JP6797526B2 - Substrate cleaning equipment - Google Patents

Description

The present invention relates to a substrate cleaning device that cleans a substrate surface using a two-fluid jet.

Conventionally, a cleaning method using a two-fluid jet (2FJ) has been known as a cleaning method for cleaning the substrate surface in a non-contact manner. In this cleaning method, minute droplets (mist) placed on a high-speed gas are ejected from a two-fluid nozzle toward the substrate surface to collide, and the shock wave generated by the collision of the droplets with the substrate surface is used. Removes (cleans) particles and the like on the surface of the substrate (see, for example, Patent Document 1).

However, in two-fluid cleaning, when a two-fluid jet collides with the surface of the substrate to remove fine particles on the surface of the substrate, the droplets on the surface of the substrate are surrounded by the centrifugal force of the rotating substrate and the side jet of the two-fluid cleaning. Scatter to. If the scattered droplets adhere to the outer wall of the cleaning module, they may contaminate the cleaning module or reattach to the substrate. Therefore, in the conventional device, in order to suppress the scattering of droplets, a cover is installed around the rotating substrate, the droplets scattered toward the outer wall are received by the cover, and the droplets are discharged from the lower part of the cover to the outside of the device. , It prevented reattachment to the substrate and suppressed the defect.

Japanese Unexamined Patent Publication No. 2005-294891

However, in the conventional device, the cover installed around the substrate is fixed. In the two-fluid cleaning, the velocity (flow velocity) of the droplets ejected from the two-fluid nozzle is high, and the velocity of the side jet (spraying velocity of the droplets in the radial direction) is also high (see FIG. 7). For example, in general two-fluid cleaning, the velocity Vo of droplets ejected from the two-fluid nozzle is 250 to 350 m / sec, and the velocity Vf of the side jet (spraying velocity of droplets in the radial direction) is 300 to. It is 400 m / sec. Further, in high-speed two-fluid cleaning or ultra-high-speed two-fluid cleaning, the velocity Vo of the droplets ejected from the two-fluid nozzle is 350 to 400 m / sec, and the velocity Vf of the side jet (the scattering velocity of the droplets in the radial direction). Is 700 to 1200 m / sec.

As described above, in the two-fluid cleaning, the speed of the side jet (the scattering speed of the droplets in the radial direction) becomes very high, and the droplets colliding with the cover may bounce off and reattach to the substrate surface. In particular, in high-speed two-fluid cleaning or ultra-high-speed two-fluid cleaning, there is a high risk of reattachment to the substrate surface.

The present invention has been made in view of the above problems, and is a substrate capable of suppressing the rebound of droplets from the cover and preventing the droplets from reattaching to the surface of the substrate when performing two-fluid cleaning. It is an object of the present invention to provide a cleaning device.

The substrate cleaning device of the present invention includes a substrate holding mechanism for holding a substrate, a substrate rotating mechanism for rotating a substrate held by the substrate holding mechanism, and a two-fluid nozzle for ejecting a two-fluid jet toward the surface of the substrate. A cover arranged around the substrate and a cover rotating mechanism for rotating the cover are provided, and the cover rotating mechanism rotates the cover in the same rotation direction as the substrate.

According to this configuration, even if droplets on the surface of the substrate are scattered and collide with the cover due to the centrifugal force generated by the rotation of the substrate or the side jet generated by the two-fluid cleaning during the two-fluid cleaning, the cover Since it is rotated in the same rotation direction as the substrate, the collision speed of the droplets can be reduced as compared with the case where the cover is not rotated. As a result, the bounce of the droplet from the cover can be suppressed, and the droplet can be prevented from reattaching to the surface of the substrate.

Further, the substrate cleaning device of the present invention includes a substrate holding mechanism for holding a substrate, a substrate rotating mechanism for rotating a substrate held by the substrate holding mechanism, a pulsating cleaning mechanism for oscillating and cleaning the surface of the substrate, and a substrate. A cover arranged around the substrate and a cover rotating mechanism for rotating the cover are provided, and the cover rotating mechanism rotates the cover in the same rotation direction as the substrate.

According to this configuration, even if a large amount of rinse water supplied during rocking cleaning scatters as droplets from the surface of the substrate due to the centrifugal force generated by the rotation of the substrate and collides with the cover, the cover is covered. Is rotated in the same rotation direction as the substrate, so that the collision speed of the droplets can be reduced as compared with the case where the cover is not rotated. As a result, the bounce of the droplet from the cover can be suppressed, and the droplet can be prevented from reattaching to the surface of the substrate.

Further, the substrate cleaning device of the present invention includes a substrate holding mechanism for holding the substrate, a substrate rotating mechanism for rotating the substrate held by the substrate holding mechanism, and an ultrasonic cleaning mechanism for cleaning the surface of the substrate using ultrasonic waves. A cover arranged around the substrate and a cover rotating mechanism for rotating the cover are provided, and the cover rotating mechanism rotates the cover in the same rotation direction as the substrate.

According to this configuration, even if a large amount of rinse water supplied during ultrasonic cleaning scatters as droplets from the surface of the substrate due to the centrifugal force generated by the rotation of the substrate and collides with the cover, the cover is covered. Is rotated in the same rotation direction as the substrate, so that the collision speed of the droplets can be reduced as compared with the case where the cover is not rotated. As a result, the bounce of the droplet from the cover can be suppressed, and the droplet can be prevented from reattaching to the surface of the substrate.

Further, in the substrate cleaning device of the present invention, the cover rotation mechanism may rotate the cover at the same angular velocity as the substrate.

According to this configuration, since the cover is rotating at the same angular velocity as the substrate, the collision of droplets is higher than when the cover is rotating at a different angular velocity than the substrate (for example, when the cover is not rotating). The speed can be reduced.

Further, in the substrate cleaning device of the present invention, the radial distance A between the outer edge of the substrate and the tip of the cover is set in the range of 2 mm to 80 mm, and the distance B in the height direction between the substrate and the tip of the cover is set. The distance C in the radial direction between the outer edge of the substrate and the inner peripheral surface of the cover may be set in the range of 3 mm to 50 mm, and may be set in the range of 2 mm to 80 mm.

According to this configuration, since the cover is arranged at an appropriate position with respect to the substrate, it is possible to suppress the splashing of the droplets from the cover and prevent the droplets from reattaching to the surface of the substrate. ..

Further, in the substrate cleaning device of the present invention, the radial distance A between the outer edge of the substrate and the tip of the cover is set to 2 mm, and the height distance B between the substrate and the tip of the cover is set to 15 mm. The radial distance C between the outer edge of the substrate and the inner peripheral surface of the cover may be set to 19 mm.

According to this configuration, since the cover is arranged at an optimum position with respect to the substrate, it is possible to suppress the splashing of the droplets from the cover and prevent the droplets from reattaching to the surface of the substrate. ..

Further, in the substrate cleaning apparatus of the present invention, the two-fluid nozzle may be provided at an inclined angle so as to eject the two-fluid jet toward the upstream side in the rotation direction of the substrate.

According to this configuration, since the two-fluid jet is ejected from the two-fluid nozzle toward the upstream side in the rotation direction of the substrate (against the rotation of the substrate), the relative speed of the two-fluid jet with respect to the rotating substrate increases. However, the cleaning performance can be improved.

Further, the substrate cleaning device of the present invention is provided in a casing accommodating the substrate cleaning device, a pair of gas inlets provided on the wall surface of the casing and allowing gas to flow into the casing, and provided in the lower part of the casing. A gas discharge port for discharging gas and a pair of gas inlets may be provided on the opposite wall surfaces of the casing and may be arranged at a position higher than the substrate.

According to this configuration, gas flows into the casing from a pair of gas inlets provided on the facing wall surfaces of the casing. Since the pair of gas inlets are located higher than the substrate, the gas flowing in from the pair of gas inlets collides with the upper part of the substrate in the central part of the casing to form a downdraft, and the lower part of the casing is formed. It is discharged from the gas outlet of. At this time. Droplets and mist in the casing are also discharged from the gas outlet at the bottom of the casing along the downdraft. As a result, it is possible to suppress the spread of droplets and mist in the casing, and it is possible to suppress the defect due to the reattachment of the droplets and mist.

Further, in the substrate cleaning apparatus of the present invention, substrate transport areas are provided adjacent to each other on the upstream side and the downstream side of the substrate cleaning device, and the gas inflow port is blown from a blower unit in the substrate transport area. Gas may be introduced into the casing.

According to this configuration, it is possible to suppress the spread of droplets and mist in the casing by utilizing the blower unit in the substrate transport area adjacent to the substrate cleaning device.

Further, in the substrate cleaning apparatus of the present invention, a gas supply line for supplying gas into the casing may be connected to the gas inlet.

According to this configuration, it is possible to suppress the spread of droplets and mist in the casing due to the gas supplied from the gas supply line. Therefore, for example, even when the blower unit in the substrate transport area adjacent to the substrate cleaning device cannot be used, it is possible to suppress the spread of droplets and mist in the casing.

Further, in the substrate cleaning device of the present invention, the two-fluid nozzle may be composed of a conductive member.

According to this configuration, since the tip of the two-fluid nozzle is made of a conductive member, the amount of charge of the droplet ejected from the two-fluid nozzle can be suppressed. As a result, the amount of charge on the surface of the substrate due to the two-fluid cleaning can be suppressed, and the defect caused by the charged particles adhering to the substrate can be suppressed.

Further, the substrate cleaning device of the present invention may include a chemical solution supply nozzle for supplying a chemical solution having conductivity to the substrate.

According to this configuration, since the chemical solution having conductivity is supplied from the chemical solution supply nozzle, the amount of charge on the surface of the substrate can be suppressed. As a result, the amount of charge on the surface of the substrate due to the two-fluid cleaning can be suppressed, and the defect caused by the charged particles adhering to the substrate can be suppressed.

According to the present invention, when performing two-fluid cleaning, it is possible to suppress the rebound of the droplets from the cover and prevent the droplets from reattaching to the surface of the substrate.

It is a top view which shows the whole structure of the substrate processing apparatus provided with the substrate cleaning apparatus (the substrate cleaning unit) in embodiment of this invention. It is a perspective view which shows the structure of the substrate cleaning apparatus (board cleaning unit) in embodiment of this invention. It is a top view which shows the structure of the substrate cleaning apparatus (board cleaning unit) in embodiment of this invention. It is a side view which shows the structure of the substrate cleaning apparatus (board cleaning unit) in embodiment of this invention. It is explanatory drawing which shows the main part of the substrate cleaning apparatus (board cleaning unit) in embodiment of this invention. It is explanatory drawing of the collision speed of the droplet of the two-fluid cleaning in the substrate cleaning apparatus (board cleaning unit) of the embodiment of this invention. It is explanatory drawing of the speed of the side jet of 2 fluid cleaning. It is a perspective view which shows the structure of the substrate cleaning apparatus (board cleaning unit) in another embodiment. It is a perspective view which shows the structure of the substrate cleaning apparatus (board cleaning unit) in another embodiment. It is a perspective view which shows the structure of the substrate cleaning apparatus (board cleaning unit) in another embodiment. It is a perspective view which shows the structure of the substrate cleaning apparatus (board cleaning unit) in another embodiment. It is a top view which shows the main part of the substrate cleaning apparatus (board cleaning unit) in another embodiment. It is a side view which shows the main part of the substrate cleaning apparatus (board cleaning unit) in another embodiment. It is a side view which shows the main part of the substrate cleaning apparatus (board cleaning unit) provided with the air flow improvement function. It is a side view which shows the main part of the substrate cleaning apparatus (board cleaning unit) provided with the air flow improvement function. It is a side view which shows the main part of another example of the substrate cleaning apparatus (board cleaning unit) provided with the air flow improvement function. It is a side view which shows the main part of another example of the substrate cleaning apparatus (board cleaning unit) provided with the air flow improvement function. It is a side view which shows the main part of the substrate cleaning apparatus (board cleaning unit) which has the charge suppression function.

Hereinafter, the substrate cleaning apparatus according to the embodiment of the present invention will be described with reference to the drawings. In this embodiment, the case of a substrate cleaning device used for cleaning a semiconductor wafer or the like is illustrated.

FIG. 1 is a plan view showing an overall configuration of a substrate processing apparatus including the substrate cleaning apparatus (board cleaning unit) of the present embodiment. As shown in FIG. 1, the substrate processing apparatus includes a substantially rectangular housing 10 and a load port 12 on which a substrate cassette for stocking substrates such as a large number of semiconductor wafers is placed. The load port 12 is arranged adjacent to the housing 10. The load port 12 has an open cassette, SMIF (Standard Manufacturing Inter).
face) Pod or FOUP (Front Opening Unified Pod) can be installed. SMIF and FOUP are airtight containers that can maintain an environment independent of the external space by storing the substrate cassette inside and covering it with a partition wall.

Inside the housing 10, a plurality of (four in the example of FIG. 1) polishing units 14a to 14d, a first cleaning unit 16 and a second cleaning unit 18 for cleaning the polished substrate, and a cleaned substrate are placed. A drying unit 20 for drying is housed. The polishing units 14a to 14d are arranged along the longitudinal direction of the substrate processing apparatus, and the cleaning units 16 and 18 and the drying unit 20 are also arranged along the longitudinal direction of the substrate processing apparatus. The substrate cleaning apparatus of the present invention is applied to the second cleaning unit 18.

As shown in FIG. 1, the first substrate transfer robot 22 is arranged in the area surrounded by the funnel port 12, the polishing unit 14a located on the funnel port 12 side, and the drying unit 20. Further, the substrate transport unit 24 is arranged in parallel with the polishing units 14a to 14d. The first substrate transfer robot 22 receives the substrate before polishing from the funnel port 12 and delivers it to the substrate transfer unit 24, and receives the dried substrate from the drying unit 20 and returns it to the funnel port 12. The substrate transfer unit 24 conveys the substrate received from the first substrate transfer robot 22, and transfers the substrate between the polishing units 14a to 14d.

Between the first cleaning unit 16 and the second cleaning unit 18, a second substrate transfer robot 26 that transfers a substrate between the units 16 and 18 is arranged. Further, between the second cleaning unit 18 and the drying unit 20, a third substrate transfer robot 28 that transfers the substrate between the units 18 and 20 is arranged.

Further, inside the housing 10, a control unit 30 that controls the movement of each device of the substrate processing device is arranged. The control unit 30 also has a function of controlling the movement of the second cleaning unit (board cleaning device) 18.

In the present embodiment, as the first cleaning unit 16, a roll cleaning unit that cleans the substrate by rubbing roll-shaped extending roll cleaning members on both the front and back surfaces of the substrate in the presence of a cleaning liquid is used. The first cleaning unit (roll cleaning unit) 16 is configured to be used in combination with megasonic cleaning in which ultrasonic waves of around 1 MHz are applied to the cleaning liquid and the acting force due to the vibration acceleration of the cleaning liquid is applied to the fine particles adhering to the substrate surface. ing.

Further, the substrate cleaning device of the present invention is used as the second cleaning unit 18. Further, as the drying unit 20, a spin drying unit is used which holds the substrate, ejects IPA steam from a moving nozzle to dry the substrate, rotates the substrate at a higher speed, and dries the substrate by centrifugal force. The cleaning unit may have a two-stage upper and lower structure in which the cleaning units 16 and 18 are arranged in two upper and lower stages. In this case, the cleaning unit has two upper and lower substrate processing units.

FIG. 2 is a perspective view of the substrate cleaning device (board cleaning unit) according to the present embodiment, and FIG. 3 is a plan view of the substrate cleaning device (board cleaning unit) according to the present embodiment.

As shown in FIGS. 2 and 3, the substrate cleaning apparatus (second cleaning unit) 18 of the present embodiment is erected on the side of the cleaning tank 40 surrounding the substrate W and the processing tank 40. A rotatable support shaft 42 and a swing arm 44 extending in the horizontal direction with a base connected to the upper end of the support shaft 42 are provided. In the cleaning tank 40, the substrate W is held by a chuck or the like and is configured to rotate by the rotation of the chuck or the like. A fluid nozzle (two-fluid nozzle) 46 is attached to the free end (tip) of the swing arm 44 so as to be vertically movable.

The fluid nozzle 46 is connected to a carrier gas supply line 50 that supplies a carrier gas such as N ₂ gas and a cleaning liquid supply line 52 that supplies a cleaning liquid such as pure water or CO ₂ gas dissolved water. By ejecting the carrier gas such as N ₂ gas supplied to the inside of the carrier gas and the cleaning liquid such as pure water or CO ₂ gas dissolved water from the fluid nozzle 46 at high speed, the cleaning liquid becomes minute droplets (mist) in the carrier gas. An existing two-fluid jet stream is generated. By ejecting a two-fluid jet flow generated by the fluid nozzle 46 toward the surface of the rotating substrate W and causing it to collide, the surface of the substrate using the shock wave generated by the collision of minute droplets with the substrate surface It is possible to remove (clean) particles and the like.

The support shaft 42 is connected to a motor 54 as a drive mechanism that swings the swing arm 44 around the support shaft 42 by rotating the support shaft 42.

In this example, a pencil-type cleaning tool 60 made of, for example, a PVA sponge is attached to the tip of the swing arm 44 so as to be vertically movable and rotatable. Further, a rinse liquid supply nozzle 62 for supplying the rinse liquid and a chemical liquid supply nozzle 64 for supplying the chemical liquid are arranged on the surface of the substrate W which is located above the side of the cleaning tank 40 and is held by a chuck or the like and is rotating. Has been done. While the lower end of the pencil-type washer 60 is brought into contact with the surface of the rotating substrate W with a predetermined pressing force, the pencil-type washer 60 is moved by the swing of the swing arm 44, and at the same time, is brought to the surface of the substrate W. By supplying a rinse solution or a chemical solution, the surface of the substrate W is contact-cleaned. The contact cleaning of the surface of the substrate W is a process performed as necessary and is not always necessary.

As shown in FIG. 3, the fluid nozzle 46 is located above the center O of the substrate W and above the displacement point B separated from the center O by a predetermined distance from the offset position A as the swing arm 44 swings. The surface of the substrate W is cleaned by moving along the arc-shaped movement locus to the cleaning end position C outside the outer peripheral portion of the substrate W through the position. At the time of this cleaning, a two-fluid jet stream in which the cleaning liquid exists as minute droplets (mist) in the carrier gas is ejected from the fluid nozzle 46 toward the surface of the rotating substrate W. Note that FIG. 3 shows a state in which the fluid nozzle 46 is located above the displacement point B.

Here, the configuration of the substrate cleaning apparatus (board cleaning unit) will be described in more detail with reference to the drawings. FIG. 4 is a side view of the substrate cleaning device (board cleaning unit).

As shown in FIG. 4, the substrate cleaning device includes a substrate holding mechanism 1 that holds the substrate W horizontally, a motor (rotating mechanism) 2 that rotates the substrate W around its central axis via the substrate holding mechanism 1. It includes a rotating cover 3 arranged around the substrate W.

The substrate holding mechanism 1 includes a plurality of chucks 70 that grip the peripheral edge of the substrate W, a circular pedestal 71 to which these chucks 70 are fixed, a stage 72 that supports the pedestal 71, and a hollow that supports the stage 72. It has a shaped support shaft 73. In this case, the pedestal 71, the stage 72, and the support shaft 73 are arranged coaxially. The rotary cover 3 is fixed to the end of the stage 72, and the stage 72 and the rotary cover are also arranged coaxially. Further, the substrate W held by the chuck 70 and the rotary cover 3 are located coaxially with each other.

A motor 2 is connected to the outer peripheral surface of the support shaft 73. The torque of the motor 2 is transmitted to the support shaft 73, whereby the substrate W held by the chuck 70 rotates. In this case, the substrate W and the rotating cover rotate integrally, and the relative speed between the two becomes 0. There may be a slight speed difference between the substrate W and the rotating cover 3.

In this way, the substrate W and the rotation cover 3 can be rotated by the same rotation mechanism (motor 2). In this case, the substrate W and the rotation cover 3 can be rotated at the same speed. Rotating the substrate W and the rotating cover 3 at the same speed means rotating the substrate W and the rotating cover 3 in the same direction at the same angular velocity, and does not include rotating them in opposite directions. This rotation mechanism (motor 2) corresponds to the substrate rotation mechanism and the cover rotation mechanism of the present invention. The substrate W and the rotation cover 3 may be rotated by separate rotation mechanisms.

Further, as shown in FIG. 4, a plurality of discharge holes 74 are formed in the stage 72. The discharge hole 74 is, for example, an elongated hole extending in the circumferential direction of the rotary cover 3. The cleaning liquid supplied from the fluid nozzle 46 is discharged through the discharge hole 74 together with the carrier gas and the ambient atmosphere (usually air). In this embodiment, the displacement is controlled in the range of 1 to ³ m ³ / min. Then, by controlling the air supply amount to be lower than the exhaust amount, the atmosphere in the substrate cleaning device (board cleaning unit) is appropriately exhausted. As a result, the droplets can be appropriately discharged on the air flow, and the droplets can be suppressed from being scattered on the substrate. Further, a fixed cover 75 is provided on the outside of the rotating cover 3. The fixed cover 75 is configured not to rotate.

FIG. 5 is an explanatory view of a main part of the substrate cleaning device (board cleaning unit). In the present embodiment, the radial distance A between the outer edge of the substrate and the tip of the rotating cover is set in the range of 2 mm to 80 mm, and the height distance B between the substrate and the tip of the rotating cover is 3 mm. It is desirable that the distance C between the outer edge of the substrate and the inner peripheral surface of the rotating cover is set in the range of about 50 mm and is set in the range of 2 mm to 80 mm. For example, the radial distance A between the outer edge of the substrate and the tip of the rotating cover is set to 2 mm, the height distance B between the substrate and the tip of the rotating cover is set to 15 mm, and the outer edge of the substrate. The radial distance C between the rotating cover and the inner peripheral surface of the rotating cover is set to 19 mm.

The operation of the substrate cleaning device configured as described above will be described.

In the substrate processing apparatus, the surface of the substrate taken out from the substrate cassette in the load port 12 is conveyed to any of the polishing units 14a to 14d for polishing. Then, the surface of the substrate after polishing is cleaned by the first cleaning unit (roll cleaning unit) 16 and then further cleaned by the second cleaning unit (substrate cleaning unit) 18 using a two-fluid jet flow. When the substrate surface is cleaned by the second cleaning unit (board cleaning unit) 18, a two-fluid jet stream is ejected toward the surface of the rotating substrate W while controlling the moving speed of the fluid nozzle 46.

In the present embodiment, the rinse liquid is supplied to the surface of the substrate for several seconds (for example, 3 seconds) from the rinse liquid supply nozzle 62 while rotating the substrate that has been roll-cleaned by the first cleaning unit 16 and carried into the second cleaning unit 18. Then, the surface of the substrate is rinsed, and the pencil-type cleaning tool 60 is scanned a predetermined number of times (for example, 2 to 3 times) while spraying the chemical solution onto the surface of the substrate from the chemical solution supply nozzle 64 to clean the substrate surface. In the same second cleaning unit 18, cleaning using a two-fluid jet flow is immediately started.

To clean the substrate surface using the two-fluid jet flow, the swing arm 44 is swung a predetermined number of times (for example, 1 to 4 times), and the fluid nozzle 46 ejecting the two-fluid jet flow is rotating the substrate. It is done by moving above. The angular velocity of the swing arm 44, that is, the moving speed of the fluid nozzle 46 is calculated from the processing allowable time and number of times. It should be noted that the rotation speed of the substrate when cleaning the substrate surface using the two-fluid jet flow and the rotation speed of the substrate when cleaning the substrate surface using the pencil-type cleaning tool 60 do not necessarily match. There is no need.

Then, the cleaned substrate is taken out from the second cleaning unit 18, carried into the drying unit 20 for spin drying, and then the dried substrate is returned to the substrate cassette of the load port 12.

According to the substrate cleaning apparatus of the present embodiment, during two-fluid cleaning, droplets on the surface of the substrate are scattered by the centrifugal force generated by the rotation of the substrate and the side jets generated by the two-fluid cleaning to cover the rotating cover. Even if a collision occurs, the rotating cover rotates in the same rotation direction as the substrate, so that the collision speed of the droplets can be reduced as compared with the case where the cover does not rotate. As a result, it is possible to suppress the rebound of the droplets from the rotating cover and prevent the droplets from reattaching to the surface of the substrate.

In this case, since the rotating cover is rotating at the same angular velocity as the substrate, the collision speed of the droplets is higher than when the rotating cover is rotating at a different angular velocity from the substrate (for example, when the cover is not rotating). Can be reduced.

For example, as shown in FIG. 6, in the case of a fixed cover (when the cover is not rotated), the collision velocity V of the droplet is V ₁ (= r ₁ ω), and the droplet (at a large relative velocity). Droplets that collide with the cover) may scatter on the substrate against the air flow, whereas in the case of a rotating cover (especially if the rotating cover is rotating at the same angular velocity as the substrate). The collision velocity V of the droplets is V ₁ −V ₂ (= r ₁ ω −r ₂ ω ≈ 0), and the collision velocity of the droplets can be reduced. In this case, the droplet (the droplet that collides with the cover at a small relative velocity) can be derived from the lower part by riding the air flow. Here, r ₁ is the radius of the substrate W, and r ₂ is the radius of the inner peripheral surface of the rotating cover. Further, ω is the angular velocity of the substrate W and the rotating cover.

Further, in the present embodiment, as shown in FIG. 5, since the rotating cover is arranged at an optimum position with respect to the substrate W, it is possible to suppress the rebound of the droplets from the rotating cover, and the droplets are formed on the substrate. It can be prevented from reattaching to the surface of the.

Although the embodiments of the present invention have been described above by way of illustration, the scope of the present invention is not limited to these, and can be changed or modified according to an object within the scope described in the claims. is there.

For example, in the above description, an example in which both the fluid nozzle (two-fluid nozzle) 46 and the pencil-type cleaning tool 60 are provided at the tip of the swing arm 44 has been described, but as shown in FIG. 8, the swing arm 44 Only the fluid nozzle (two-fluid nozzle) 46 may be provided at the tip. Further, as shown in FIG. 9, only the pencil type cleaning tool 60 may be provided at the tip of the swing arm 44. Further, as shown in FIG. 10, the substrate cleaning device 18 may be provided with an ultrasonic cleaning machine 90 that cleans the surface of the substrate W using ultrasonic waves.

Further, as shown in FIG. 11, the fluid nozzle (two-fluid nozzle) 46 may be provided at the outer peripheral position (edge position) of the substrate. The surface of the outer periphery (edge) of the substrate can be cleaned by the fluid nozzle (two-fluid nozzle) 46. In this case, the local exhaust mechanism 80 may be provided in the vicinity of the fluid nozzle (two-fluid nozzle) 46. With this local exhaust mechanism 80, the exhaust at the outer peripheral position (edge position) of the substrate can be strengthened, and the scattering of droplets can be suppressed. The local exhaust mechanism 80 is not always necessary. That is, the local exhaust mechanism 80 does not have to be provided.

Further, the two-fluid nozzle 46 may be provided at an angle of a predetermined angle so as to eject the two-fluid jet toward the upstream side in the rotation direction of the substrate W. For example, the two-fluid nozzle 46 has an angle of 0 ° to 90 ° with respect to the rotation direction (tangential direction) toward the upstream side in the rotation direction of the substrate W in a plan view.
It can be installed at an angle within the range of. In the example of FIG. 12A, the two-fluid nozzle 46 is provided at an angle of 0 ° with the rotation direction (tangential direction) toward the upstream side in the rotation direction of the substrate W. As a result, the relative speed of the two-fluid jet with respect to the rotating substrate is increased, and the cleaning performance can be improved. In the example of FIG. 12B, the two-fluid nozzle 46 is provided at an angle of 90 ° with the rotation direction (tangential direction) of the substrate W. In this case, the relative velocity of the two-fluid jet with respect to the rotating substrate does not decrease, and the cleaning performance can be maintained (without decreasing).

Further, the two-fluid nozzle 46 can be provided at an angle of 45 ° to 90 ° with respect to the rotation direction toward the upstream side in the rotation direction of the substrate W in a side view. In this case, it can be said that the two-fluid nozzle 46 can be provided at an angle of 45 ° to 90 ° with the substrate surface toward the upstream side in the rotation direction of the substrate W in a side view. In the example of FIG. 13A, the two-fluid nozzle 46 is provided at an angle of 45 ° with the rotation direction (board surface) toward the upstream side in the rotation direction of the substrate W. As a result, the relative speed of the two-fluid jet with respect to the rotating substrate is increased, and the cleaning performance can be improved. In the example of FIG. 13B, the two-fluid nozzle 46 is provided at an angle of 90 ° with respect to the rotation direction (board surface) of the substrate W. In this case, the relative velocity of the two-fluid jet with respect to the rotating substrate does not decrease, and the cleaning performance can be maintained (without decreasing).

14 and 15 show a substrate cleaning device having an air flow improving function. The substrate cleaning device 18 is housed in a casing 80, and a pair of ventilation plates 81 are provided on the upper portion of the wall surface of the casing 80. In this case, the ventilation plate 81 is arranged at a position higher than the substrate W (upper side in FIG. 14). A substrate transfer area 82 of the second substrate transfer robot 26 is adjacently provided on the upstream side (left side in FIG. 14) of the substrate cleaning device 18, and is provided on the downstream side (right side in FIG. 14) of the substrate cleaning device 18. Is provided with a substrate transfer area 83 of the third substrate transfer robot 28 adjacent to the third substrate transfer robot 28. A blower unit 84 is provided above each of the substrate transport areas 82 and 83, and the ventilation plate 81 is provided with a gas inflow port 85 for introducing the gas blown from the blower unit 84 into the casing 80. Has been done. As the blower unit 84, for example, an FFU (fan filter unit) that sucks air with a fan and purifies it with a filter may be adopted. By providing the blower unit 84, clean air can be blown from the upper side to the lower side in the vertical direction in the board transport areas 82 and 83 for transporting the substrate, so that particles and the like fly up from below. It is possible to prevent contamination of the substrate during transportation in the substrate transfer areas 82 and 83. At the lower part of the casing 80, a gas discharge port 86 for discharging the gas inside the casing 80 to the outside is provided. The gas discharge port 86 may be the discharge hole 74 described above.

According to such a substrate cleaning device 18, gas flows into the casing 80 from a pair of gas inlets 85 provided on the facing wall surfaces of the casing 80. Since the pair of gas inlets 85 are arranged higher than the substrate W, the gas flowing in from the pair of gas inlets 85 collides with the upper part of the substrate W at the center of the casing 80 to form a downdraft. , It is discharged to the outside from the gas discharge port 86 at the lower part of the casing 80. At this time, the droplets and mist inside the casing 80 are also discharged to the outside from the gas discharge port 86 at the lower part of the casing 80 along the downdraft. As a result, it is possible to suppress the spread of droplets and mist inside the casing 80, and it is possible to suppress contamination and defects due to reattachment of the droplets and mist. In this case, the blower unit 84 of the substrate transport areas 82 and 83 adjacent to the substrate cleaning device 18 can be used to prevent droplets and mist from spreading inside the casing 80.

Further, FIGS. 16 and 17 show a modified example of the substrate cleaning device having an air flow improving function. In this example, the gas supply port 88 of the gas supply line 87 is connected to the ventilation plate 81, and the gas supplied from the gas supply line 87 (for example, N ₂ gas) is supplied from the gas inflow port 85 to the inside of the casing 80. Will be done. A valve 89 is provided in the gas supply line 87, and the gas supply can be controlled on / off. For example, the gas supply is turned on (started) when the substrate W is conveyed inside the casing 80, and the gas supply is turned off (started) when the substrate W is conveyed from the casing to the outside after cleaning the substrate W. Stop).

Also in this modification, it is possible to suppress the spread of droplets and mist inside the casing 80 due to the gas supplied from the gas supply line 87. In this case, for example, even in a situation where the blower unit 84 of the substrate transport areas 82 and 83 adjacent to the substrate cleaning device 18 cannot be used, it is possible to suppress the spread of droplets and mist inside the casing 80. it can.

FIG. 18 shows a substrate cleaning device with charge suppression. The substrate cleaning device 18 includes a chemical liquid supply nozzle 64 that supplies a conductive chemical liquid to the substrate W, and a rinse supply nozzle 62 that supplies a rinse liquid (for example, pure water) to the substrate W. In the substrate cleaning device 18, when the substrate W is first carried in, the chemical liquid having conductivity is supplied from the chemical liquid supply nozzle 64 to the surface of the substrate W (see FIG. 18A), and then from the two-fluid nozzle 46. The two-fluid cleaning of the substrate W is performed by ejecting a two-fluid jet (see FIG. 18B). 2 It is desirable to continue supplying the conductive chemical solution from the chemical solution supply nozzle 64 during the fluid cleaning. Then, after the two-fluid cleaning is completed, the rinsing liquid is supplied to the surface of the substrate W from the rinsing supply nozzle 62, and the chemical liquid is washed away (see FIG. 18C).

According to such a substrate cleaning device 18, since the chemical solution having conductivity is supplied from the chemical solution supply nozzle 64, the amount of charge on the surface of the substrate W can be suppressed. As a result, the amount of charge on the surface of the substrate due to the two-fluid cleaning can be suppressed, and contamination and defects due to the charged particles adhering to the substrate W can be suppressed.

The two-fluid nozzle 46 may be composed of a conductive member (for example, conductive PEEK or the like). Even with such a configuration, the amount of charge of the droplets ejected from the two-fluid nozzle 46 can be suppressed. Therefore, the amount of charge on the surface of the substrate due to the two-fluid cleaning can be suppressed, and contamination and defects due to the charged particles adhering to the substrate W can be suppressed.

Further, the flow velocity of the carrier gas (N ₂ gas, etc.) is larger than that of the cleaning liquid such as CO ₂ gas dissolved water, and therefore, the carrier gas supply line of the carrier gas (N ₂ gas, etc.) is higher than the cleaning liquid supply line 52. 50 is more likely to be charged. Therefore, a conductive member is used not only for the two-fluid nozzle 46 but also for the member forming the carrier gas supply line 50 connected to the two-fluid nozzle 46, and the carrier gas supply line 50 is grounded at the point where the carrier gas supply line 50 comes out of the casing 80. By connecting the lead wire 101 to the carrier gas supply line 50 so as to be (grounded), further charging can be effectively prevented (see FIG. 18A). In this configuration, it is possible to prevent the charged particles from adhering to the substrate W, so that the chemical solution supply nozzle 64 does not necessarily have to be provided (at this time, the rinse supply nozzle 62 may not be provided). it can). Further, when a cleaning unit for cleaning the substrate W with a rinsing liquid is provided downstream from the substrate cleaning device 18, the chemical liquid supply nozzle 64 is provided, but the rinse supply nozzle 62 is not always provided. May be good.

Regarding the above-mentioned air flow improving function (see FIGS. 14 to 17) of the substrate cleaning apparatus of the present invention, not only the substrate cleaning apparatus using a two-fluid nozzle but also a swing cleaning of a pencil-type cleaning tool or the like is performed. It can also be applied to a substrate cleaning device that uses a mechanism or an ultrasonic cleaning mechanism. Further, as described above, the two-fluid nozzle and the carrier gas supply line composed of the conductive member are not only the substrate cleaning device having a rotatable cover described in this embodiment, but also the substrate having a fixed cover. It can also be applied to cleaning equipment.

As described above, the substrate cleaning apparatus according to the present invention has the effect of suppressing the rebound of droplets from the cover and preventing the droplets from reattaching to the surface of the substrate when performing two-fluid cleaning. It is useful for cleaning semiconductor wafers and the like.

1 Board holding mechanism 2 Motor (board rotation mechanism, cover rotation mechanism)
3 Rotating cover 10 Housing 12 Load port 14a-14d Polishing unit 16 1st cleaning unit 18 2nd cleaning unit (board cleaning device)
20 Drying unit 22 1st board transfer robot 24 Board transfer unit 26 2nd board transfer robot 28 3rd board transfer robot 30 Control unit 40 Cleaning tank 42 Support shaft 44 Swing arm 46 Fluid nozzle (2 fluid nozzle)
50 Carrier gas supply line 52 Cleaning liquid supply line 54 Motor 60 Pencil type cleaning tool 62 Rinse liquid supply nozzle 64 Chemical solution supply nozzle 70 Chuck 71 Pedestal 72 Stage 73 Support shaft 74 Discharge hole 75 Fixed cover 80 Casing 81 Ventilation plate 82 Board transfer area 83 Board transfer area 84 Blower unit 85 Gas inlet 86 Gas outlet 87 Gas supply line 88 Gas supply port 89 Valve 90 Ultrasonic cleaner W board

Claims (10)

A board holding mechanism that holds the board and
A substrate rotation mechanism for rotating the substrate held by the substrate holding mechanism,
A two-fluid nozzle that ejects a two-fluid jet containing a carrier gas toward the surface of the substrate.
A cover arranged around the substrate and
A cover rotation mechanism that rotates the cover,
A discharge hole for discharging the cleaning liquid supplied from the two-fluid nozzle together with the gas containing the carrier gas, and a discharge hole.
With
The cover rotation mechanism rotates the cover in the same rotation direction as the substrate.
A substrate cleaning device characterized in that the amount of exhaust air from the discharge hole is controlled so that the amount of air supply is lower than the amount of exhaust air. The substrate cleaning device according to claim 1, wherein the cover rotation mechanism rotates the cover at the same angular velocity as the substrate. The radial distance A between the outer edge of the substrate and the tip of the cover is set in the range of 2 mm to 80 mm.
The distance B in the height direction between the substrate and the tip of the cover is set in the range of 3 mm to 50 mm.
The substrate cleaning device according to claim 1 or 2 , wherein the radial distance C between the outer end of the substrate and the inner peripheral surface of the cover is set in the range of 2 mm to 80 mm. The radial distance A between the outer edge of the substrate and the tip of the cover is set to 2 mm.
The distance B in the height direction between the substrate and the tip of the cover is set to 15 mm.
The substrate cleaning device according to claim 3 , wherein the radial distance C between the outer end of the substrate and the inner peripheral surface of the cover is set to 19 mm. The substrate cleaning device according to claim 1, wherein the two-fluid nozzle is provided at an angle of a predetermined angle so as to eject the two-fluid jet toward the upstream side in the rotation direction of the substrate. A board holding mechanism that holds the board and
A substrate rotation mechanism for rotating the substrate held by the substrate holding mechanism,
A two-fluid nozzle that ejects a two-fluid jet containing a carrier gas toward the surface of the substrate.
A cover arranged around the substrate and
A cover rotation mechanism that rotates the cover,
With
The cover rotation mechanism is a substrate cleaning device that rotates the cover in the same rotation direction as the substrate.
The substrate cleaning device is
A casing accommodating the substrate cleaning device and
A pair of gas inlets provided on the wall surface of the casing and allowing gas to flow into the casing.
A gas discharge port provided in the lower part of the casing and discharging a gas containing a carrier gas supplied into the casing from the two-fluid nozzle, and a gas discharge port.
With
A substrate cleaning device characterized in that the pair of gas inlets are provided on the opposite wall surfaces of the casing and are arranged at a position higher than the substrate. Substrate transfer areas are provided adjacent to each other on the upstream side and the downstream side of the substrate cleaning device.
The substrate cleaning device according to claim 6 , wherein the gas inlet introduces a gas blown from a blowing unit in the substrate transport area into the casing. The substrate cleaning device according to claim 6 , wherein a gas supply line for supplying the gas is connected to the gas inlet. The substrate cleaning device according to any one of claims 1 to 8, wherein the two-fluid nozzle is composed of a conductive member. A board holding mechanism that holds the board and
A substrate rotation mechanism for rotating the substrate held by the substrate holding mechanism,
A two-fluid nozzle that ejects a two-fluid jet toward the surface of the substrate,
A cover arranged around the substrate and
A cover rotation mechanism that rotates the cover,
With
The cover rotation mechanism is a substrate cleaning device that rotates the cover in the same rotation direction as the substrate.
The substrate cleaning device is
When the two-fluid jet is supplied to the surface of the substrate, the chemical solution supply nozzle for supplying the conductive chemical solution to the same surface as the surface of the substrate to which the two-fluid jet is supplied is provided. Substrate cleaning device.

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