KR20160017779A - Substrate treating apparatus and substrate transporting method - Google Patents

Abstract

Provided is a substrate treating apparatus. According to an embodiment of the present invention, the substrate treating apparatus comprises: a treating module which treats a substrate; a load port which loads a carrier storing a plurality of substrates; and an index module which is arranged between the treating module and the load port, and transfers the substrate between the carrier loaded on the load port and the treating module, wherein the index module comprises: a frame; an index robot which is arranged in the frame and transfers the substrate; a guide rail which guides a movement of the index robot in the frame; and a fan unit which discharges particles in the frame to the outside.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a substrate processing apparatus,

The present invention relates to a substrate processing apparatus and a substrate transfer method using the same.

A photo-lithography process in a semiconductor manufacturing process is a process of forming a desired pattern on a wafer. The photolithography process is usually carried out at a spinner local facility where exposure equipment is connected and the application process, the exposure process, and the development process are successively processed. The spinner apparatus sequentially or selectively performs a HMDS (hexamethyl disilazane) process, a coating process, a baking process, and a developing process. Here, the HMDS process is a process of supplying a chemical (hereinafter referred to as an 'adhesive agent') for increasing the coating efficiency of a photoresist (PR: photo-resist) onto a wafer, Or to heat and cool the wafer so that the temperature of the wafer is adjusted to a predetermined temperature.

In a substrate processing apparatus for processing a semiconductor substrate for manufacturing such a semiconductor device, in the case of a transfer robot moving in one direction and moving the substrate, an inner flow is compressed in both edge regions to form an upflow in which the airflow rises upward. This causes an internal airflow change and can cause particles on the substrate.

The present invention is intended to reduce the occurrence of process defects due to the particles generated during the transfer of the substrate.

The problems to be solved by the present invention are not limited to the above-mentioned problems, and the problems not mentioned can be clearly understood by those skilled in the art from the present specification and the accompanying drawings will be.

The present invention provides a substrate processing apparatus.

A substrate processing apparatus according to an embodiment of the present invention includes: a processing module for processing a substrate; a load port for loading a carrier for accommodating a plurality of substrates; a processing unit disposed between the processing module and the load port, And an index module for transferring the substrate between the loaded carrier and the processing module, wherein the index module comprises: a frame; an index robot disposed in the frame and carrying the substrate; A guide rail, and a fan unit for discharging the inner particles of the frame to the outside.

Wherein the load port, the index module, and the processing module are sequentially provided along a first direction, the guide rail is provided along a second direction perpendicular to the first direction when viewed from above, May include a plurality of fans disposed along the second direction.

The fan unit may include a pair of fans disposed at both end sides of the guide rail.

The fan unit may include a pair of fans disposed at both lower ends of the guide rail.

The index module may further include a sensor for recognizing a position of the index robot on the guide rail.

The sensor may be disposed in an edge region of the guide rail.

The index module may further include a controller for controlling the index module, and the controller may control the exhaust speed of the fan by measuring the position of the index robot on the guide rail with the sensor.

Wherein the controller controls the fan at a first speed when the index robot is located at a central region on the guide rail and controls the fan to move at a first speed when the index robot is positioned at an edge area on the guide rail, The first speed may be slower than the second speed.

According to an embodiment of the present invention, it is possible to provide a substrate processing apparatus capable of preventing process defects from being generated due to particles generated during a process of transferring a substrate.

The effects of the present invention are not limited to the above-described effects, and the effects not mentioned can be clearly understood by those skilled in the art from the present specification and the accompanying drawings.

1 is a schematic view of a substrate processing apparatus according to an embodiment of the present invention.
FIG. 2 is a view of the substrate processing apparatus 1 of FIG. 1 viewed from the direction AA.
FIG. 3 is a view of the substrate processing apparatus 1 of FIG. 1 viewed from the BB direction.
Figure 4 is a side view of the index module of Figure 1;
5 is a view showing the index module of FIG.
6 is a view showing an index module according to another embodiment.
7 and 8 are views showing the controller controlling the fan unit.
FIG. 9 is a view showing the transport chamber of FIG. 1; FIG.
Fig. 10 is a side view of the transport chamber of Fig. 9; Fig.
11 is a view showing a transport chamber according to another embodiment.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiments of the present invention can be modified in various forms, and the scope of the present invention should not be construed as being limited to the following embodiments. This embodiment is provided to more fully describe the present invention to those skilled in the art. Thus, the shape of the elements in the figures has been exaggerated to emphasize a clearer description.

The facility of this embodiment is used to perform a photolithography process on a substrate such as a semiconductor wafer or a flat panel display panel. In particular, the facilities of this embodiment are used to perform a coating process and a developing process on a substrate. Hereinafter, a case where a wafer is used as a substrate will be described as an example.

1 to 3 are schematic views showing a substrate processing apparatus 1 according to an embodiment of the present invention. Fig. 1 is a view of the substrate processing apparatus 1 viewed from above, Fig. 2 is a view of the facility 1 of Fig. 1 viewed from the AA direction, Fig. 3 is a cross- Fig.

1 to 3, the substrate processing apparatus 1 includes a load port 100, an index module 200, a buffer module 300, a coating and developing module 400, an interface module 700, Module 800. < / RTI > The load port 100, the index module 200, the buffer module 300, the application and development module 400, and the interface module 700 are sequentially arranged in one direction in one direction. The purge module 800 may be provided in the interface module 700. The fuzzy module 800 may be provided at various positions such as a position where the exposure device at the rear end of the interface module 700 is connected or a side of the interface module 700. [

Hereinafter, the direction in which the load port 100, the index module 200, the buffer module 300, the application and development module 400, and the interface module 700 are arranged is referred to as a first direction 12. A direction perpendicular to the first direction 12 is referred to as a second direction 14 and a direction perpendicular to the first direction 12 and the second direction 14 is referred to as a third direction 16, Quot;

The wafer W is moved in a state accommodated in the cassette 20. The cassette 20 has a structure that can be sealed from the outside. For example, as the cassette 20, a front open unified pod (FOUP) having a door at the front can be used.

Hereinafter, the load port 100, the index module 200, the buffer module 300, the application and development module 400, the interface module 700, and the fuzzy module 800 will be described.

The load port 100 has a mounting table 120 on which a cassette 20 accommodating wafers W is placed. A plurality of mounts 120 are provided, and the mounts 120 are arranged in a line along the second direction 14. In Fig. 1, four placement tables 120 are provided.

4 is a side view of the index module 200 of FIG. 5 is a view showing the index module 200 of FIG. FIG. 6 is a view showing an index module 200 according to another embodiment. The index module 200 transfers the wafer W between the cassette 20 and the buffer module 300 placed on the table 120 of the load port 100. The index module 200 includes a frame 210, an index robot 220, a guide rail 230, a fan unit 240, a sensor 250, and a controller 260. The frame 210 is provided generally in the shape of an inner rectangular parallelepiped and is disposed between the load port 100 and the buffer module 300. The frame 210 of the index module 200 may be provided at a lower height than the frame 210 of the buffer module 300 described later. A fan filter unit 215 may be provided on the upper part of the frame 210. The index robot 220 and the guide rail 230 are disposed within the frame 210.

The index robot 220 is a four-axis drive system in which the hand 221 directly handling the wafer W is movable in the first direction 12, the second direction 14 and the third direction 16, This is a possible structure. The index robot 220 includes a hand 221, an arm 222, a support 223, and a pedestal 224. The hand 221 is fixed to the arm 222. The arm 222 is provided with a stretchable structure and a rotatable structure. The support base 223 is disposed along the third direction 16 in the longitudinal direction. The arm 222 is coupled to the support 223 to be movable along the support 223. The support 223 is fixedly coupled to the pedestal 224. The guide rails 230 are provided so that their longitudinal direction is arranged along the second direction 14. The pedestal 224 is coupled to the guide rail 230 so as to be linearly movable along the guide rail 230. Further, although not shown, the frame 210 is further provided with a door opener for opening and closing the door of the cassette 20. The guide rail 230 guides the linear movement of the index robot 220. Referring to FIG. 1, the guide rail 230 may be provided along the second direction 14 in the longitudinal direction thereof.

The fan unit 240 is provided in the index module 200. The fan unit 240 can discharge the particles in the frame 210 to the outside. A plurality of fan units 240 may be provided. A plurality of fan units 240 may be provided along the second direction 14. The fan unit 240 may have a pair of fans disposed at both ends of the guide rail 230. The fan unit 240 is provided at both ends of the guide rail 230 so as to prevent an upflow in the area where the internal airflow in the frame 210 is compressed. For example, as shown in FIG. 5, the fan unit 240 may be disposed at both end sides of the guide rail 230. Alternatively, as shown in FIG. 6, the fan unit 240 may be disposed at both lower ends of the guide rail 230. Alternatively, the fan may be provided in another area.

The sensor 250 measures the position of the index robot 220 on the guide rail 230. The sensor 250 may be disposed in an edge region of the guide rail 230. For example, the sensor 250 may be provided at both ends of the guide rail 230. A plurality of sensors 250 may be provided. Further, the sensors 250 are provided as a pair, and can function as a light receiving unit and a light emitting unit. Alternatively, the plurality of sensors 250 may be provided on the guide rail 230 at equal intervals. The sensor 250 transmits the position information of the index robot 220 to the controller 260.

FIGS. 7 and 8 are views showing the controller 260 controlling the fan unit 240. FIG. The controller 260 controls the index module 200. In one example, the controller 260 controls the rotation speed and / or rotation timing of the fan unit 240 and the like. The controller 260 receives the position information of the index robot 220 from the sensor 250 and thereby controls the exhaust speed of the fan. For example, as shown in FIG. 7, when the index robot 220 is positioned in the central region of the guide rail 230, the fan unit 240 is controlled to the first speed v1. 8, when the index robot 220 is positioned at the edge region of the guide rail 230, the fan unit 240 is controlled to the second speed v2. The second speed v2 is provided different from the first speed v1. In one example, the first speed v1 is slower than the second speed v2. The controller 260 controls the speed of the fan unit 240 to be faster when the index robot 220 is positioned at the edge region of the guide rail 230, Can be suppressed. Therefore, it is possible to prevent the up-flow of the edge region in the frame 210 and to prevent the generation of the particles. The controller 260 can gradually control the speed of the index robot 220 according to the position of the index robot 220 on the guide rail 230. [

The buffer module 300 includes a frame 210, a first buffer 320, a second buffer 330, a cooling chamber 350, and a first buffer robot 360. The frame 210 is provided in the shape of an inner rectangular parallelepiped and is disposed between the index module 200 and the application and development module 400. The first buffer 320, the second buffer 330, the cooling chamber 350, and the first buffer robot 360 are located in the frame 210. The cooling chamber 350, the second buffer 330, and the first buffer 320 are sequentially disposed in the third direction 16 from below. The second buffer 330 and the cooling chamber 350 are located at a height corresponding to the coating module 401 of the coating and developing module 400 described later and the coating and developing module 400 at a height corresponding to the developing module 402. [ The first buffer robot 360 is spaced apart from the second buffer 330, the cooling chamber 350 and the first buffer 320 by a predetermined distance in the second direction 14.

The first buffer 320 and the second buffer 330 temporarily store a plurality of wafers W, respectively. The second buffer 330 has a housing 331 and a plurality of supports 332. The supports 332 are disposed within the housing 331 and are provided spaced apart from each other in the third direction 16. One wafer W is placed on each support 332. The housing 331 includes a housing 331 and an index robot 220. The housing 331 supports the index robot 220 and the first buffer robot 360 in a direction in which the index robot 220 is provided so that the index robot 220 and the first buffer robot 360 can carry the wafers W into / 1 buffer robot 360 has an opening (not shown) in the direction in which it is provided. The first buffer 320 has a structure substantially similar to that of the second buffer 330. The housing 321 of the first buffer 320 has an opening in a direction in which the first buffer robot 360 is provided and a direction in which the transport robot 432 located in the application module 401 is provided. The number of supports 322 provided in the first buffer 320 and the number of supports 332 provided in the second buffer 330 may be the same or different. According to one example, the number of supports 332 provided in the second buffer 330 may be greater than the number of supports 322 provided in the first buffer 320.

The first buffer robot 360 transfers the wafer W between the first buffer 320 and the second buffer 330. The first buffer robot 360 includes a hand 361, an arm 362, and a support 363. The hand 361 is fixed to the arm 362. The arm 362 is provided in a stretchable configuration so that the hand 361 is movable along the second direction 14. The arm 362 is coupled to the support 363 so as to be linearly movable along the support 363 in the third direction 16. The support base 363 has a length extending from a position corresponding to the second buffer 330 to a position corresponding to the first buffer 320. The support 363 may be provided longer in the upper or lower direction. The first buffer robot 360 may be provided such that the hand 361 is driven only in two directions along the second direction 14 and the third direction 16.

The cooling chambers 350 cool the wafers W, respectively. The cooling chamber 350 includes a housing 351 and a cooling plate 352. The cooling plate 352 has an upper surface on which the wafer W is placed and a cooling means 353 for cooling the wafer W. [ As the cooling means 353, various methods such as cooling with cooling water and cooling using a thermoelectric element can be used. In addition, the cooling chamber 350 may be provided with a lift pin assembly for positioning the wafer W on the cooling plate 352. The housing 351 is provided with the index robot 220 and the developing unit 402. The housing 351 is provided with the index robot 220, The robot has an opening in the direction provided. Further, the cooling chamber 350 may be provided with doors for opening and closing the above-described opening.

The application module 401 includes a step of applying a photosensitive liquid such as a photoresist to the wafer W and a heat treatment step such as heating and cooling for the wafer W before and after the resist application step. The application module 401 has a resist application chamber 410, a heat treatment chamber 500, a bake chamber 420, and a transfer chamber 430. The resist application chamber 410, the heat treatment chamber 500, the bake chamber 420, and the transfer chamber 430 are sequentially disposed along the second direction 14. [ A plurality of resist coating chambers 410 are provided, and a plurality of resist coating chambers 410 are provided in the first direction 12 and the third direction 16, respectively. A plurality of bake chambers 420 are provided in the first direction 12 and the third direction 16, respectively.

9 is a view showing the delivery chamber 430. Fig. FIG. 10 is a side view of the transfer chamber 430 of FIG. 11 is a view showing a delivery chamber 430 according to another embodiment. The transfer chamber 430 is positioned in parallel with the first buffer 320 of the first buffer module 300 in the first direction 12. The transfer chamber 430 has a frame 431, a transfer robot 432, a guide rail 438, a fan unit 440, a sensor 450, and a controller 460. The frame 431 has a generally rectangular shape. The transfer robot 432 transfers the wafer W between the bake chambers 420, the resist application chambers 410 and the first buffer 320 of the first buffer module 300. The guide rails 438 are arranged so that their longitudinal directions are parallel to the first direction 12. The guide rail 438 guides the transport robot 432 to move linearly in the first direction 12. The transfer robot 432, the guide rail 438, the fan unit 440, the sensor 450 and the controller 460 of the transfer chamber 430 are connected to the index robot 200 of the index module 200, 230, the fan unit 240, the sensor 250, and the controller 260, respectively. Hereinafter, a duplicate description will be omitted.

The resist coating chambers 410 all have the same structure. However, the types of the photoresist used in each of the resist coating chambers 410 may be different from each other. As an example, a chemical amplification resist may be used as the photoresist. The resist coating chamber 410 applies a photoresist on the wafer W. [ The resist coating chamber 410 has a housing 411, a support plate 412, and a nozzle 413. The housing 411 has a cup shape with an open top. The support plate 412 is located in the housing 411 and supports the wafer W. [ The support plate 412 is rotatably provided. The nozzle 413 supplies the photoresist onto the wafer W placed on the support plate 412. The nozzle 413 has a circular tube shape and can supply photoresist to the center of the wafer W. [ Alternatively, the nozzle 413 may have a length corresponding to the diameter of the wafer W, and the discharge port of the nozzle 413 may be provided as a slit. In addition, the resist coating chamber 410 may further be provided with a nozzle 414 for supplying a cleaning liquid such as deionized water to clean the surface of the wafer W coated with the photoresist.

The heat treatment chamber 500 supplies liquid to the upper surface of the substrate. For example, the liquid may be a cohesive agent. In the present embodiment, the heat treatment chamber 500 provides an example having a heating means. Alternatively, the heat treatment chamber 500 may be provided with a cooling plate or a heating plate. The cooling plate is provided with a cooling means such as a cooling water or a thermoelectric element. The heating plate may also be provided with a heating means such as a hot wire or a thermoelectric element. The cooling plate and the heating plate may be provided in a single heat treatment chamber 500, respectively. Alternatively, some of the heat treatment chambers 500 may have only a cooling plate, and the other portion may have only a heating plate.

The bake chamber 420 heat-treats the wafer W. For example, the bake chambers 420 may be formed by a prebake process in which the wafer W is heated to a predetermined temperature to remove organic matter and moisture on the surface of the wafer W before the photoresist is applied, A soft bake process is performed after coating the wafer W on the wafer W, and a cooling process for cooling the wafer W after each heating process is performed. The bake chamber 420 has a cooling plate 421 or a heating plate 422. The cooling plate 421 is provided with a cooling means 423 such as a cooling water or a thermoelectric element. The heating plate 422 is also provided with a heating means 424, such as a hot wire or a thermoelectric element. Some of the bake chambers 420 may include only the cooling plate 421 and the other portion may include only the heating plate 422. [ Alternatively, the cooling plate 421 and the heating plate 422 may be provided in a single bake chamber 420, respectively.

The developing module 402 includes a developing process of supplying a developing solution to obtain a pattern on the wafer W to remove a part of the photoresist and a heat treatment process such as heating and cooling performed on the wafer W before and after the developing process . The development module 402 has a development chamber 460, a bake chamber 470, and a transfer chamber 480. The development chamber 460, the bake chamber 470, and the transfer chamber 480 are sequentially disposed along the second direction 14. The development chamber 460 and the bake chamber 470 are positioned apart from each other in the second direction 14 with the transfer chamber 480 therebetween. A plurality of developing chambers 460 are provided, and a plurality of developing chambers 460 are provided in the first direction 12 and the third direction 16, respectively.

The transfer chamber 480 is positioned in parallel with the second buffer 330 of the first buffer module 300 in the first direction 12. In the transfer chamber 480, the transfer robot 482 and the guide rail 483 are located. The transfer chamber 430 has a frame 481, a transfer robot 482, a guide rail 488, a fan unit 492, a sensor 494, and a controller 496. The frame 481 has a generally rectangular shape. The transfer robot 482 transfers the wafer W between the bake chambers 470, the development chambers 460 and the second buffer 330 of the first buffer module 300 and the cooling chamber 350. The guide rail 483 is arranged such that its longitudinal direction is parallel to the first direction 12. The guide rail 483 guides the transport robot 482 to move linearly in the first direction 12. Each of the conveying robot 482, the guide rail 488, the fan unit 492, the sensor 494 and the controller 496 of the developing module 402 has the conveying robot 432 of the coating module 401, The fan unit 440, the sensor 450, and the controller 460, respectively. Hereinafter, a duplicate description will be omitted.

The development chambers 460 all have the same structure. However, the types of developers used in the respective developing chambers 460 may be different from each other. The development chamber 460 removes a region of the photoresist on the wafer W irradiated with light. At this time, the area of the protective film irradiated with the light is also removed. Depending on the type of selectively used photoresist, only the areas of the photoresist and protective film that are not irradiated with light can be removed.

The development chamber 460 has a housing 461, a support plate 462, and a nozzle 463. The housing 461 has a cup shape with an open top. The support plate 462 is placed in the housing 461 and supports the wafer W. [ The support plate 462 is rotatably provided. The nozzle 463 supplies the developer onto the wafer W placed on the support plate 462. The nozzle 463 has a circular tube shape and can supply developer to the center of the wafer W. [ Alternatively, the nozzle 463 may have a length corresponding to the diameter of the wafer W, and the discharge port of the nozzle 463 may be provided as a slit. Further, the developing chamber 460 may further be provided with a nozzle 464 for supplying a cleaning liquid such as deionized water to clean the surface of the wafer W to which the developer is supplied.

The bake chamber 470 heat-treats the wafer W. For example, the bake chambers 470 may include a post-bake process for heating the wafer W before the development process is performed, a hard bake process for heating the wafer W after the development process is performed, And a cooling step for cooling the wafer. The bake chamber 470 has a cooling plate 471 or a heating plate 472. The cooling plate 471 is provided with a cooling means 473 such as a cooling water or a thermoelectric element. Or the heating plate 472 is provided with a heating means 474 such as a hot wire or a thermoelectric element. Some of the bake chambers 470 may include only the cooling plate 471 and the other portion may include only the heating plate 472. [ Alternatively, the cooling plate 471 and the heating plate 472 may be provided in a single bake chamber 470, respectively.

As described above, in the application and development module 400, the application module 401 and the development module 402 are provided to be separated from each other. In addition, the application module 401 and the development module 402 may have the same chamber arrangement as viewed from above.

The interface module 700 transfers the wafer W. The interface module 700 includes a frame 710, a first buffer 720, a second buffer 730, and an interface robot 740. The first buffer 720, the second buffer 730, and the interface robot 740 are located within the frame 710. The first buffer 720 and the second buffer 730 are spaced apart from each other by a predetermined distance and are stacked on each other. The first buffer 720 is disposed higher than the second buffer 730.

The interface robot 740 is spaced apart from the first buffer 720 and the second buffer 730 in the second direction 14. The interface robot 740 carries the wafer W between the first buffer 720, the second buffer 730 and the exposure apparatus 900.

The first buffer 720 temporarily stores the processed wafers W before they are transferred to the exposure apparatus 900. The second buffer 730 temporarily stores the processed wafers W in the exposure apparatus 900 before they are moved. The first buffer 720 has a housing 721 and a plurality of supports 722. The supports 722 are disposed within the housing 721 and are provided spaced apart from each other in the third direction 16. One wafer W is placed on each support 722. The housing 721 is movable in the direction in which the interface robot 740 is provided and in the direction in which the interface robot 740 and the preprocessing robot 632 transfer the wafer W to and from the support table 722, 632 are provided with openings in the direction in which they are provided. The second buffer 730 has a structure similar to that of the first buffer 720. The interface module may be provided with only buffers and robots as described above without providing a chamber to perform a predetermined process on the wafer.

The substrate processing apparatus of the above-described example has been described by taking the index robot in the index module as an example. Alternatively, however, the substrate transporting method and the substrate processing apparatus according to the embodiment of the present invention can be applied to all other transporting apparatuses that are provided along one direction in the longitudinal direction thereof and move along one direction to transport the substrate. For example, the substrate processing apparatus may correspond to a transport module. Optionally, the substrate processing apparatus may correspond to an interface module.

The foregoing detailed description is illustrative of the present invention. In addition, the foregoing is intended to illustrate and explain the preferred embodiments of the present invention, and the present invention may be used in various other combinations, modifications, and environments. That is, it is possible to make changes or modifications within the scope of the concept of the invention disclosed in this specification, within the scope of the disclosure, and / or within the skill and knowledge of the art. The embodiments described herein are intended to illustrate the best mode for implementing the technical idea of the present invention and various modifications required for specific applications and uses of the present invention are also possible. Accordingly, the detailed description of the invention is not intended to limit the invention to the disclosed embodiments. It is also to be understood that the appended claims are intended to cover such other embodiments.

20: cassette 100: load port
200: Index module 210: Frame
220: index robot 230: guide rail
240: fan unit 250: sensor
260: controller 300: buffer module
400: application and development module 401: application module
402: developing module 500: heat treatment chamber
600: gas supply unit 700: interface module

Claims (16)

A processing module for processing the substrate;
A load port for loading a carrier for accommodating a plurality of substrates;
And an index module disposed between the processing module and the load port and transferring the substrate between the processing module and the carrier loaded in the load port,
The index module comprises:
frame;
An index robot disposed in the frame and transferring the substrate;
A guide rail for guiding movement of the index robot within the frame; And
And a fan unit for discharging the inner particles of the frame to the outside. The method according to claim 1,
Wherein the load port, the index module, and the processing module are sequentially provided along a first direction, the guide rail is provided along a second direction perpendicular to the first direction when viewed from above,
Wherein the fan unit includes a plurality of fans disposed along the second direction. 3. The method of claim 2,
Wherein the fan unit includes a pair of fans disposed at both ends of the guide rail. The method of claim 3,
Wherein the fan unit includes a pair of fans disposed on both side ends of the guide rail. 5. The method of claim 4,
Wherein the index module further comprises a sensor for recognizing the position of the index robot on the guide rail. 6. The method of claim 5,
Wherein the sensor is disposed in an edge region of the guide rail. The method according to claim 6,
Wherein the index module further comprises a controller for controlling the index module,
Wherein the controller measures the position of the index robot on the guide rail with the sensor to control an exhaust speed of the fan. 8. The method of claim 7,
Wherein the controller controls the fan at a first speed when the index robot is located in a central region on the guide rail and when the index robot is positioned at an edge area on the guide rail, Wherein the first speed is a slower speed than the second speed. A processing module for processing the substrate;
A load port for loading a carrier for accommodating a plurality of substrates;
And an index module disposed between the processing module and the load port,
The processing module comprises:
A first chamber provided on one side and performing a first process on the substrate;
A second chamber provided on the other side and performing a second process on the substrate different from the first process;
And a transfer chamber disposed between the first chamber and the second chamber for transferring the substrate between the first chamber and the second chamber,
The transfer chamber
frame;
A transport robot disposed in the frame and transporting the substrate;
A guide rail for guiding movement of the carrying robot in the frame; And
And a fan unit for discharging the inner particles of the frame to the outside. 10. The method of claim 9,
Wherein the load port, the index module, and the processing module are sequentially provided along a first direction, the first chamber, the transfer chamber, and the second chamber are perpendicular to the first direction when viewed from above And is provided along a second direction,
Wherein the guide rail is provided along the first direction, and the fan unit includes a plurality of fans disposed along the first direction. 11. The method of claim 10,
Wherein the fan unit includes a pair of fans disposed at both ends of the guide rail. 12. The method of claim 11,
The transfer chamber
A sensor for recognizing a position of the carrying robot on the guide rail;
Further comprising a controller for controlling said transfer chamber,
Wherein the controller measures the position of the carrying robot on the guide rail with the sensor to control the exhaust speed of the fan. 13. The method of claim 12,
Wherein the controller controls the fan at a first speed when the carrying robot is located at a central area on the guide rail and controls the fan to move at a first speed when the carrying robot is positioned at an edge area on the guide rail, Wherein the first speed is a slower speed than the second speed. A substrate transporting unit for transporting a substrate by using a transfer robot in a transport module provided along a longitudinal direction of the substrate transporting unit and for controlling the speed of a fan disposed in the transporting module in accordance with the position of the transporting robot along the one direction, Way. 15. The method of claim 14,
And the fan is disposed at both ends of the transfer module. 16. The method of claim 15,
And controls the fan at a first speed when the transfer robot is positioned at a central region on the transfer module and controls the fan to rotate at a second speed different from the first speed when the transfer robot is positioned at an edge area on the transfer module Wherein the first velocity is slower than the second velocity.

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