KR20210054647A - Apparatus and Method for treating substrate - Google Patents

Abstract

The present invention provides an apparatus for processing a substrate, capable of improving the cooling efficiency when cooling a heating unit. According to one embodiment of the present invention, the apparatus for processing a substrate includes: a housing formed therein with a processing space; a support plate for supporting a substrate and including a support unit for supporting the substrate in the processing space; a heater member provided on the support plate to heat the substrate; a cooling plate including a cooling unit provided under the heater member for forcibly cooling the support plate, wherein the cooling unit is spaced apart from the heater member; and a nozzle provided on the cooling plate for supplying gas to the bottom surface of the heater member, wherein the nozzle is rotatably provided.

Description

Substrate processing apparatus and method {Apparatus and Method for treating substrate}

The present invention relates to an apparatus and method for heat treating a substrate.

In order to manufacture a semiconductor device, various processes such as cleaning, deposition, photographing, etching, and ion implantation are performed. Among these processes, the photography process includes forming a liquid film such as a photoresist on a substrate.

After the liquid film is formed on the substrate, a bake process of heating the substrate is performed. The bake process is performed at a very high temperature compared to room temperature, and for this purpose, a heater for heating the substrate is used.

The chamber performing the bake process heats the substrate at different temperatures depending on the substrate. For example, a preceding substrate is treated at a first temperature, and a subsequent substrate carried into the bake chamber is treated at a second temperature lower than the first temperature. After treating the preceding substrate to the first temperature, in order to treat the subsequent substrate to a second temperature lower than the first temperature, a cooling process of cooling the heater is required.

In general, in the cooling process, cooling gas is supplied toward the heater to cool the heater. When injecting the cooling gas, the flow rate and flow rate of the injected cooling gas affect the cooling efficiency. When spraying the same flow rate, the length of the nozzle supplying the cooling gas must be lengthened to ensure a faster flow rate. In addition, when spraying at the same flow rate, the number of nozzles must be increased in order to secure a large flow rate. In this case, there is a problem that the size of the bake chamber increases.

The present invention is to provide a substrate processing apparatus and a substrate processing method capable of increasing cooling efficiency when cooling a heating unit.

The present invention is to provide a substrate processing apparatus and a substrate processing method capable of securing a flow rate and a flow rate of a cooling gas used for cooling a heater in a bake chamber having a limited size.

The present invention is not limited thereto, and other objects not mentioned will be clearly understood by those skilled in the art from the following description.

The present invention provides an apparatus for processing a substrate. According to an embodiment of the present invention, a substrate processing apparatus includes: a housing providing a processing space therein; And a support unit for supporting the substrate in the processing space, the support unit comprising: a support plate for supporting the substrate; A heater member provided on the support plate to heat the substrate; Further, the cooling unit provided under the heater member and forcibly cooling the support plate, the cooling unit includes: a cooling plate disposed to be spaced apart from the heater member; And it includes a nozzle provided on the cooling plate to supply gas to the bottom surface of the heater member, the nozzle may be provided to be rotatable.

According to an embodiment, the nozzle may include a rotating body.

According to an embodiment, the nozzle may have a rotating body rotatably inserted into the cooling plate on the other side with a discharge port for supplying gas to the bottom surface of the heater member on one side.

According to an embodiment, the rotating body may be provided in a spherical shape.

According to one embodiment, the rotating body may be provided as a ball joint.

According to an embodiment, the rotating body may be provided to be rotated by the pressure of the gas introduced into the rotating body and discharged through the discharge port.

According to an embodiment, the cooling plate has a mounting groove formed on its upper surface, and the nozzle may be disposed in the mounting groove.

According to an embodiment, a plurality of nozzles may be provided along the circumferential direction of the cooling plate.

According to an exemplary embodiment, a plurality of nozzles may be provided to the cooling plate along the circumferential direction of the cooling plate at a first distance from the cooling plate, and the first distance may be provided to face each other between the central region and the edge region of the heater member.

According to an embodiment, a plurality of nozzles are provided to the cooling plate along the circumferential direction of the inner plate at a second distance and a third distance from the center of the cooling plate, and the second distance is positioned to face the central region of the heater member, The third distance may be positioned to face the edge region of the heater member.

Further, the present invention provides a substrate processing method. According to an embodiment, a first heating step of heating the substrate to a first temperature by the support plate; In addition, a cooling step of forcibly cooling the support plate to a predetermined temperature by supplying gas to the support plate is included. In the cooling step, the nozzle may rotate and cool the entire area of the bottom surface of the heater member.

According to an embodiment, after the cooling step, the support plate may further include a second heating step of heating the substrate to a second temperature.

According to an embodiment, the second temperature may be provided lower than the first temperature.

According to the embodiment of the present invention, when cooling the heating unit, it is possible to increase the cooling efficiency.

According to an embodiment of the present invention, it is possible to secure a flow rate and a flow rate of a cooling gas used for cooling a heater in a bake chamber having a limited size.

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

1 is a perspective view schematically showing a substrate processing apparatus according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view of a substrate processing apparatus showing a coating block or a developing block of FIG. 1.
3 is a plan view of the substrate processing apparatus of FIG. 1.
4 is a diagram illustrating an example of a hand of the transfer robot of FIG. 3.
5 is a plan view schematically showing an example of the heat treatment chamber of FIG. 3.
6 is a front view of the heat treatment chamber of FIG. 5.
7 is a cross-sectional view showing the heating device of FIG. 6.
8 to 9 are plan and cross-sectional views, respectively, illustrating the substrate support unit of FIG. 7.
10 is a plan view showing a cooling plate according to an embodiment of the present invention.
11 is a perspective view showing a state of a nozzle according to an embodiment of the present invention.
12 is a diagram illustrating a procedure of a substrate processing method according to an embodiment of the present invention.
13 is a plan view showing a state of a cooling plate according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings. The embodiments of the present invention may be modified in various forms, and the scope of the present invention should not be construed as being limited to the following examples. This embodiment is provided to more completely explain the present invention to those with average knowledge in the art. Therefore, the shape of the element in the drawings is exaggerated to emphasize a clearer description.

Referring to FIGS. 1 to 3, the substrate processing apparatus 1 includes an index module 20, a treating module 30, and an interface module 40. According to an embodiment, the index module 20, the processing module 30, and the interface module 40 are sequentially arranged in a line. Hereinafter, the direction in which the index module 20, the processing module 30, and the interface module 40 are arranged is referred to as a first direction 12, and a direction perpendicular to the first direction 12 when viewed from the top is referred to as The second direction 14 is referred to as, and a direction perpendicular to both the first direction 12 and the second direction 14 is referred to as the third direction 16.

The index module 20 transfers the substrate W from the container 10 in which the substrate W is stored to the processing module 30, and stores the processed substrate W into the container 10. The longitudinal direction of the index module 20 is provided in the second direction 14. The index module 20 has a load port 22 and an index frame 24. The load port 22 is located on the opposite side of the processing module 30 based on the index frame 24. The container 10 in which the substrates W are accommodated is placed on the load port 22. A plurality of load ports 22 may be provided, and a plurality of load ports 22 may be disposed along the second direction 14.

As the container 10, a container 10 for sealing such as a front open unified pod (FOUP) may be used. The container 10 may be placed on the load port 22 by an operator or a transport means (not shown) such as an overhead transfer, an overhead conveyor, or an automatic guided vehicle. I can.

An index robot 2200 is provided inside the index frame 24. In the index frame 24, a guide rail 2300 in which the longitudinal direction is provided in the second direction 14 may be provided, and the index robot 2200 may be provided to be movable on the guide rail 2300. The index robot 2200 includes a hand 2220 on which the substrate W is placed, and the hand 2220 moves forward and backward, rotates about the third direction 16, and rotates the third direction 16. It may be provided to be movable along the way.

The processing module 30 performs a coating process and a developing process on the substrate W. The processing module 30 has a coating block 30a and a developing block 30b. The coating block 30a performs a coating process on the substrate W, and the developing block 30b performs a development process on the substrate W. A plurality of coating blocks 30a are provided, and they are provided to be stacked on each other. A plurality of developing blocks 30b are provided, and the developing blocks 30b are provided to be stacked on each other. According to the embodiment of Fig. 2, two coating blocks 30a are provided, and two developing blocks 30b are provided. The coating blocks 30a may be disposed under the developing blocks 30b. According to an example, the two coating blocks 30a perform the same process with each other, and may be provided with the same structure. In addition, the two developing blocks 30b perform the same process with each other, and may be provided with the same structure.

Referring to FIG. 4, the coating block 30a includes a heat treatment chamber 3200, a transfer chamber 3400, a liquid processing chamber 3600, and a buffer chamber 3800. The heat treatment chamber 3200 performs a heat treatment process on the substrate W. The heat treatment process may include a cooling process and a heating process. The liquid processing chamber 3600 supplies a liquid onto the substrate W to form a liquid film. The liquid film may be a photoresist film or an antireflection film. The transfer chamber 3400 transfers the substrate W between the heat treatment chamber 3200 and the liquid processing chamber 3600 within the coating block 30a.

The conveying chamber 3400 is provided in its longitudinal direction parallel to the first direction 12. A transfer robot 3422 is provided in the transfer chamber 3400. The transfer robot 3422 transfers the substrate between the heat treatment chamber 3200, the liquid treatment chamber 3600, and the buffer chamber 3800. According to an example, the transfer robot 3422 has a hand 3420 on which the substrate W is placed, and the hand 3420 moves forward and backward, a rotation about the third direction 16, and a third direction. It may be provided to be movable along (16). In the transfer chamber 3400, a guide rail 3300 whose longitudinal direction is provided in parallel with the first direction 12 may be provided, and the transfer robot 3422 may be provided to be movable on the guide rail 3300. .

4 is a diagram illustrating an example of a hand of the transfer robot of FIG. 3. 4, the hand 3420 has a base 3428 and a support protrusion 3429. The base 3428 may have an annular ring shape in which a part of the circumference is bent. The base 3428 has an inner diameter larger than the diameter of the substrate W. The support protrusion 3429 extends inwardly from the base 3428. A plurality of support protrusions 3429 are provided and support an edge region of the substrate W. According to an example, the support protrusions 3429 may be provided with four at equal intervals.

The heat treatment chamber 3200 is provided in plural. 3 and 4, the heat treatment chambers 3200 are arranged to be arranged along the first direction 12. The heat treatment chambers 3200 are located on one side of the transfer chamber 3400.

5 is a plan view schematically showing an example of the heat treatment chamber of FIG. 3, and FIG. 6 is a front view of the heat treatment chamber of FIG. 5. The heat treatment chamber 3200 has a housing 3210, a cooling device 3220, a heating device 3230, and a conveying plate 3240.

The housing 3210 is generally provided in the shape of a rectangular parallelepiped. A carry-in port (not shown) through which the substrate W enters and exits is formed on the sidewall of the housing 3210. The entrance can be kept open. A door (not shown) may be provided to selectively open and close the entrance. The cooling device 3220, the heating device 3230, and the conveying plate 3240 are provided in the housing 3210. The cooling device 3220 and the heating device 3230 are provided side by side along the second direction 14. According to an example, the cooling device 3220 may be located closer to the conveying chamber 3400 than the heating device 3230.

The cooling device 3220 has a cooling plate 3222. The cooling plate 3222 may have a generally circular shape when viewed from the top. A cooling member 3224 is provided on the cooling plate 3222. According to an example, the cooling member 3224 is formed inside the cooling plate 3222 and may be provided as a flow path through which the cooling fluid flows.

The heating device 3230 is provided as a heating unit 1000 that heats the substrate to a temperature higher than room temperature. The heating device 3230 heats the substrate W in an atmosphere of atmospheric pressure or a lower pressure.

The transfer plate 3240 has a generally disk shape and has a diameter corresponding to the substrate W. A notch 3244 is formed at the edge of the transfer plate 3240. The notch 3244 may have a shape corresponding to the protrusion 3429 formed on the hand 3420 of the transfer robot 3422 and 3424 described above.

In addition, the notch 3244 is provided in a number corresponding to the protrusion 3429 formed in the hand 3420 and is formed at a position corresponding to the protrusion 3429. When the vertical position of the hand 3420 and the transfer plate 3240 is changed in the position where the hand 3420 and the transfer plate 3240 are aligned in the vertical direction, the substrate W between the hand 3420 and the transfer plate 3240 is changed. Delivery takes place. The transfer plate 3240 is mounted on the guide rail 3249 and may be moved between the first area 3212 and the second area 3214 along the guide rail 3249 by a driver 3246.

The transfer plate 3240 is provided with a plurality of slit-shaped guide grooves 3242. The guide groove 3242 extends from the end of the transfer plate 3240 to the inside of the transfer plate 3240. The guide groove 3242 is provided along the second direction 14 in its longitudinal direction, and the guide grooves 3242 are positioned to be spaced apart from each other along the first direction 12. The guide groove 3242 prevents the transfer plate 3240 and the lift pin 1340 from interfering with each other when the transfer of the substrate W is made between the transfer plate 3240 and the heating device 3230.

The substrate W is heated while the substrate W is directly placed on the support plate 1320, and the substrate W is cooled by the transfer plate 3240 on which the substrate W is placed. It is made in the state of being in contact with. The transfer plate 3240 is made of a material having a high heat transfer rate so that heat transfer between the cooling plate 3222 and the substrate W is well performed. According to an example, the transfer plate 3240 may be made of a metal material.

The heating apparatus 3230 provided in some of the heat treatment chambers 3200 may supply a gas while heating the substrate W to improve the adhesion rate of the photoresist to the substrate W. According to an example, the gas may be hexamethyldisilane gas.

The liquid processing chamber 3600 is provided in plural. Some of the liquid treatment chambers 3600 may be provided to be stacked on each other. The liquid processing chambers 3600 are disposed on one side of the transfer chamber 3402. The liquid processing chambers 3600 are arranged side by side along the first direction 12. Some of the liquid processing chambers 3600 are provided at positions adjacent to the index module 20. Hereinafter, these liquid treatment chambers are referred to as a front liquid treatment chamber 3602 (front liquid treating chamber). Other portions of the liquid processing chambers 3600 are provided at positions adjacent to the interface module 40. Hereinafter, these liquid treatment chambers are referred to as rear heat treating chambers 3604.

The front liquid treatment chamber 3602 applies the first liquid onto the substrate W, and the rear liquid treatment chamber 3604 applies the second liquid onto the substrate W. The first liquid and the second liquid may be different types of liquids. According to an embodiment, the first liquid is an antireflection film, and the second liquid is a photoresist. The photoresist may be applied on the substrate W on which the antireflection film is applied. Optionally, the first liquid may be a photoresist, and the second liquid may be an antireflection film. In this case, the antireflection film may be applied on the substrate W on which the photoresist is applied. Optionally, the first liquid and the second liquid are of the same type, and they may both be photoresists.

7 is a cross-sectional view showing the heating device of FIG. 6. Referring to FIG. 7, the heating unit 1000 includes a housing 1100, a support unit 1300, and an exhaust unit 1500.

The housing 1100 provides a processing space 1110 for heating the substrate W therein. The processing space 1110 is provided as a space blocked from the outside. The housing 1100 includes an upper body 1120, a lower body 1140, and a sealing member 1160.

The upper body 1120 is provided in a cylindrical shape with an open lower part. An exhaust hole 1122 and an inlet hole 1124 are formed on the upper surface of the upper body 1120. The exhaust hole 1122 is formed in the center of the upper body 1120. The exhaust hole 1122 exhausts the atmosphere of the processing space 1110. A plurality of inlet holes 1124 are provided so as to be spaced apart, and are arranged to surround the exhaust hole 1122. The inlet holes 1124 introduce external airflow into the processing space 1110. According to an example, there are four inlet holes 1124, and the external airflow may be air.

Optionally, three or five or more inlet holes 1124 may be provided, or outside air may be an inert gas.

The lower body 1140 is provided in a cylindrical shape with an open top. The lower body 1140 is located under the upper body 1120. The upper body 1120 and the lower body 1140 are positioned to face each other in the vertical direction. The upper body 1120 and the lower body 1140 are combined with each other to form a processing space 1110 therein. The upper body 1120 and the lower body 1140 are positioned so that their central axes coincide with each other in the vertical direction. The lower body 1140 may have the same diameter as the upper body 1120. That is, the upper end of the lower body 1140 may be positioned to face the lower end of the upper body 1120.

One of the upper body 1120 and the lower body 1140 is moved to the open position and the blocked position by the elevating member 1130, and the other position is fixed. In this embodiment, it will be described that the position of the lower body 1140 is fixed and the upper body 1120 is moved. The open position is a position in which the upper body 1120 and the lower body 1140 are spaced apart from each other to open the processing space 1110. The blocking position is a position where the processing space 1110 is sealed from the outside by the lower body 1140 and the upper body 1120.

The sealing member 1160 is positioned between the upper body 1120 and the lower body 1140. The sealing member 1160 allows the processing space to be sealed from the outside when the upper body 1120 and the lower body 1140 contact each other. The sealing member 1160 may be provided in an annular ring shape. The sealing member 1160 may be fixedly coupled to the upper end of the lower body 1140.

The support unit 1300 supports the substrate W in the processing space 1110. The support unit 1300 includes a support plate 1320, a heater member 1400, a lift pin 1340, a support pin 1360, and a cooling unit 900.

8 is a plan view showing the support unit of FIG. 7. 7 and 8, the support plate 1320 transfers heat generated from the heater unit 1400 to the substrate W. The support plate 1320 is provided in a circular plate shape. The upper surface of the support plate 1320 has a larger diameter than the substrate W.

The support plate 1320 functions as a seating surface on which the substrate W is placed. When viewed from the top, the lift holes 1322 are arranged to surround the center of the upper surface of the support plate 1320, respectively. Each of the lift holes 1322 is arranged to be spaced apart from each other along the circumferential direction. The lift holes 1322 are positioned to be spaced apart from each other at equal intervals.

The support plate 1320 may be made of a material including aluminum nitride (AlN). The lift pin 1340 raises and lowers the substrate W on the support plate 1320. A plurality of lift pins 1340 are provided, and each of the lift pins 1340 is provided in a pin shape facing a vertical vertical direction. A lift pin 1340 is positioned in each lift hole 1322. A driving member (not shown) moves each of the lift pins 1340 between the lifting position and the lowering position. Here, the lifting position is a position where the upper end of the lift pin 1340 is higher than the seating surface, and the lowering position is defined as a position where the upper end of the lift pin 1340 is equal to or lower than the seating surface. The driving member (not shown) may be located outside the housing 1100. The driving member (not shown) may be a cylinder.

The support pin 1360 prevents the substrate W from directly contacting the mounting surface. The support pin 1360 is provided in a pin shape having a longitudinal direction parallel to the lift pin 1340. A plurality of support pins 1360 are provided, each of which is fixedly installed on a seating surface. The support pins 1360 are positioned to protrude upward from the seating surface. The upper end of the support pin 1360 is provided as a contact surface that directly contacts the bottom surface of the substrate W, and the contact surface has a convex upward shape. Accordingly, the contact area between the support pin 1360 and the substrate W can be minimized.

The guide 1380 guides the substrate W so that the substrate W is placed in a proper position. The guide 1380 is provided to have an annular ring shape surrounding the seating surface. The guide 1380 has a larger diameter than the substrate W. The inner surface of the guide 1380 has a shape inclined downward as it approaches the central axis of the support plate 1320. Accordingly, the substrate W over the inner surface of the guide 1380 is moved to the correct position along the inclined surface. In addition, the guide 1380 may prevent a small amount of airflow flowing between the substrate W and the seating surface.

The heater unit 1400 heats the substrate W placed on the support plate 1320. The heater unit 1400 is positioned below the substrate W placed on the support plate 1320. The heater unit 1400 includes a plurality of heaters 1420. The heaters 1420 are located in the support plate 1320.

The heaters 1420 heat different regions of the support surface. When viewed from above, a region of the support plate 1320 corresponding to each heater 1420 may be provided as a plurality of heating zones. Each heater 1420 is independently adjustable in temperature. For example, there may be 15 heating zones. The temperature of each heating zone is measured by a measuring member (not shown). The heaters 1420 may be printed patterns or heating wires. The heater unit 1400 may heat the support plate 1320 to a process temperature.

The exhaust unit 1500 forcibly exhausts the interior of the processing space 1110. The exhaust unit 1500 includes an exhaust pipe 1530 and a guide plate 1540. The exhaust pipe 1530 has a tubular shape in which the longitudinal direction faces in a vertical direction. The exhaust pipe 1530 is positioned to penetrate the upper wall of the upper body 1120. According to an example, the exhaust pipe 1530 may be positioned to be inserted into the exhaust hole 1122. That is, the lower end of the exhaust pipe 1530 is located in the processing space 1110, and the upper end of the exhaust pipe 1530 is located outside the processing space 1110. A pressure reducing member 1560 is connected to an upper end of the exhaust pipe 1530. The pressure reducing member 1560 depressurizes the exhaust pipe 1530. Accordingly, the atmosphere in the processing space 1110 is exhausted through the through hole 1542 and the exhaust pipe 1530 in sequence.

The guide plate 1540 has a plate shape having a through hole 1542 in the center. The guide plate 1540 has a circular plate shape extending from the lower end of the exhaust pipe 1530. The guide plate 1540 is fixedly coupled to the exhaust pipe 1530 so that the through hole 1542 and the inside of the exhaust pipe 1530 communicate with each other. The guide plate 1540 is positioned above the support plate 1320 to face the support surface of the support plate 1320. The guide plate 1540 is positioned higher than the lower body 1140. According to an example, the guide plate 1540 may be positioned at a height facing the upper body 1120. When viewed from the top, the guide plate 1540 is positioned to overlap the inlet hole 1124 and has a diameter spaced apart from the inner surface of the upper body 1120. Accordingly, a gap is generated between the side end of the guide plate 1540 and the inner surface of the upper body 1120, and this gap is provided as a flow path through which the air flow introduced through the inlet hole 1124 is supplied to the substrate W.

The cooling unit 900 will be described in detail with reference to FIGS. 9 to 10. 9 is a cross-sectional view showing the support unit 1300 of FIG. 7, and FIG. 10 is a plan view showing a cooling plate 920 according to an embodiment of the present invention.

Referring to FIG. 9, a heater member 1400 is provided on the support plate 1320. The heater member 1400 is provided with a plurality of heaters 1420. In one example, the heater member 1400 is provided in a plate shape. The cooling plate 920 cools the support plate 1320 by supplying cooling gas to the bottom surface of the heater member 1400.

Referring to FIG. 10, the cooling unit 900 includes a cooling plate 920, a gas supply member 950, and a controller (not shown). The cooling unit 900 is provided under the heater member 1400 and forcibly cools the support plate 1320. The cooling plate 920 is provided under the heater member 1400 to be spaced apart from the heater member 1400.

The gas supply member 950 includes a gas supply line 954, a control valve 956 and a nozzle 952. The gas supply member 950 supplies a cooling gas into the nozzle 952. In one example, the gas is air. The gas supply line 954 supplies cooling gas to the nozzle 952. The control valve 956 regulates the flow rate of the cooling gas supplied to the gas supply line 954 from a gas supply source (not shown). The nozzle 952 is provided on the cooling plate 920 to supply cooling gas to the bottom surface of the heater member 1400. The nozzle 952 is provided to be rotatable.

11 is a perspective view of a nozzle 952 according to an embodiment of the present invention. Referring to FIG. 11, the nozzle 952 has a discharge port 9526 for supplying gas to the bottom of the heater member 1400 on one side, and a rotating body 9524 rotatably inserted into the cooling plate 920 on the other side. Have. In one example, the nozzle 952 may be provided with a length such that the gas discharged from the discharge port 9526 directly contacts the bottom surface of the heater member 1400.

In one example, the rotating body 9524 is located in the mounting groove 953 provided on the cooling plate 920 as shown in FIG. 10. The rotating body 9524 is inserted into the mounting groove 953 to prevent the nozzle 952 from being separated from the mounting groove 953 while the gas is discharged through the discharge port 9526.

Gas is introduced into the rotating body 9524 through a gas supply line 954. The rotating body 9524 is provided to be rotatable in the mounting groove 953. In one example, the rotating body 9524 is provided to be rotated by the pressure of the gas introduced into the rotating body 9524 and discharged through the discharge port (9526). That is, the rotating body 9524 automatically rotates by the pressure of gas without additional power.

The rotating body 9524 is provided in a spherical shape. In one example, the rotating body 9524 is provided as a ball joint. In one example, the nozzle 952 is provided to be rotatable about all of the X-axis, Y-axis, and Z-axis with respect to the center of the rotating body 9524. While the flow velocity of the gas discharged from the discharge port 9526 maintains a constant speed, the nozzle 952 sporadically rotates about all of the X-axis, Y-axis, and Z-axis with respect to the center of the rotating body 9524.

A plurality of nozzles 952 may be provided along the circumferential direction of the cooling plate 920. In one example, a plurality of nozzles 952 are provided on the cooling plate 920 along the circumferential direction of the cooling plate 920 at a first distance from the cooling plate 920. In one example, the first distance is set to be opposite between the central region and the edge region of the heater member 1400.

12 is a diagram illustrating a procedure of a substrate processing method according to an embodiment of the present invention. Referring to FIG. 12, the substrate processing method of the present invention includes a first heating step (S10), a cooling step (S20), and a second heating step (S30).

In one example, a cooling step (S20) is included to treat a preceding substrate at a first temperature in the first heating step (S10), and to process a subsequent substrate at a second temperature in the second heating step (S20).

In the first heating step S10, the support plate 1320 heats the substrate to a first temperature. Thereafter, in the cooling step (S20), a cooling gas is supplied to the support plate 1320 to forcibly cool to a preset temperature. In the cooling step S20, cooling gas is supplied to the bottom surface of the heater member 1400 through the gas supply member 950, so that the temperature of the support plate 1320 is lowered. In the cooling step S20, the nozzle 952 rotates and cools the entire area of the bottom surface of the heater member 1400. The cooling step S20 continues until the temperature of the support plate 1320 reaches a second temperature lower than the first temperature.

After the cooling step (S20), the second heating step (S30) is started. In the second heating step (S30), the support plate 1320 treats the substrate to a second temperature lower than the first temperature.

In the above-described example, it has been described that the nozzle 952 is positioned so as to be opposite between the central region and the edge region of the heater member 1400. However, in another example, as shown in FIG. 13, a plurality of nozzles 952 are provided on the cooling plate 920 at a second distance and a third distance from the center of the cooling plate 920 along the circumferential direction of the cooling plate. Can be provided. The second distance may be positioned to face the central region of the heater member 1400, and the third distance may be positioned to face the edge region of the heater member 1400. The nozzle 952b located at the second distance is inserted into the mounting groove 953b formed at the second distance, and the nozzle 952a located at the third distance is inserted into the mounting groove 953b formed at the third distance.

By arranging a plurality of nozzles 952 at the second and third distances, respectively, there is an advantage of improving cooling performance.

In the above-described example, it has been described that the nozzle 952 is automatically rotated by the pressure of the gas supplied to the nozzle 952. However, in another example, the rotating body 9524 may be driven by a driver. For example, the rotating body 9524 may be rotated by a motor.

According to the present invention, the nozzle 952 is positioned so as to be opposite between the central region and the edge region of the heater member 1400, and with respect to all of the X-axis, Y-axis, and Z-axis based on the center of the rotating body 9524. It is provided to be rotatable. Accordingly, in a limited space, the nozzle 952 may supply cooling gas to a wider area of the bottom surface of the heater member 1400. Accordingly, there is an advantage in that the time for cooling the heater member 1400 is shortened.

Referring back to FIGS. 2 and 3, a plurality of buffer chambers 3800 are provided. Some of the buffer chambers 3800 are disposed between the index module 20 and the transfer chamber 3400. Hereinafter, these buffer chambers are referred to as a front buffer 3802. The shear buffers 3802 are provided in plural and are positioned to be stacked with each other along the vertical direction. Other portions of the buffer chambers 3802 and 3804 are disposed between the transfer chamber 3400 and the interface module 40 below. These buffer chambers are referred to as rear buffer 3804. The rear buffers 3804 are provided in plural, and are positioned to be stacked with each other along the vertical direction. Each of the front buffers 3802 and the rear buffers 3804 temporarily stores a plurality of substrates W. The substrate W stored in the shear buffer 3802 is carried in or taken out by the index robot 2200 and the transfer robot 3422. The substrate W stored in the rear buffer 3804 is carried in or taken out by the transfer robot 3422 and the first robot 4602.

The developing block 30b has a heat treatment chamber 3200, a transfer chamber 3400, and a liquid treatment chamber 3600. The heat treatment chamber 3200, the transfer chamber 3400, and the liquid treatment chamber 3600 of the developing block 30b are the heat treatment chamber 3200, the transfer chamber 3400, and the liquid treatment chamber 3600 of the coating block 30a. ) And is provided in a generally similar structure and arrangement, so it is for this. However, in the developing block 30b, all of the liquid processing chambers 3600 are provided as a developing chamber 3600 for developing and processing a substrate by supplying a developer in the same manner.

The interface module 40 connects the processing module 30 to an external exposure apparatus 50. The interface module 40 has an interface frame 4100, an additional process chamber 4200, an interface buffer 4400, and a conveying member 4600.

A fan filter unit may be provided at an upper end of the interface frame 4100 to form a downward airflow therein. The additional process chamber 4200, the interface buffer 4400, and the transfer member 4600 are disposed inside the interface frame 4100. The additional process chamber 4200 may perform a predetermined additional process before the substrate W, which has been processed in the coating block 30a, is carried into the exposure apparatus 50. Optionally, the additional process chamber 4200 may perform a predetermined additional process before the substrate W, which has been processed by the exposure apparatus 50, is carried into the developing block 30b. According to an example, the additional process is an edge exposure process of exposing the edge region of the substrate W, a top surface cleaning process of cleaning the upper surface of the substrate W, or a lower surface cleaning process of cleaning the lower surface of the substrate W. I can. A plurality of additional process chambers 4200 may be provided, and they may be provided to be stacked on each other. All of the additional process chambers 4200 may be provided to perform the same process. Optionally, some of the additional process chambers 4200 may be provided to perform different processes.

The interface buffer 4400 provides a space in which the substrate W transferred between the coating block 30a, the additional process chamber 4200, the exposure apparatus 50, and the developing block 30b temporarily stays during the transfer process. A plurality of interface buffers 4400 may be provided, and a plurality of interface buffers 4400 may be provided to be stacked on each other.

According to an example, an additional process chamber 4200 may be disposed on one side and an interface buffer 4400 may be disposed on the other side based on an extension line in the length direction of the transfer chamber 3400.

The conveying member 4600 conveys the substrate W between the coating block 30a, the addition process chamber 4200, the exposure apparatus 50, and the developing block 30b. The transfer member 4600 may be provided as one or a plurality of robots. According to an example, the carrying member 4600 has a first robot 4602 and a second robot 4606. The first robot 4602 transfers the substrate W between the coating block 30a, the additional process chamber 4200, and the interface buffer 4400, and the interface robot 4606 includes the interface buffer 4400 and the exposure apparatus ( 50), and the second robot 4604 may be provided to transport the substrate W between the interface buffer 4400 and the developing block 30b.

Each of the first robot 4602 and the second robot 4606 includes a hand on which the substrate W is placed, and the hand moves forward and backward, rotates about an axis parallel to the third direction 16, and It may be provided to be movable along the three directions (16).

The hand of the index robot 2200, the first robot 4602, and the second robot 4606 may all be provided in the same shape as the hand 3420 of the transfer robots 3422 and 3424. Optionally, the hand of the robot that directly exchanges the substrate (W) with the transfer plate 3240 of the heat treatment chamber is provided in the same shape as the hand 3420 of the transfer robots 3422 and 3424, and the hands of the other robots have a different shape. Can be provided.

According to an embodiment, the index robot 2200 is provided to directly exchange the substrate W with the heating device 3230 of the shear heat treatment chamber 3200 provided in the coating block 30a.

In addition, the transfer robot 3422 provided in the coating block 30a and the developing block 30b may be provided to directly exchange the substrate W with the transfer plate 3240 located in the heat treatment chamber 3200.

The processing block of the above-described substrate processing apparatus 1 has been described as performing a coating treatment process and a development treatment process. However, unlike this, the substrate processing apparatus 1 may include only the index module 20 and the processing block 37 without an interface module. In this case, the processing block 37 performs only a coating process, and a film applied on the substrate W may be a spin-on hard mask film SOH.

The detailed description above is illustrative of the present invention. In addition, the above description shows and describes preferred embodiments of the present invention, and the present invention can be used in various other combinations, modifications, and environments. That is, changes or modifications may be made within the scope of the concept of the invention disclosed in the present specification, the scope equivalent to the disclosed contents, and/or the technology or knowledge in the art. The above-described embodiments are to describe the best state for implementing the technical idea of the present invention, and various changes required in the specific application fields and uses of the present invention are also possible. Therefore, the detailed description of the invention is not intended to limit the invention to the disclosed embodiment. In addition, the appended claims should be construed as including other embodiments.

900: cooling unit
920: cooling plate
952: nozzle
953: mounting groove
1320: support plate

Claims (13)

In the apparatus for processing a substrate,
A housing providing a processing space therein; And
It includes a support unit for supporting the substrate in the processing space,
The support unit,
A support plate supporting the substrate;
A heater member provided on the support plate to heat the substrate; And,
And a cooling unit provided under the heater member and forcibly cooling the support plate,
The cooling unit,
A cooling plate disposed to be spaced apart from the heater member; And
And a nozzle provided on the cooling plate to supply gas to the bottom surface of the heater member,
The substrate processing apparatus is provided so that the nozzle is rotatable. The method of claim 1,
The nozzle is a substrate processing apparatus including a rotating body. The method of claim 1,
The nozzle,
A substrate processing apparatus having a rotating body rotatably inserted into the cooling plate on the other side with a discharge port for supplying the gas to the bottom surface of the heater member on one side. The method of claim 3,
The rotating body is a substrate processing apparatus provided in a spherical shape. The method of claim 3,
The rotating body is a substrate processing apparatus provided as a ball joint. The method according to any one of claims 3 to 5,
The rotating body,
A substrate processing apparatus provided to be rotated by a pressure of a gas introduced into the rotating body and discharged through the discharge port. The method of claim 1,
The cooling plate has a mounting groove formed on its upper surface,
The nozzle is a substrate processing apparatus disposed in the mounting groove. The method of claim 1,
The substrate processing apparatus is provided in a plurality of nozzles along the circumferential direction of the cooling plate. The method of claim 1,
A plurality of nozzles are provided on the cooling plate along the circumferential direction of the cooling plate at a first distance from the cooling plate,
The first distance is provided so as to be opposite between a central region and an edge region of the heater member. The method of claim 1,
A plurality of nozzles are provided to the cooling plate at a second distance and a third distance from the center of the cooling plate along the circumferential direction of the cooling plate,
The second distance is positioned to face the central region of the heater member,
The third distance is provided to be positioned so as to face the edge region of the heater member. In the method of processing a substrate using the substrate processing apparatus of claim 1,
A first heating step in which the support plate heats the substrate to a first temperature; And
A cooling step of forcibly cooling the gas to a preset temperature by supplying the gas to the support plate,
The nozzle,
In the cooling step, the nozzle rotates and cools the entire area of the bottom surface of the heater member. The method of claim 11,
After the cooling step,
A second heating step in which the support plate heats the substrate to a second temperature. The method of claim 12,
The second temperature is provided lower than the first temperature.

Images