 21a (FIG. 2) on the upper surface of the air ejection portion 21. It is like that. The glass substrate W is levitated by the blown air. The air ejection part 21 only needs to be able to eject air upward. Instead of the large number of small holes 21a, the air ejection part 21 is made of a porous member (for example, porous alumina, porous carbon, porous aluminum, etc.). It may be configured.

Between the rows of adjacent air ejection portions 21, a net (not shown) made of Teflon (registered trademark) is stretched at a position lower than the upper surface of the air ejection portion 21, and the propulsion roller 23 is disposed from the upper surface of the air ejection portion 21. It arrange | positions so that it may protrude slightly. The propulsion rollers 23 are arranged on the left and right at a pitch (for example, 1000 mm pitch) slightly shorter than the longitudinal dimension of the glass substrate W. By the rotation of the propulsion roller 23, the glass substrate W can be transported in one direction (for example, from left to right).
A virtual horizontal plane P <b> 1 on which the glass substrate W is transported in the processing housing 11 constitutes a “processing position”.

  At the bottom of the processing housing 11, a suction duct 15 (suction part) is arranged with the opening facing upward, and the opening edge is in contact with the floating air stage 20. The suction duct 15 is connected to a suction exhaust unit (not shown), and sucks and exhausts gas above the floating air stage 20 via a net between the air ejection portions 21 of the floating air stage 20.

  A nozzle head 30 (nozzle part) is installed on the ceiling of the processing housing 11. The nozzle head 30 has an ejection head portion 30A and suction head portions 30B and 30B provided on the left and right sides of the ejection head portion 30A. The head portions 30A and 30B may be configured as separate members, or may be configured as an integral member. Lower portions (portions on the processing position P1 side) of the head portions 30A and 30B protrude below the ceiling portion of the processing housing 11 and face the processing chamber 11a. A floating air stage 20 is disposed below the nozzle head 30, and the glass substrate W is conveyed below the nozzle head 30. The distance (work distance) between the nozzle head 30 and the glass substrate W passing therebelow is set to be about 2 mm, for example.

  The nozzle head 30 faces the suction duct 15 with the floating air stage 20 in the processing housing 11 interposed therebetween. At least the ejection head portion 30 </ b> A of the nozzle head 30 is accommodated in the opening of the suction duct 15 in plan view.

  A plurality (for example, six, only three are shown in FIG. 2) of the ejection heads 31 are formed in the ejection head portion 30A. The spout 31 is formed in a slit shape extending in the front-rear direction, and is arranged with a space left and right. The width dimension of the jet port 31 in the left-right direction is, for example, 0.5 mm. As shown in FIG. 3, the lower end portion of each ejection port 31 reaches the bottom surface 33 (surface facing the workpiece W) of the nozzle head 30 and is opened.

  As shown in FIG. 1, a processing gas supply source 3 is disposed outside the outer peripheral housing 12. A processing gas supply path 3 a extends from the processing gas supply source 3 and is connected to each ejection port 31. The processing gas supply source 3 generates a processing gas containing a reaction component according to the processing purpose and sends it to the nozzle head 30 via the processing gas supply path 3a. Although not shown in the figure, a rectifying unit that equalizes the processing gas from the processing gas supply path 3a in the longitudinal direction of the nozzle head 30 (the direction orthogonal to the plane of FIG. 1) is provided on the upper side of the nozzle head 30. The processing gas is introduced uniformly in the longitudinal direction of the ejection port 31.

As the processing gas, for example, in etching of amorphous silicon, a gas containing an oxygen-based reaction component such as ozone and a fluorine-based reaction component such as hydrofluoric acid vapor is used. Ozone can be generated by an ozonizer using oxygen (O ₂ ). The hydrofluoric acid vapor can be generated by adding water (H ₂ O) to a fluorine-containing material such as CF ₄ and turning it into plasma with a plasma generator. Instead of the ozonizer, oxygen-based reaction components such as ozone and oxygen radicals may be generated from an oxygen source by a plasma generation apparatus. You may decide to produce | generate a hydrofluoric acid vapor | steam and an oxygen-type reaction component with one plasma production | generation apparatus. The plasma generation apparatus has at least a pair of electrodes, generates plasma between these electrodes, and converts the raw material gas into plasma to generate reaction components. The plasma is preferably generated near atmospheric pressure. Here, the near atmospheric pressure refers to the range of ^{1.013 × 10 4 ~50.663 × 10 4} Pa, considering the convenience of easier and device configuration of the pressure adjustment, 1.333 × 10 ⁴ ~ 10.664 × 10 ⁴ Pa is preferable, and 9.331 × 10 ^{4 to} 10.9797 × 10 ⁴ Pa is more preferable.

  As shown in FIG. 2, suction ports 34 are formed in the left and right suction head portions 30B. The suction port 34 has a slit shape extending in the front-rear direction. The width dimension of the suction port 34 in the left-right direction is larger than that of the ejection port 31 and is 2 mm, for example.

As shown in FIG. 1, the suction port 34 continues to the suction path 4a. This suction path 4 a is drawn out of the outer peripheral housing 12 and connected to the suction exhaust means 4. The suction exhaust means 4 includes a flow control valve, a suction pump, a detoxification facility, and the like.
Note that the suction exhaust part connected to the suction path 4a, the suction exhaust part connected to the suction duct 15, and the suction exhaust part connected to the exhaust duct 13 may be shared.

The suction port 34 reaches the bottom surface 33 of the nozzle head 30 and is opened.
As best shown in FIG. 3, a portion of the bottom surface 33 of the nozzle head 30 inside the suction port 34 is a flat surface 33a (first surface portion). While the jet port 31 is opened on the flat surface 33a, a step is formed just at the suction port 34, and a surface 33b (second surface portion) on the left and right outside of the suction port 34 is retracted upward. Therefore, the outer edge 34b of the suction port 34 (the edge opposite to the ejection port 31) is retracted above the inner edge 34a (the edge on the ejection port 31 side) (the opposite side in the direction facing the workpiece W). It is out.
The height h of the step between the first surface portion 33a and the second surface portion 33b is preferably about h = 5 to 30 mm, for example.

A method for surface-treating the glass substrate W by the surface treatment apparatus 1 having the above configuration will be described.
The glass substrate W to be processed is levitated on the levitating air stage 20 and conveyed in one direction (for example, from left to right). The glass substrate W passes through the opening 12 a on the left wall of the outer housing 12 and enters the outer housing 12, and further passes through the opening 11 b on the left wall of the processing housing 11 and enters the processing housing 11. Then, it is introduced below the nozzle head 30. A processing space 1 a is defined between the bottom surface 33 of the nozzle head 30 and the glass substrate W.

  At the same time, the processing gas of the processing gas supply source 3 is introduced into the nozzle head 30 through the processing gas supply path 3a, is made uniform in the front-rear direction by a rectifying unit (not shown), and is jetted downward from the jet port 31. . This processing gas contacts the amorphous silicon layer on the surface of the glass substrate W while flowing in the processing space 1a to the left and right outside. Thereby, the reaction between ozone and hydrofluoric acid vapor (reaction component) in the processing gas and amorphous silicon occurs, and the amorphous silicon layer is etched (surface treatment).

In parallel with the ejection of the processing gas, the suction / exhaust means 4 is driven. The suction flow rate of the suction / exhaust means 4 is made sufficiently larger than the flow rate of the processing gas. Thereby, as shown in FIG. 3, the processed processing gas F1 that has reached the processing space 1a directly below the suction port 34 is sucked from the suction port 34 and discharged through the suction path 4a.
Further, the atmospheric gas F 2 outside the nozzle head 30 is sucked into the suction port 34. Here, in the bottom surface 33 of the nozzle head 30, the second surface portion 33 b outside the suction port 34 is retracted upward from the first surface portion 33 a inside the suction port 34, and the outer edge 34 b of the suction port 34 is from the inner edge. Since it is retracted upward, the flow rate of the atmospheric gas F2 entering the space between the second surface portion 33b and the glass substrate W can be increased, and the treated gas F1 can be taken into the atmospheric gas flow F2. Thus, the treated gas F1 can be reliably sucked into the suction port 34 together with the atmospheric gas F2 and discharged. Furthermore, the gas adhering and staying on the surface of the glass substrate W can be peeled off and sucked and discharged together with the atmospheric gas.
In this way, it is possible to prevent or suppress the processing gas and the attached gas from leaking out of the processing housing 11 from the opening 12a. Even if it leaks from the opening 12 a, it can be stopped between the outer peripheral housing 12 and the processing housing 11 and can be exhausted by the exhaust duct 13 therefrom.

The processed glass substrate W passes through the opening 11 b on the right wall of the processing housing 11 and further passes through the opening 12 a on the right wall of the outer peripheral housing 12 and is carried out.
A plurality of glass substrates W are arranged in a line at intervals, and are continuously introduced into the processing chamber 11 a by the floating air stage 20. When the glass substrate W is not positioned below the nozzle head 30, the unprocessed processing gas F <b> 1 flows downward through the net of the floating air stage 20. This processing gas is sucked into the suction duct 15 and discharged.

  As described above, according to the surface treatment apparatus 1, even if the openings 12a and 11b are always opened, it is possible to reliably prevent the processing gas from leaking to the outside world, and the plurality of glass substrates W are always opened. It is possible to perform continuous processing while continuously transporting through the openings 12a and 11b, thus enabling in-line processing.

Next, another embodiment of the present invention will be described. In the following embodiments, the same reference numerals are given to the drawings and the description thereof is omitted for the same configurations as those of the above-described embodiments.
FIG. 4 shows a second embodiment of the present invention. In this embodiment, as in the first embodiment, the outer edges 34b of the left and right suction ports 34 of the nozzle head 30 (shown only on the left side in the figure) are retracted upward from the inner edges, while the outer edges of the suction ports 34 are A bottom surface 33c (second surface portion) extending outward from left and right from 34b is a slope that protrudes downward as it moves away from the suction port 34 (to the processing position P1 as it goes away from the jet port 31 side). Projecting towards). The second surface portion 33c forms a diffuser portion in cooperation with the glass substrate W. The outer edge 33d located at the bottom of the second surface portion 33c is at the same height as the first surface portion 33a inside the suction port 34, but may be located below the first surface portion 33a. It may be located above the first surface portion 33a.
The inclination angle θ of the second surface portion 33c forming the inclined surface is preferably about θ = 3 to 30 °, for example.

  According to the second embodiment, since the gap between the outer edge of the second surface portion 33c and the glass substrate W is narrow, the processed processing gas F1 from the processing space 1a is less likely to leak to the outside. Can do. In addition, after the atmospheric gas F2 outside the nozzle head 30 enters the space between the second surface portion 33c and the glass substrate W due to the diffuser effect between the second surface portion 33c and the glass substrate W, Inflate. Thus, the processed gas F1 from the processing space 1a is reliably taken in and mixed in the atmospheric gas flow F2, and is reliably sucked into the suction port 34 together with the atmospheric gas F2. Therefore, it is possible to reliably prevent the processing gas-completed gas F1 from leaking to the outside.

  FIG. 5 shows a third embodiment of the present invention. The nozzle head 30 of this embodiment is provided with an inactive jet 35 on the outer side of the left and right suction ports 34 (only the left side is shown in the figure). The inert nozzle 35 extends straight downward and reaches the bottom surface 33 of the nozzle head 30 and is opened. The upstream end of the inert jet 35 is connected to the inert gas supply source 5 through the inert supply path 5a. The inert gas only needs to have no reactivity with the workpiece W, and for example, nitrogen, air, argon, helium, or the like is used.

  According to the third embodiment, the inert gas curtain F3 can be formed outside the suction port 34, and leakage of the treated gas F1 to the outside can be more reliably prevented. Further, the inert gas does not cause a reaction such as corrosion even if it contacts each component of the surface treatment apparatus 1, and there is no problem even if it leaks to the outside. The inert gas F3 is sucked into the suction port 34 together with the processed gas F1 and discharged. Furthermore, the gas adhering to and staying on the surface of the glass substrate W can be peeled off and sucked and discharged together with the inert gas from the suction port 34, and the adhered gas is carried out together with the glass substrate W. Can be prevented.

  FIG. 6 shows a fourth embodiment of the present invention. In this embodiment, the lower side portion (front end portion) of the inert jet port 35 is inclined so as to approach the suction port 34 toward the lowermost opening, thereby forming the ejector path 35a. A horizontal throat surface 33e is formed between the tip opening of the ejector passage 35a on the bottom surface of the nozzle head 30 and the second surface portion 33c (diffuser portion). The throat surface 33e forms a throat portion in cooperation with the glass substrate W.

  According to the fourth embodiment, the inert gas F3 is ejected from the ejector passage 35a toward the suction port 34, and the external atmospheric gas F2 is ejected from the nozzle by the ejector effect of the inert gas ejection flow F3. It can be reliably pulled between the head 30 and the glass substrate W. The atmospheric gas draw-in flow F2 can reliably prevent the treated gas F1 from leaking to the outside. Further, the flow rate of the inert gas may be small, and the running cost can be reduced.

  The inert gas F3 and the atmospheric gas F2 flow into the throat portion while being mixed with each other, increase the flow velocity and decrease the static pressure, and then flow into the diffuser portion and decelerate. As a result, the flow rate of the atmospheric gas F2 can be reliably increased, and the leakage of the treated gas F1 can be prevented more reliably.

  FIG. 7 shows a fifth embodiment of the present invention. In this embodiment, a roller conveyor 40 is used as the moving means of the glass substrate W. The roller conveyor 40 includes a driving unit 41 such as a motor, and a transmission unit 43 that connects the driving unit 41 and the conveyor main body 42. The transmission unit 43 includes a pulley, an endless belt, a chain, a gear train, and the like. The conveyor main body 42 has roller shafts (not shown in detail) arranged on the left and right, and rollers 44 provided on each roller shaft. The power of the drive unit 41 is transmitted to the roller shaft by the transmission unit 43, and the glass substrate W is moved (the power of the drive unit 41 is indirectly transmitted to the workpiece W) by rotating the roller 44. It has become.

The drive unit 41 for the conveyor main body 42 in the processing chamber 11a is disposed outside the processing chamber 11a. Thereby, even if the processing gas or the by-product resulting from the reaction contains a corrosive component, the corrosive component can be prevented from coming into contact with the drive unit 41. Therefore, corrosion of the drive unit 41 can be prevented and the life can be extended.
The drive unit 41 may be disposed between the outer peripheral housing 12 and the processing housing 11 or may be disposed outside the outer peripheral housing 12.

The present invention is not limited to the above-described embodiments, and various modifications can be made within the scope obvious to those skilled in the art.
For example, the numerical values such as dimensions described in the above embodiment are merely examples, and are not limited to these, and can be changed as appropriate.
The workpiece W is not limited to a glass substrate, and may be a silicon wafer or a resin film, and is not particularly limited as long as it is surface-treated.
The content of the surface treatment is not limited to the etching of the amorphous silicon layer, but may be the etching of other components such as an oxide film and a nitride film, and is not limited to the etching, but for various surface treatments such as film formation, surface modification, and cleaning. Applicable. Examples of film formation include CVD of an amorphous silicon layer. Examples of the surface modification include a treatment for improving the adhesiveness of a joint portion of a rubber tube, a treatment for improving wettability, and the like.
The processing gas is appropriately selected according to the composition of the workpiece W and the content of the surface treatment. In addition to ozone and hydrofluoric acid vapor in the above embodiment, corrosive and toxic components such as HF, COF ₂ , F ₂ , CO, and NO may be used. According to the present invention, even when the processing gas component is corrosive and toxic, leakage to the outside can be surely prevented, and reliability can be ensured.
There is no particular limitation on the moving means. A plate stage on which the workpiece W is placed in contact may be used instead of the floating stage, and the moving means may move the plate stage. When the workpiece W is a wafer or the like, the workpiece W may be sucked with a suction hand, and the suction hand may be moved with a manipulator (moving means). When the workpiece W is a long resin film, a roll for feeding out the resin film and a roll for winding may be used as the moving means.
While the workpiece W is fixed in position, the nozzle unit 30 may be moved by the moving means, or the workpiece W and the nozzle unit may be moved together. The moving unit may be omitted, and the nozzle unit and the workpiece W may be processed without moving relative to each other.

  The present invention can be used in a manufacturing process of a semiconductor device such as a liquid crystal panel.

1 is a front view of an overall configuration of a surface treatment apparatus according to a first embodiment of the present invention. It is a top view of the said surface treatment apparatus. It is sectional drawing of the nozzle head of the said surface treatment apparatus. It is sectional drawing of the nozzle head which shows 2nd Embodiment of this invention. It is sectional drawing of the nozzle head which shows 3rd Embodiment of this invention. It is sectional drawing of the nozzle head which shows 4th Embodiment of this invention. It is a front view which shows 5th Embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Surface treatment apparatus 1a Processing space 2 Air supply source 2a Floating air supply path 3 Processing gas supply source 3a Processing gas supply path 4 Suction exhaust means 4a Suction path 5 Inert gas supply source 5a Inactive supply path 10 Double housing 11 Processing Housing 11a Processing chamber 11b Opening 12 Outer peripheral housing 12a Opening 13 Exhaust duct (exhaust part)
14 Fan filter unit 15 Suction duct (suction part)
20 Floating air stage (moving means)
21 Air ejection part 21a Small hole 22 Floating air supply port 23 Propulsion roller 30 Nozzle head (nozzle part)
30A Ejection head portion 30B Suction head portion 31 Ejection port 33 Nozzle head bottom surface (surface facing the object to be processed)
34 Suction port 33a First surface portion 33b Second surface portion 33c Second surface portion (diffuser portion)
33d Outer edge 33e Throat surface 34a Edge 34b of suction port side 34b Edge 35 of suction port opposite to jet port side Inactive jet port 35a Ejector path 40 Roller conveyor (moving means)
41 Drive unit 42 Conveyor body 43 Transmission unit F1 Processing gas flow F2 Atmospheric gas flow F3 Inert gas flow P1 Processing position W Glass substrate (processing object)

Claims (7)

An apparatus for performing surface treatment by spraying a processing gas on an object to be processed,
A nozzle portion facing a processing position where a workpiece is to be disposed is provided, and a nozzle port for jetting the processing gas toward the processing position and a suction port for sucking the gas are arranged in the nozzle portion. The surface treatment apparatus is characterized in that an edge of the suction port opposite to the ejection port side is recessed from the edge of the ejection port side to the opposite side in the facing direction.   The surface of the nozzle portion facing the processing position is a first surface portion between the jet port and the suction port, and a second surface opposite to the first surface portion across the suction port. The surface treatment apparatus according to claim 1, wherein the second surface portion is retracted to the opposite side of the facing direction from the first surface portion.   The surface of the nozzle portion that faces the processing position has a second surface portion that is continuous with the opposite edge of the suction port, and the second surface portion is directed to the opposite side to the ejection port side. The surface treatment apparatus according to claim 1, wherein the surface treatment apparatus protrudes toward the position to be treated.   An inert jet port for jetting an inert gas is provided on the side opposite to the jet port side from the suction port of the nozzle portion, and a tip portion of the inert jet port is directed to the suction port. 4. The device according to claim 3, wherein the first surface portion is inclined to the opposite side of the suction port side with respect to the second surface portion of the surface facing the processing position. Surface treatment equipment. A suction part that is arranged to face the nozzle part across the processing position and sucks a gas;
Moving means for moving the object to be passed between the nozzle part and the suction part;
The surface treatment apparatus according to claim 1, comprising: A processing housing in which the processing position is disposed and at least a portion of the nozzle portion facing the processing position;
The said moving means contains the drive part arrange | positioned outside the said process housing, and the transmission part which transmits the motive power of the said drive part to the said to-be-processed object directly or indirectly. The surface treatment apparatus according to any one of 5.   The surface treatment apparatus according to claim 6, further comprising an outer peripheral housing that surrounds the processing housing, and an exhaust unit that sucks and exhausts between the outer peripheral housing and the processing housing.

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