JP2001104893A - Brush and device and method for treating substrate - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a brush, a substrate washing device and a substrate washing method for surely washing a substrate. SOLUTION: A brush implantation part 308 is formed on a brush part 120 into a cruciform shape to pass through the center of the part 120 and a purified water supplying nozzle 127 is disposed in the central part of the part 120.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a brush for cleaning a substrate, a substrate processing apparatus and a substrate processing method, and in particular,
The present invention relates to a brush for processing a substrate taken out of a substrate storage, a substrate processing apparatus, and a substrate processing method.

[0002]

2. Description of the Related Art As a substrate processing apparatus for performing substrate processing such as cleaning processing on a semiconductor substrate and a substrate such as a glass substrate for a liquid crystal or a photomask, there is an apparatus disclosed in Japanese Patent Application Laid-Open No. 4-162426. . This apparatus includes a loader carrier for mounting a cassette containing a large number of wafers on the top and bottom, a loader transfer robot for taking out a substrate from a substrate storage section on the loader carrier, and a rotary brush mechanism for simultaneously cleaning both front and back surfaces of the substrate. And a rotary drying mechanism for rotating and drying the washed wafer.

In this substrate processing apparatus, a transfer robot for a loader takes out substrates one by one from a substrate storage section mounted on a loader carrier. At this time, the substrate storage unit and the substrate are exposed to clean air. The substrate taken out by the loader transfer robot is supported at both ends by a rotating brush mechanism, and the front and back surfaces are simultaneously cleaned. The washed wafer is rotated and dried by a rotary drying mechanism while both end faces are supported. The dried wafer is placed on the unloader carrier.

[0004]

In the above-described conventional configuration, particles may remain on the substrate. An object of the present invention is to reliably clean a substrate.

[0005]

Means for Solving the Problems According to a first aspect of the present invention for achieving the above object, the present invention can be arranged such that a rotation center axis intersects a main surface of a substrate, and a substrate is supplied while supplying a cleaning liquid to the substrate. And a brush for cleaning the brush, wherein the brush is formed in a cross shape passing through the center. According to the first aspect of the present invention, it is possible to prevent particles removed from the substrate from adhering to the brush and causing clogging.

According to a second aspect of the present invention, there is provided a brush for cleaning a substrate while supplying a cleaning liquid to the substrate, the brush being capable of being arranged so that a rotation center axis intersects the main surface of the substrate. It is a brush which has many circular planting parts arranged. According to the second aspect of the invention, it is possible to prevent particles removed from the substrate from adhering to the brush and causing clogging.

According to a third aspect of the present invention, there is provided a brush according to the first or second aspect, wherein a pure water supply nozzle for discharging the pure water as the cleaning liquid to the substrate is provided at a central portion. Is characterized by being arranged in a. According to the third aspect of the invention, it is possible to further prevent the particles removed from the substrate from adhering to the brush and causing clogging.

According to a fourth aspect of the present invention, there is provided a substrate holding means for holding a substrate, and a cleaning means for cleaning the substrate held by the substrate holding means. And a rotating means for relatively rotating the brush and the substrate held by the substrate holding means. According to the fourth aspect of the present invention, it is possible to provide a substrate processing apparatus capable of preventing particles removed from a substrate from adhering to a brush and causing clogging, and reliably cleaning the substrate.

According to a fifth aspect of the present invention, there is provided a substrate processing apparatus according to the fourth aspect, wherein the substrate is a disk-shaped substrate, and the substrate holding means is provided on a peripheral edge of the substrate. A wafer edge contact portion capable of contacting, an urging means for urging the wafer edge contact portion in the direction of the substrate, and a wafer holding / releasing mechanism for moving the wafer edge contact portion and the urging means back and forth with respect to the substrate And a swing means for relatively swinging the brush and the substrate held by the substrate holding means. According to the fifth aspect of the present invention, since the wafer holding / releasing mechanism can move the wafer edge contact portion and the urging means back and forth with respect to the substrate, the wafer holding / releasing mechanism releases or holds the substrate holding force by the wafer edge contact portion. If it decreases, the frictional force at the contact surface between the brush and the substrate exceeds the frictional force between the wafer edge contact portion and the substrate, and the substrate rotates with the rotation of the brush. Therefore, it is possible to prevent the contact position between the wafer edge contact portion and the substrate from being unprocessed. Furthermore,
Since the brush is formed in a cross shape passing through its center, or because a large number of circular implants are arranged,
The rotation of the substrate during the cleaning process can be adjusted by changing the contact area between the brush and the substrate.

Here, the wafer holding / releasing mechanism can be configured to release or reduce the substrate holding force by retreating the wafer edge contact portion and the urging means with respect to the substrate at regular intervals. In this case, the substrate rotates with the rotation of the brush within the time when the substrate holding force is released or reduced, and the above-described operation becomes remarkable. Further, the brush can be configured to be able to contact the lower surface of the substrate held by the substrate holding means. In this case, it is possible to prevent particles on the back surface and the peripheral edge of the substrate from remaining. Further, the wafer edge contact portion can be constituted by a plurality of rollers that contact the peripheral edge of the substrate. In this case, the substrate rotates smoothly with the rotation of the brush, and the above-described operation is more remarkable. Further, it is possible to provide a roller support member opposed to the horizontal direction and to rotatably support the roller by the roller support member. Also in this case, the above-described operation is more remarkable. Further, when the roller supporting member is configured to be urged in the direction of the substrate by the urging means, the substrate can always be gripped with an appropriate pressure, and the moving stroke of the roller supporting member when the substrate is gripped. Need not be performed with high accuracy. Here, the roller provided as the wafer edge contact portion preferably has a configuration having an annular groove that contacts the peripheral edge of the substrate. In this case, the peripheral edge of the substrate can be reliably held by using the annular groove. The wafer edge contact portion has a contact surface that contacts the peripheral edge of the substrate, and a convex portion that projects toward the center of the substrate above the contact surface, and the entire lower surface of the substrate is exposed downward. As described above, the configuration may be such that the peripheral edge of the substrate is gripped. In this case, it is easy to clean the lower surface of the substrate from below, and it is possible to prevent particles on the rear surface and the peripheral edge of the substrate from remaining.

According to a sixth aspect of the present invention to achieve the above object, a substrate held by a substrate holding means and the brush according to any one of the first to third aspects are rotated relative to each other while rotating the substrate. A substrate processing method characterized by cleaning. According to the sixth aspect of the present invention, it is possible to provide a substrate processing method capable of preventing particles removed from the substrate from adhering to the brush and causing clogging, and reliably cleaning the substrate.

[0012]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A substrate processing apparatus as one embodiment of the present invention shown in FIGS.
A cleaning and drying process is performed on (an example of a substrate).

In these figures, the substrate processing apparatus includes an underwater loader 1 for immersing a large number of wafers W stored in a cassette C (an example of a substrate storage section) in pure water, and a wafer W taken out of the cassette C. A back surface cleaning device 2 for brush cleaning the back surface (lower surface) of the wafer W, a front surface cleaning device 3 for brush cleaning the front surface (upper surface) of the wafer W, a rinsing and drying device 4 for rinsing and drying the wafer W, An unloader 5 for accommodating and discharging the wafer W in another cassette C is arranged in this order.

Between each of the loaders 1, 5 and the devices 2 to 4,
A transfer device 6 having an articulated robot 7 is arranged. The transfer device 6 and each of the loaders 1 and 5 and the devices 2 to 4 can be shut off by a shutter (not shown). Also,
Pure water is supplied to the loader 1 and the devices 2 to 4 and 6 from the pure water supply device 8 via the control valve 9. The drainage from the loader 1 and the devices 2 to 4 and 6 is collected by a drainage collection device 10.

As shown in FIGS. 3 to 6, the underwater loader 1 stores a water tank 11 for storing pure water therein and immersing the cassette C in the pure water, and moves the cassette C up and down in the water tank 11. And a cassette elevating device 12 for performing the operation.
The elevating device 12 moves the cassette C at least between the position where the uppermost wafer W stored in the cassette C is completely immersed in pure water and the lowermost wafer W stored in the cassette C. Move up and down to a position that floats from the water. The cassette C is hollow, and an opening 13 for taking in and out of the accommodated wafer W is provided at the right front side in FIG.
Are formed.

The water tank 11 is made of a synthetic resin, and has a side surface opposite to the side surface on which the opening 13 of the cassette C is arranged (FIG. 4).
On the left side), a weir 14 whose vertical position can be adjusted is provided. The height of the liquid level in the water tank 11 is determined by the weir 14. Further, a pure water supply port 15 is formed in a portion of the bottom surface of the water tank 11 near the opening 13 of the cassette C,
Pure water is supplied from the supply port 15 to the water tank 11. The supplied pure water overflows from the weir 14 and is discharged. Therefore, during the supply of pure water, a water flow is formed from the opening 13 of the cassette C to the back side at least near the liquid level in the water tank 11. A liquid level gauge 17 using a capacitance sensor 18 is disposed on one side surface of the water tank 11.

The cassette lifting device 12 includes a lifting frame 19.
It has. The elevating frame 19 is vertically movably supported by two guide shafts 20 arranged vertically. A ball nut 21 is arranged at the center of the lifting frame 19. The ball nut 21 is screwed into a ball screw 22 extending vertically. The ball screw 22 is rotatably supported by a guide frame 23 that supports the guide shaft 20. Ball screw 22
Is a toothed pulley 24 and a toothed belt 2 arranged at the lower end.
5, and is rotated by a motor 26. As a result, the lifting frame 19 is driven up and down.

At both ends of the lifting frame 19, a pair of lifting members 27 made of a stainless steel thin plate member and a vertical member 31 connected thereto are arranged. Each vertical member 3
At the lower end of 1 is a cassette table 3 made of a synthetic resin flat member.
2 are installed. On the cassette table 32, positioning members 33 for positioning the four corners of the cassette C are attached.

The upper end of each elevating member 27 is connected to the connecting member 3.
0, and a lifting prevention member 44a for preventing the cassette C from floating when the cassette C is immersed in the water tank 11 is provided at the center of the connecting member 30.
Are arranged. This lifting prevention member 44a is
It comprises a bearing 45a fixed to the connecting member 30 and a stopper 47a rotatably connected to the bearing 45a via a shaft 46a.

In the transfer device 6 shown in FIG. 2, above the three articulated robots 7 on the upstream side in the transfer direction, a nozzle 34 for jetting pure water is provided as shown in FIGS. The nozzle 34 is for spraying pure water onto the wafer W sucked and held by the articulated robot 7 to prevent drying of the wafer W and to suppress contact between the wafer W and air. The nozzle 34 sprays pure water in a cone shape slightly larger in diameter than the wafer W.

The articulated robot 7 includes a vertical column 41 attached to a frame 40 of the substrate processing apparatus, and a base 42 supported on the vertical column 41 so as to be rotatable in the horizontal direction.
And a transfer arm 43 supported at the tip of the base 42 so as to be rotatable in the horizontal direction. The articulated robot 7 can take a standby posture shown by a solid line in FIG. 7, an unloading posture shown by a two-dot chain line, and a loading posture shown by a dotted line. The standby posture is a posture in which the transfer arm 43 is folded on the base 42. The unloading posture is such that the base 42 rotates 90 ° counterclockwise in FIG.
3 is a posture that is arranged so as to extend on a straight line. The carry-in posture is a posture that is line-symmetric with the carry-out posture with respect to the standby posture.

The vertical column 41 is made of stainless steel and has a substantially cylindrical shape as shown in FIG. A rotating shaft 44 rotatably supported by stainless steel bearings 45 and 46 is disposed inside the vertical column 41. A rotating lever 49 made of synthetic resin is fixed to an upper end of the rotating shaft 44, and a rotation driving mechanism including a motor (not shown) is connected to a lower end side. The rotating lever 49 has a fan shape as shown in FIG. 10, and the outer edge thereof is fixed to the base 42. Therefore, the base 42 and the rotation shaft 44 rotate integrally.

At the upper end of the vertical column 41, a spur gear 50 made of synthetic resin is fixed. Thus, the spur gear 50 rotates integrally with the vertical column 41. Bearings 47 and 48 made of stainless steel are arranged on the outer periphery of the upper end of the vertical column 41. The bearings 47 and 48 are for rotatably supporting the base 42.

The base 42 is made of aluminum and has an outer surface covered with a tetrafluoroethylene resin. Base 4
Reference numeral 2 denotes an oval shape, and a bearing 4
It has a bearing housing 51 for housing 7, 48. Further, fixed shafts 52 and 53 made of synthetic resin are provided upright at the front end and the intermediate portion of the base 42. An intermediate gear 54 made of synthetic resin meshing with the spur gear 50 is rotatably supported on the fixed shaft 53 at the intermediate portion. The intermediate gear 54 is a two-piece gear that can be adjusted to remove backlash. A pinion 5 made of synthetic resin is attached to the fixed shaft 52 at the tip.
5 is rotatably supported. The pinion 55 has a boss 56 at the top, and the base end of the transfer arm 43 is fixed to the upper end of the boss 56.

The rotation lever 49 and the spur gear 5
0, the intermediate gear 54 and the pinion 55 are covered with a synthetic resin cover 57 screwed around the base 42.

The transfer arm 43 is made of a stainless steel thin plate member. Inside the transfer arm 43 is formed a suction hole 58 which is opened at the upper end of the transfer arm 43 and extends to the fixed shaft 52 therefrom. Similarly, suction holes 59 and 60 are also formed in the shaft centers of the fixed shaft 52 and the fixed shaft 53. The base 42 is also provided with the suction holes 61 so as to connect the suction holes 59 and 60.
Are formed. Further, a suction hole 62 is also formed in the axis of the rotating shaft 44, and the suction hole 62 and the suction hole 60 are formed.
Are connected by an adsorption pipe 63.

As shown in FIG. 11, one end of a negative pressure pipe 64 is connected to the base end of the rotating shaft 44. The suction holes 65 to 62, the suction pipe 63, and the negative pressure pipe 64 form a suction path 65. The other end of the negative pressure pipe 64 is connected to a negative pressure generating section 66.

The negative pressure generating section 66 is of an aspirator type, and generates a negative pressure by high-pressure air from an air source 67 connected to the negative pressure generating section 66. A vacuum gauge 69 with a lower limit contact is connected to the negative pressure generator 66 via a measurement pipe 68. In the vicinity of the vacuum gauge 69 in the measurement pipe 68,
An open pipe 70 open to the atmosphere is connected. An on / off valve 71 of an electromagnetic control type is arranged in the open pipe 70. The open pipe 70 is for removing pure water that has entered the measurement pipe 68 from the adsorption path 65.

A steam / water separator 72 is connected downstream of the negative pressure generator 66. The steam separator 72 is for separating moisture contained in air from air. The downstream side of the steam separator 72 is connected to an exhaust pipe 73 and a drain pipe 74.

Here, when the wet wafer W is sucked by the tip of the transfer arm 43, water enters the suction path 65.
The intruded water flows from the negative pressure generating section 66 to the steam-water separator 72. Then, the air separated by the steam separator 72 is discharged to an exhaust pipe 73, and moisture is discharged to a drain pipe 74. Further, a part of the water also enters the measurement pipe 68. If pure water stays in the measurement pipe 68, the measurement by the vacuum gauge 69 becomes impossible. Therefore, immediately before the measurement by the vacuum gauge 69, the on / off valve 71 is opened, and the measurement pipe 68 is opened to the atmosphere.
The pure water therein is discharged to the negative pressure generating section 66 side.

As shown in FIG. 12, the back surface cleaning device 2
A wafer gripping mechanism 80 that grips and swings the wafer W;
It has a brush cleaning mechanism 81 that contacts the back surface of the wafer W to clean the back surface of the wafer W, and a front surface cleaning nozzle 82 that injects pure water to the front surface of the wafer W.

The wafer gripping mechanism 80 moves the wafer W
It has a pair of grips 83 and 84 that are opposed to each other. Gripping parts 83, 84
Are rollers 201 and 202 arranged at intervals along the outer periphery of the wafer W, and these rollers 201 and 202
And gripping arms 87 and 88 for rotatably supporting. The gripping arms 87 and 88 are provided with cover members 203 and 20.
4 is fixed. The cover members 203 and 204 are supported by sliding brackets 207 and 208 disposed outside. The grip arm 88 and the cover member 204 on one side are constantly urged in the direction of pressing the wafer W by a spring 206 provided between the sliding bracket 208 and the cover member 204. Further, the sliding brackets 207 and 208 are fixed to the piston rods 211 and 212 of the air cylinders 209 and 210, and can be moved toward and away from each other as the air cylinders 209 and 210 are driven. As a result, the gripping arms 87 and 88 can contact and separate from each other.

The back surface cleaning apparatus 2 is shown in FIGS.
As shown in FIG.
The holding arms 87 and 88 including the processing tanks 201 and 202
It is located inside. Openings 302 and 303 are provided on the side of the processing tank 301. Openings 302, 303
Has a cylindrical shape protruding inward of the processing tank 301, and the cover members 203, 204 have openings 302, 303 from inside.
It is arranged to cover. The air cylinder 20
The piston rods 211, 212 and the sliding brackets 207, 208 of 9, 210 are movable through the openings 302, 303.

Further, as shown in FIG. 15, the rollers 201 and 202 are rotatably supported on the distal ends of the gripping arms 87 (88) via a support shaft 213 extending in the vertical direction.
An annular groove 214 is formed on the outer peripheral surface of the roller 201 (202), and the wafer W can be inserted into the annular groove 214.

The air cylinders 209 and 210 are fixed to swing frames 304 and 305, respectively. As shown in FIG. 16 (the swing frame 305 is not shown), the swing frames 304 and 305 are connected to the lower swing frame 95 via connecting members 306 and 307. Bearings 100 and 101 are arranged on the back surface of the lower swing frame 95 at intervals. The ends of swing shafts 102 and 103 having an eccentric cam 104 at the top are rotatably supported by the bearings 100 and 101. When the swing shafts 102 and 103 rotate, the lower swing frame 95 performs an eccentric swing motion in the direction of arrow B by the action of the eccentric cam 104. Thus, the wafer W held by the rollers 201 and 202 swings.

The oscillating shafts 102 and 103 are provided with an eccentric cam 104.
And the lower lifting frame 1 disposed below the swing shafts 102 and 103.
08 so as to be rotatable. Further, it is supported rotatably and vertically movable by an upper fixed frame 107 disposed between the upper lifting frame 106 and the lower lifting frame 108.

A swinging motor 111 fixed to a bracket 110 extending downward from the lower lifting frame 108 is connected to the lower end of the swinging shaft 102 on the left front side in FIG. The driving force of the swing motor 111 is transmitted to the other swing shaft 103 via a pulley 112, a timing belt 113 and a pulley 114 disposed between the lower lifting frame 108 and the motor 111. Therefore, the swing shaft 102 and the swing shaft 103 rotate in the same direction in synchronization with each other.

The upper fixed frame 107 and the lower fixed frame 109 are connected by guide shafts 115 and 116. The guide shafts 115 and 116 are attached to the lower lifting frame 1
08 is supported to be able to move up and down freely. A screw shaft 117 is disposed between the guide shaft 115 and the guide shaft 116. The screw shaft 117 is rotatably supported by the upper fixed frame 107 and the lower fixed frame 109. The screw shaft 117 is screwed into a female screw (not shown) provided on the lower lifting frame 108, and is driven to rotate by a lifting motor 118 fixed to the lower fixing frame 109. The lower drive frame 108 is driven by the rotation of the motor 118.
Is driven up and down. Thus, the wafer W can be moved up and down in the direction of arrow C.

The brush rotating mechanism 81 has a brush section 120 as shown in FIG. The brush unit 120
It is fixed to the upper end of the rotating shaft 121. Rotating shaft 121
Is a cylindrical shaft support 1 that is arranged concentrically with the rotation shaft 121.
22 rotatably supported. Shaft support 122
Is fixed to the device frame 40. Rotary axis 1
The driving force of the motor 124 is transmitted to 21 via a transmission mechanism 123 including a pulley and a timing belt. Thus, the brush unit 120 is driven to rotate in the direction of arrow D with respect to the wafer W.

The brush section 120 has a structure in which a large number of nylon fibers are implanted. At the center of the brush section 120, a pure water supply nozzle 127 communicating with the upper end of the flowing water hole 126 is arranged. When pure water is discharged from the nozzle 127 during cleaning, the discharged pure water flows to the outer peripheral side of the brush unit 120 due to centrifugal force. Thereby, the particles removed by the brush unit 120 can be efficiently removed. Also, during standby, the nozzle 12
When the pure water is released from 7, the discharged pure water flows to the outer peripheral side of the brush part 120 by centrifugal force. This makes it possible to reliably remove particles attached to the brush unit 120,
In addition, drying of the brush unit 120 during standby can be prevented.

The brush portion 120 may have a configuration in which a nylon brush is planted in a circular shape corresponding to the wafer W, or may have a shape as shown in FIGS. In FIG. 18, fibers are planted in a cross shape passing through the center to form a planting portion 308, and the other portions are non-planting portions 3.
09. In FIG. 19, a plurality of radially implanted portions 310 extending from the center to the outer periphery are formed, and the other portions are non-implanted portions 311. In FIG. 20, a large number of circular implanted portions 312 are arranged, and other portions are not implanted portions 31.
It is set to 3. 18 to 20, a pure water supply nozzle 127 is arranged at the center. By using the brush having the shape shown in FIGS.
Particles removed from the brush can be prevented from adhering to the brush fibers and causing clogging. Further, the rotation area of the wafer W during the cleaning process can be adjusted by changing the contact area with the lower surface of the wafer W.

As shown in FIG. 21, the surface cleaning device 3
A wafer elevating / lowering rotating mechanism 130 for gripping and raising / lowering and rotating the wafer W; a brush cleaning mechanism 131 for contacting the surface of the wafer W to clean the surface of the wafer W;
And a pure water jetting mechanism 132 for jetting pure water to the surface of the liquid crystal display.

The wafer elevating and rotating mechanism 130 has a plurality of gripping claws 133 for gripping the side surface of the wafer W. The gripping claw 133 is moved up and down and rotated by the wafer elevating and rotating unit 134.

The brush cleaning mechanism 131 has an arm 135. The arm 135 is configured such that its tip swings from the center of the wafer W toward the outer periphery. At the tip of the arm 135, a downward circular brush 136 is rotatably arranged. In the state where the arm 135 is arranged at the standby position indicated by the two-dot chain line in FIG.
A cleaning nozzle 137 for cleaning the circular brush 136 is disposed at a position facing the cleaning brush 136. The particles attached to the circular brush 136 can be removed by the cleaning nozzle 137. The circular brush 136 may be formed by implanting nylon fibers. In addition, a polyvinyl chloride (PVA) sponge, mohair, or the like may be used.

The pure water injection mechanism 132 has a nozzle support arm 138 that moves up and down and swings. At the tip of the nozzle support arm 138, an ultrasonic nozzle 139 for jetting pure water vibrated by ultrasonic waves is arranged so as to be able to jet pure water obliquely downward toward the center of the wafer W. Note that this injection angle is adjustable.

On the lower surface of the wafer W, a back surface cleaning nozzle 140 for removing particles wrapping around from the front surface to the back surface during cleaning is arranged. Back cleaning nozzle 140
Sprays pure water in two directions on the back surface of the wafer W.

As shown in FIG. 22, the washing / drying device 4
A wafer elevating / rotating mechanism 141 similar to the surface cleaning device 3;
A rinsing nozzle 142 that can be radially protruded and retracted from the surface of the wafer W, and a gas nozzle 143 for injecting nitrogen gas into the center of the wafer W are provided. The wafer elevating / lowering rotating mechanism 141 has a plurality of gripping claws 144 for gripping the side surface of the wafer W. This gripping claw 144 is
Then, the wafer elevating and rotating mechanism 141 injects pure water from the rinsing nozzle 142 while washing the wafer W at a low speed to wash the wafer W, and then rotates the wafer W at a high speed to perform draining and drying.

Further, the washing / drying apparatus 4 is also provided with a back surface cleaning nozzle 145 for removing particles wrapping around from the front surface to the back surface. The reason why the rinsing nozzle 142 can appear and retract is to prevent the wafer W from getting wet by dripping when not in use.

In the substrate processing apparatus configured as described above,
Since pure water is always supplied between the underwater loader 1 and the washing / drying device 4 during transportation and processing, drying of the wafer W can be prevented, and contact of the wafer W with air can be suppressed.

Next, the operation of the above-described substrate processing apparatus will be described.

When a cassette C containing a large number of wafers W is positioned and mounted on the cassette table 32 of the underwater loader 1 by the positioning member 33, the lifting frame 10
Is lowered, and the cassette C is immersed in the water tank 11. At this time, pure water is supplied from the pure water supply port 15. The supplied pure water overflows from the weir 14. As a result, the water tank 1
Near the first liquid level, a water flow is formed from the opening 13 of the cassette C toward the back. Therefore, the lifting frame 19
Is lowered, each wafer W receives the urging force of the water flow, and the wafer W does not slide out of the cassette C.

When the wafer W is supplied to the back surface cleaning device 2, the immersed cassette C is moved to the cassette lifting device 1.
2 to rise. Then, with the wafer W to be carried out positioned slightly above the take-out position, the cassette elevating device 12 stops.

Subsequently, the rotating shaft 44 of the articulated robot 7 is rotated counterclockwise in FIG. 10 by a motor (not shown), and the base 42 is rotated counterclockwise via the rotating lever 49. Then, the spur gear 5 fixed to the base 42
0 rotates together with the base 42 to rotate the pinion 55 via the intermediate gear 54. When the pinion 55 rotates, the transfer arm 58 rotates. Then, when the base 42 rotates 90 ° counterclockwise, the base 42 and the revolving arm 43 assume the unloading posture (the posture indicated by the two-dot chain line in FIG. 7). By slightly lowering the cassette elevating device 12, the transfer arm 43 of the articulated robot 7 is moved.
The wafer W is received above.

Here, the inside of the suction path 65 is set to a negative pressure, and the wafer W is suction-held. Further, the on / off valve 71 is opened instantaneously, and the measurement pipe 68 is opened to the atmosphere. As a result, the water that has entered the measurement pipe 68 and stays there is discharged, and the vacuum gauge 6
9, the negative pressure can be confirmed. Then, it is checked whether or not the lower limit contact of the vacuum gauge 69 is on. When the lower contact is ON, the device is stopped because the negative pressure is not sufficient.

When a normal negative pressure is detected and the wafer W is suctioned normally, the rotating shaft 44 is rotated in the opposite direction (clockwise in FIG. 10), and the base 42 is rotated in the opposite direction. 9
Rotate 0 °. As a result, the transfer arm 43 is
2 becomes the standby posture positioned above. Here, when the wafer W is received and extracted from the underwater loader 1, the wafer W does not slide on the transfer device 6 and the cassette C. Therefore, generation of particles due to wear can be prevented.

The standby posture of the articulated robot 7 is maintained until a transfer request from the back surface cleaning device 2 comes. During this time,
Pure water is sprayed from the nozzle 34. Therefore, the wafer W
Does not dry during transport and during standby, and can prevent oxidation caused by contact with air, adhesion of particles and chemicals, and the like.

When a transport request is issued from the back surface cleaning device 2,
The rotation shaft 44 further rotates clockwise by 90 °. Then, the transfer arm 43 is brought into the carry-in posture extending toward the back surface cleaning device 2, and the tip thereof is disposed at the center position of the back surface cleaning device 2 (Step S <b> 1 in FIG. 23). At this time, on the back surface cleaning device 2 side, the air cylinders 209 and 210 advance, and the rollers 2
The wafer W is gripped by 01 and 202 (FIG. 23, step S2). Further, the articulated robot 7 returns to the standby posture. At this time, the grip arm 88 on one side and the cover member 2
04 is urged by a spring 206 provided between the sliding bracket 208 and the cover member 204 in the direction of pressing the wafer W, and the gripping of the wafer W by the rollers 201 and 202 is ensured by an appropriate pressing force. Done in
Further, the gripping arm 8 by the air cylinders 209 and 210 is used.
As long as the movement stroke of 7,88 is within the allowable range of expansion and contraction of the spring 206, high precision is not required.

Subsequently, the wafer gripping mechanism 80 is
The lower surface of the wafer W is brought into contact with the rotating brush unit 120 by lowering the wafer 8 by the step 8. In this state, the motor 111 is rotationally driven to swing the wafer W such that the peripheral edge of the brush unit 120 is inscribed in the peripheral edge of the wafer W (step S3 in FIG. 23). At this time, the wafer W is
By supplying pure water also to the surface of the wafer W, drying of the surface of the wafer W and adhesion of particles are prevented.

Here, the wafer W is applied to the rollers 201 and 20
2 so as to be rotatable. However,
The wafer gripping mechanism 80 performs an eccentric oscillating motion with the rotation of the oscillating shafts 102 and 103. For this reason, the roller 2
01 and 202 and the brush unit 1
The rotation center of 20 is relatively eccentrically oscillated, and the wafer W does not rotate integrally with the brush unit 120.

In step S3, the rollers 201, 20
2 holds the wafer W by the air cylinders 209 and 2
10 and the urging force of the spring 206.
Air cylinder 2 during back surface cleaning of wafer W in step S3
Assuming that the piston rod 211 of 09 is at a fixed position, the force by which the rollers 201 and 202 hold the wafer W is given by the air cylinder 210 and the spring 206. As shown in FIGS. 24 and 25, the air cylinder 2
10 is controlled by a solenoid valve 215. When the M chamber of the air cylinder 210 is evacuated and the N chamber is supplied with air,
As shown in FIG. 24, the piston rod 212 of the air cylinder 210 is fully extended, and the spring 206
Of the roller 202 becomes the maximum. When both the M chamber and the N chamber of the air cylinder 210 are exhausted, as shown in FIG.
6 stops at a position where it is balanced with the biasing force. When the solenoid valve 215 is controlled to control the piston rod 212 of the air cylinder 210 to the position shown in FIG.
The holding force of the wafer W by the wafer unit 202 is maximized, and the wafer W rotates with the rotation of the brush unit 120 even when the tip of the fiber implanted in the brush unit 120 is in contact with the lower surface of the wafer W. Is difficult. In this state, brush part 1
20 is rotated to clean the back surface of the wafer W.

When the piston rod 212 of the air cylinder 210 is controlled to the position shown in FIG.
The frictional force at the contact position between the roller W and the rollers 201 and 202 is minimized, so that the wafer W
It rotates in the same direction with the rotation of. As a result, the portion of the wafer W that is in contact with the rollers 201 and 202 is exposed. Here, the piston rod 212 of the air cylinder 210 is controlled again to the position shown in FIG. As a result, the wafer W is transferred to the roller 2 with the portion of the wafer W in contact with the rollers 201 and 202 being exposed.
01 and 202, and cleaning by the brush unit 120 is performed.

The control of the air cylinder 210 can be performed according to a timing chart as shown in FIG. 26, for example. Here, the position shown in FIG.
The position shown in FIG. 5 is performed only for the time T2, and this is repeated. From this, the wafer W is transferred to the rollers 201 and 20.
There is no uncleaned state at the position where it comes into contact with 2, and it is possible to prevent particles from remaining.

Since the pure water discharged from the nozzle 127 flows toward the outer peripheral side of the wafer W by centrifugal force, the particles can be washed out more efficiently, and the effect of preventing the particles from re-adhering is high. Note that the particles wrapping around from the back surface to the front surface are removed by the nozzle 82.

When it is determined that the cleaning of the back surface of the wafer W has been completed (step S4 in FIG. 23), the wafer gripping mechanism 80 moves up. Subsequently, the articulated robot 7 disposed between the back surface cleaning device 2 and the front surface cleaning device 3 receives the wafer W and transfers it to the front surface cleaning device 3 (Step S5 in FIG. 23).
Note that even during the waiting period during this time, pure water is sprayed onto the wafer W from the nozzle 34, and oxidation and drying of the wafer W are prevented.

In the surface cleaning device 3, the wafer elevating / lowering rotating mechanism 130 moves up, and the gripping claws 133 grip the wafer W.
Subsequently, the wafer W rotates, and the pure water is sprayed from the ultrasonic nozzle 139 onto the surface of the wafer W while swinging the nozzle support arm 138. At the same time, the arm 135 swings while rotating the circular brush 136 to clean the surface of the wafer W.

At this time, the arm 135 descends near the center of the wafer W to bring the circular brush 136 into contact with the surface of the wafer W. In this state, the arm 135 moves toward the outer periphery of the wafer W. When the circular brush 136 reaches the outer periphery,
The arm 135 moves up. By repeating this cycle during the cleaning, the wafer W is cleaned.

During cleaning, the back surface cleaning nozzle 145 injects pure water to the back surface of the wafer W. As a result, particles that go from the front surface to the back surface are removed. When the arm 135 is at the standby position (two-dot chain line in FIG. 21), pure water is sprayed from the cleaning nozzle 137 toward the circular brush 136. Thus, particles attached to the circular brush 136 can be removed.

Here, the circular brush 136 is brought into contact with the center of the surface of the rotating wafer W, and the circular brush 136 is moved in the radial direction. Particles generated by the circular brush 136 rubbing the wafer W by this movement and rotation of the wafer W are efficiently discharged to the outer peripheral side of the wafer W.

The circular brush 136 and the ultrasonic nozzle 1
39 need not be operated at the same time. If one of them is sufficient, they can be operated alone. Further, since the injection angle of the ultrasonic nozzle 139 can be adjusted, particles can be removed more efficiently.

When the cleaning of the surface of the wafer W is completed, the articulated robot 7 disposed between the surface cleaning device 3 and the washing / drying device 4 receives the wafer W and transfers it to the washing / drying device 4. During the waiting period during this time, pure water is sprayed onto the wafer W from the nozzle 34, thereby preventing oxidation and drying of the wafer W.

In the washing / drying apparatus 4, the wafer elevating / lowering rotating mechanism 141 moves up, and the gripping claws 144 grip the wafer W.
Then, the rinse nozzle 142 advances and injects pure water, and the back surface cleaning nozzle 145 injects pure water to the back surface. In this state, the wafer W is rotated. Then, after a predetermined time, the injection of the pure water from the nozzles 142 and 145 ends, and the water washing ends.

Subsequently, the wafer W is rotated at a high speed. Thereby, the moisture adhering to the front surface and the back surface of the wafer W is blown toward the outer peripheral direction of the wafer W, and the draining and drying processing of the wafer W is performed. Finally, water remaining at the center of the wafer W is removed by injecting a nitrogen gas from the gas nozzle 143. Note that the nitrogen gas may be injected while the wafer W is rotating. Further, the spray may be performed not only on the central portion of the wafer W but also on the entire surface.

When the draining and drying of the wafer W is completed, the articulated robot 7 arranged between the rinsing / drying device 4 and the unloader 5 receives the wafer W and transfers it to the unloader 5. The unloader 5 stores the received wafer W in another cassette C.

When all the wafers W in the cassette C on the supply side are processed and stored in the cassette C on the storage side, the cassette C on the unloader 5 is discharged.

Here, in the process up to the rinsing / drying device 4, the wafer W is always in a wet state during transportation and processing. Therefore, drying of the wafer W can be prevented, and oxidation of the wafer W due to contact with air, adhesion of particles to the wafer W, and the like can be prevented.

[Other Embodiments] (a) As shown in FIG. 27, the gripping portions 83 and 84 are gripping claws 8 arranged at intervals along the outer periphery of the wafer W.
5, 86 and gripping arms 87, 88 that support the gripping claws 85, 86 at the tips. At this time, the gripping claws 85 and 86 have abutment surfaces 93 and 94 for gripping the wafer W at lower portions, respectively. The gripping claws 85, 86 gradually become thicker in the horizontal direction in the figure as they go upward from the contact surfaces 93, 94. Also, the contact surfaces 93, 9
4 constitutes a part of the same cylindrical surface centered on the center of the wafer W, and can abut on the outer peripheral edge of the wafer W, respectively. Therefore, when the gripping claws 85 and 86 grip the wafer W, the entire back surface of the wafer W is exposed downward. (B) The magnitude of the holding force of the wafer W may be changed from a size that can prevent the rotation of the wafer W to a release state in which the holding force is completely lost, and a state in which the wafer W can rotate. It may be made to decrease to. (C) The present invention can be similarly implemented in a substrate processing apparatus that processes a glass substrate for a liquid crystal or a photomask. (D) In the configuration of FIG. 16, the brush may be oscillated instead of oscillating the wafer gripping mechanism. Alternatively, both may be swung. (E) In the vicinity of the liquid surface of the side wall facing the opening 13 of the water tank 11, a nozzle or a slit for jetting pure water is provided separately from the pure water supply port 15 so as to form a water flow from the opening 13 to the back side. Is also good. Further, the pure water supply port 15 itself is connected to the water tank 1.
It may be provided on one side wall to form a water flow. Further, a water flow may be formed by providing a forced drain hole instead of the weir 14 on the side surface on the weir 14 side.

[0077]

According to the first aspect of the invention, it is possible to prevent particles removed from the substrate from adhering to the brush and causing clogging.

According to the second aspect of the present invention, it is possible to prevent particles removed from the substrate from adhering to the brush and causing clogging.

According to the third aspect of the present invention, it is possible to further prevent the particles removed from the substrate from adhering to the brush and causing clogging.

According to the fourth aspect of the present invention, it is possible to provide a substrate processing apparatus capable of preventing particles removed from a substrate from adhering to a brush and causing clogging, and reliably cleaning the substrate.

According to the fifth aspect of the present invention, since the wafer holding / releasing mechanism can move the wafer edge contact portion and the urging means back and forth with respect to the substrate, the holding force of the substrate by the wafer edge contact portion can be reduced. If the brush is released or reduced, the frictional force at the contact surface between the brush and the substrate exceeds the frictional force between the wafer edge contact portion and the substrate, and the substrate rotates with the rotation of the brush. Therefore, it is possible to prevent the contact position between the wafer edge contact portion and the substrate from being unprocessed. Furthermore, since the brush is formed in a cross shape passing through the center of the brush or a large number of circular implants are arranged, the contact area between the brush and the substrate is changed, and The rotation of the substrate can be adjusted.

According to the sixth aspect of the present invention, it is possible to provide a substrate processing method capable of preventing particles removed from a substrate from adhering to a brush and causing clogging, and reliably cleaning the substrate.

[Brief description of the drawings]

FIG. 1 is a perspective view of a substrate processing apparatus according to an embodiment of the present invention.

FIG. 2 is a schematic longitudinal sectional view thereof.

FIG. 3 is a perspective partial view of an underwater loader.

FIG. 4 is a vertical sectional view of an underwater loader.

FIG. 5 is a plan view of the underwater loader.

FIG. 6 is a perspective view of a water tank.

FIG. 7 is a plan view of the transfer device.

FIG. 8 is a side view of the transfer device.

FIG. 9 is a partially cutaway side view of the articulated robot.

FIG. 10 is a partially broken plan view of the articulated robot.

FIG. 11 is a piping diagram of an articulated robot.

FIG. 12 is a perspective partial view of a back surface cleaning apparatus.

FIG. 13 is a partially broken plan partial view thereof.

FIG. 14 is a partial cutaway side view.

FIG. 15 is a side view of a roller.

FIG. 16 is a partial longitudinal sectional view of the back surface cleaning apparatus.

FIG. 17 is a partially cutaway perspective view of a brush rotation mechanism.

FIG. 18 is a partial perspective view of an embodiment of a brush unit.

FIG. 19 is a perspective partial view of another embodiment of the brush unit.

FIG. 20 is a partial perspective view of another embodiment of the brush unit.

FIG. 21 is a partial perspective view of a surface cleaning device.

FIG. 22 is a partial perspective view of a washing / drying apparatus.

FIG. 23 is a control flowchart of the back surface cleaning apparatus.

FIG. 24 is a partial explanatory view of the back surface cleaning apparatus.

FIG. 25 is a partial explanatory view of the back surface cleaning device.

FIG. 26 is a timing chart showing control of an air cylinder of the back surface cleaning device.

FIG. 27 is an explanatory view of a main part of another embodiment.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 underwater loader 2 backside cleaning device 3 front surface cleaning device 6 transfer device 7 articulated robot 80 wafer gripping mechanism 81 brush cleaning mechanism 82 front surface cleaning nozzle 85, 86 gripping claw 87, 88 gripping arm 120 brush unit 121 rotating shaft 122 shaft support unit 123 Transmission mechanism 124 Motor 127 Pure water supply nozzle 201, 202 Roller 203, 204 Cover member 205, 206 Spring 207, 208 Sliding bracket 209, 210 Air cylinder 211, 212 Piston rod 308, 310, 312 Implanted part 309, 311 313 Non-planted part W wafer

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme court ゛ (Reference) H01L 21/304 644 H01L 21/304 644B 644C 644G (72) Inventor Masami Sawamura Yasu-machi, Yasu-gun, Shiga Prefecture No. 24, Mikami Kuchinogawara Dainippon Screen Mfg. Co., Ltd. Yasu Works (72) Inventor Nobuyuki Hirai No. 42, Michigami Kuchinogawara, Yasucho, Yasu-gun, Shiga Pref.

Claims (6)

[Claims] 1. A brush which can be arranged so that a rotation center axis intersects a main surface of a substrate, and which is for cleaning a substrate while supplying a cleaning liquid to the substrate, wherein the brush is formed in a cross shape passing through the center. Brush. 2. A brush which can be disposed so that a rotation center axis intersects a main surface of a substrate, and which cleans a substrate while supplying a cleaning liquid to the substrate, wherein a large number of circular planting portions are disposed. A brush characterized by being. 3. The brush according to claim 1, wherein a pure water supply nozzle for discharging the pure water as the cleaning liquid to the substrate is disposed at a central portion. 4. A substrate holding means for holding a substrate, and a substrate for cleaning the substrate held by the substrate holding means.
A substrate processing apparatus comprising: the brush according to any one of claims 1 to 3; and a rotating unit that relatively rotates the brush and the substrate held by the substrate holding unit. 5. The apparatus according to claim 1, wherein the substrate is a disk-shaped substrate, and the substrate holding means includes a wafer edge contact portion capable of contacting a peripheral edge of the substrate, and a biasing device for urging the wafer edge contact portion toward the substrate. Urging means, and a wafer holding / releasing mechanism for moving the wafer edge contact portion and the urging means back and forth with respect to the substrate, and relatively swings the substrate and the brush held by the substrate holding means. The substrate processing apparatus according to claim 4, further comprising a swing unit. 6. A substrate processing method, wherein the substrate is washed while the substrate held by the substrate holding means and the brush according to claim 1 are relatively rotated.