KR102258243B1 - Substrate heating unit - Google Patents

Abstract

A substrate heating unit is disclosed. The substrate heating unit includes a rotatable chuck stage on which a substrate is placed; A rotating portion having a hollow shape and coupled to the chuck stage to rotate the chuck stage; A back nozzle penetrating the inside of the rotating part, provided at the center of the upper portion of the chuck stage, and spraying a processing liquid to the rear surface of the substrate; A heating unit having ring-shaped lamps arranged to be spaced apart from the top of the chuck stage and arranged concentrically at different radial distances with respect to the center of the chuck stage; A reflective plate provided between the heating part and the chuck stage and reflecting thermal energy radiated from the heating part toward a substrate; And temperature sensor assemblies installed on the reflective plate to measure the temperature of each of the lamps.

Description

Substrate heating unit {SUBSTRATE HEATING UNIT}

The present invention relates to a substrate heating unit, and more particularly, to a substrate heating unit capable of heating a substrate to a target temperature without overload.

In general, the process of processing a glass substrate or wafer in a flat panel display device manufacturing or semiconductor manufacturing process includes a photoresist coating process, a developing process, an etching process, an ashing process, etc. Various processes are performed.

In each process, a wet cleaning process using chemical or deionized water and a drying process to dry the chemical or pure water remaining on the substrate surface to remove various contaminants attached to the substrate. ) The process is carried out.

Recently, an etching process for selectively removing a silicon nitride layer and a silicon oxide layer has been performed using an aqueous chemical solution used at a high temperature such as sulfuric acid or phosphoric acid.

In a substrate processing apparatus using a high-temperature chemical aqueous solution, a substrate heating apparatus for heating a substrate is applied and utilized in order to improve the etch rate and uniformity.

However, in the existing substrate heating device, the temperature sensor that senses the heater is made of stainless steel, so when the setting value is lowered, the substrate temperature reaches the target temperature (for example, 200 degrees). You won't be able to do it. In addition, if the temperature sensor is heated after the first process and the second process is not sufficiently cooled, the set value (the set measurement temperature) is quickly reached due to the heating of the temperature sensor, and the substrate does not reach the target temperature. I can't. On the contrary, when the setting value of the temperature sensor is set higher and proceeds, there is a problem that the sensor fails and malfunctions.

Embodiments of the present invention are intended to provide a substrate heating unit capable of heating a substrate to a target temperature without overloading a temperature sensor.

Embodiments of the present invention are intended to provide a substrate heating unit capable of blocking conductive heat transmitted from surrounding structures in addition to heat transmitted from a heating element by a temperature sensor.

Embodiments of the present invention are intended to provide a substrate heating unit capable of rapidly lowering the temperature of a temperature sensor.

The problem to be solved by the present invention is not limited thereto, and other problems that are not mentioned will be clearly understood by those skilled in the art from the following description.

According to an aspect of the present invention, a rotatable chuck stage on which a substrate is placed; A rotating portion having a hollow shape and coupled to the chuck stage to rotate the chuck stage; A back nozzle part penetrating the inside of the rotating part, provided at the center of the upper part of the chuck stage, and spraying the processing liquid to the rear surface of the substrate; A heating unit having ring-shaped lamps arranged to be spaced apart from the top of the chuck stage and arranged concentrically at different radial distances with respect to the center of the chuck stage; A reflective plate provided between the heating part and the chuck stage and reflecting thermal energy radiated from the heating part toward a substrate; And temperature sensor assemblies installed on the reflective plate to measure the temperature of each of the lamps.

In addition, the temperature sensor assembly may include a fixing block having a bolt fastening hole to fix the reflective plate; A thin support plate formed to extend from the fixing part to one side and provided to be spaced apart from the reflective plate; A temperature sensor element to which a lead wire for signal extraction is connected and positioned on a bottom surface of the support plate; A thin cover plate provided so as to surround the temperature sensor element, and having an edge fixed to a bottom surface of the support plate by welding; And an insulating spacer installed between the fixing block and the reflective plate to block heat transmitted from the reflective plate.

In addition, the fixing block, the support plate, and the cover plate may have a gold plating layer.

According to the present invention, the temperature sensor assembly minimizes the heat transmitted from the reflective plate to measure only the heat of the pure IR lamp, thereby setting the setting value of the temperature sensor low to heat the substrate to the target temperature without overloading, and the temperature of each process. It has a special effect of reducing errors between processes by making the sensor temperature the same.

According to the present invention, since the fixing block, the support plate, and the cover plate of the temperature sensor assembly are gold-plated, the heat transmitted from the reflective plate is filtered to reduce the setting value of the temperature sensor, so that it is possible to expect a smooth operation of the temperature sensor.

According to the present invention, the support plate on which the temperature sensor element is mounted is disposed adjacent to the through hole formed in the reflective plate, so that cooling by the cooling gas is possible. Therefore, it is possible to proceed with the second process by lowering the heated temperature sensor after the first process in a short time, thereby having a special effect of reducing the deviation of the process time and the substrate heating time.

1 is a plan view schematically showing a substrate processing facility according to an embodiment of the present invention.
FIG. 2 is a plan view showing the configuration of the processing apparatus shown in FIG. 1.
3 is a side cross-sectional view showing the configuration of a processing apparatus according to the present invention.
4 is a cross-sectional view of the substrate heating unit.
5 is a view showing a main part of FIG. 4.
6A and 6B are views illustrating a temperature sensor assembly installed on a reflective plate.

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 embodiments. This embodiment is provided to more completely describe 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 more clear description.

Referring to FIG. 1, the substrate processing system 1000 of the present invention may include an index unit 10, a buffer unit 20, and a processing unit 50.

The index unit 10, the buffer unit 20, and the processing unit are arranged in a line. Hereinafter, the direction in which the index unit 10, the buffer unit 20, and the processing unit 50 are arranged is referred to as a first direction, and when viewed from above, a direction perpendicular to the first direction is referred to as a second direction. A direction perpendicular to the plane including the first direction and the second direction is defined as a third direction.

The index unit 10 is disposed in front of the substrate processing system 1000 in the first direction. The index unit 10 includes four load ports 12 and one index robot 13.

The four load ports 12 are disposed in front of the index unit 10 in the first direction. A plurality of load ports 12 are provided and they are arranged along the second direction. The number of load ports 12 may increase or decrease according to the process efficiency and footprint conditions of the substrate processing system 1000. A carrier (eg, a cassette, a FOUP, etc.) in which the substrate W to be provided for the process and the substrate W that has been processed is accommodated is mounted on the load ports 12. The carrier 16 is formed with a plurality of slots for receiving substrates horizontally with respect to the ground.

The index robot 13 is disposed in the first direction adjacent to the load port 12. The index robot 13 is installed between the load port 12 and the buffer unit 20. The index robot 13 transfers the substrate W waiting on the upper layer of the buffer unit 20 to the carrier 16 or transfers the substrate W waiting on the carrier 16 to the lower layer of the buffer unit 20 do.

The buffer unit 20 is installed between the index unit 10 and the processing unit. The buffer unit 20 temporarily stores and waits for the substrate W to be provided to the process before being transferred by the index robot 13 or the substrate W that has been processed before being transferred by the main transfer robot 30. It is a place to do.

The main transfer robot 30 is installed in the movement passage 40 and transfers the substrate between the processing devices 1 and the buffer unit 20. The main transfer robot 30 transfers the substrates to be provided for the process waiting in the buffer unit 20 to each processing unit 1, or transfers the substrates that have been processed in each processing unit 1 to the buffer unit 20. Transfer.

The movement passage 40 is disposed along the first direction in the processing unit, and provides a passage through which the main transfer robot 30 moves. On both sides of the moving passage 40, the processing devices 1 face each other and are disposed along the first direction. In the moving passage 40, the main transfer robot 30 moves along the first direction, and a moving rail that can move up and down the upper and lower layers of the processing device 1 and the upper and lower layers of the buffer unit 20 is installed.

The processing device 1 is disposed facing each other on both sides of the moving passage 40 in which the main transfer robot 30 is installed. The substrate processing system 1000 includes a plurality of processing units 1 of upper and lower layers, but the number of processing units 1 may increase or decrease depending on the process efficiency and footprint conditions of the substrate processing system 1000. have. Each processing device 1 is configured as an independent housing, and thus, a process of processing a substrate in an independent form may be performed within each processing device.

In the following embodiments, an apparatus for cleaning a substrate using processing fluids such as high-temperature sulfuric acid, an alkaline chemical solution (including ozone water), an acidic chemical solution, a rinse solution, and a drying gas (a gas containing IPA) will be described as an example. However, the technical idea of the present invention is not limited thereto, and may be applied to various types of devices that perform a process while rotating a substrate, such as an etching process.

2 is a plan view showing the configuration of a processing apparatus according to the present invention. 3 is a side cross-sectional view showing the configuration of a processing apparatus according to the present invention.

In the present embodiment, a semiconductor substrate is illustrated and described as an example as a substrate processed by the sheet processing apparatus 1, but the present invention is not limited thereto, and a substrate for a liquid crystal display device, a substrate for a plasma display, and a field emission display (FED) ) Substrate, optical disk substrate, magnetic disk substrate, optical magnetic disk substrate, photomask substrate, ceramic substrate, solar cell substrate.

2 and 3, the sheet-fed processing apparatus 1 according to the present invention is an apparatus for removing foreign substances and films remaining on the surface of a heated substrate by using various processing fluids, and includes a chamber 800 and a processing container. 100, a substrate heating unit 200, a chemical solution supply member 300, a fixed nozzle 900, and a process exhaust unit 500.

The chamber 800 provides an enclosed inner space, and a fan filter unit 810 is installed above it. The fan filter unit 810 generates vertical airflow in the chamber 800.

The fan filter unit 810 is a device in which a filter and an air supply fan are modularized into one unit, and is a device that filters high-humidity outdoor air and supplies it to the interior of the chamber. High-humidity outdoor air passes through the fan filter unit 810 and is supplied into the chamber to form a vertical airflow. This vertical airflow provides a uniform airflow over the substrate, and contaminants (fumes) generated in the process of treating the substrate surface by the processing fluid are processed through the intake ducts of the processing vessel 100 together with air. By being discharged to 500 and removed, high cleanliness inside the processing container is maintained.

As shown in FIG. 3, the chamber 800 is divided into a process area 816 and a maintenance area 818 by a horizontal partition wall 814. Although only a part is shown in the drawing, in the maintenance area 818, in addition to the discharge lines 141, 143, and 145 and the exhaust line 510 connected to the processing container 100, the driving unit of the lifting unit and the first nozzle of the chemical solution supply member 300 ( It is a space in which a driving unit connected to the 310s, a supply line, etc. are located, and the maintenance area 818 is preferably isolated from a process area in which substrate processing is performed.

The processing container 100 has a cylindrical shape with an open top, and provides a processing space for processing the substrate w. The opened upper surface of the processing container 100 is provided as a passage for carrying out and carrying in the substrate w. The substrate heating unit 200 is located in the process space. The substrate heating unit 200 heats and rotates the substrate while supporting the substrate W during the process.

The processing vessel 100 provides a lower space to which the exhaust duct 190 is connected to the lower end so that forced exhaust is performed. In the processing container 100, first, second, and third annular suction ducts 110, 120, and 130 are arranged in multiple stages for introducing and inhaling the chemical liquid and gas scattered on the rotating substrate.

The annular first, second and third suction ducts 110, 120, and 130 have exhaust ports H communicating with one common annular space (corresponding to the lower space of the container). An exhaust duct 190 connected to the exhaust member 400 is provided in the lower space.

Specifically, the first to third suction ducts 110, 120, and 130 each include a bottom surface having an annular ring shape and a side wall extending from the bottom surface and having a cylindrical shape. The second suction duct 120 surrounds the first suction duct 110 and is spaced apart from the first suction duct 110. The third suction duct 130 surrounds the second suction duct 120 and is spaced apart from the second suction duct 120.

The first to third suction ducts 110, 120, and 130 provide first to third recovery spaces RS1, RS2, and RS3 into which air flows including treatment liquid and fume scattered from the substrate w are introduced. . The first recovery space RS1 is defined by the first suction duct 110, and the second recovery space RS2 is defined by a spaced space between the first suction duct 110 and the second suction duct 120. , The third recovery space RS3 is defined by a space between the second suction duct 120 and the third suction duct 130.

Each upper surface of the first to third suction ducts 110, 120, and 130 has a central opening and is formed of an inclined surface whose distance from the corresponding bottom surface gradually increases from the connected sidewall toward the opening. Accordingly, the processing liquid scattered from the substrate w flows into the recovery spaces RS1, RS2, and RS3 along the upper surfaces of the first to third suction ducts 110, 120, and 130.

The first treatment liquid introduced into the first recovery space RS1 is discharged to the outside through the first recovery line 141. The second treatment liquid introduced into the second recovery space RS2 is discharged to the outside through the second recovery line 143. The third treatment liquid introduced into the third recovery space RS3 is discharged to the outside through the third recovery line 145.

The process exhaust unit 500 is responsible for exhausting the inside of the processing container 100. For example, the process exhaust unit 500 is for providing an exhaust pressure (suction pressure) to a suction duct that recovers a treatment liquid among the first to third suction ducts 110, 120, and 130 during a process. The process exhaust unit 500 includes an exhaust line 510 and a damper 520 connected to the exhaust duct 190. The exhaust line 510 receives exhaust pressure from an exhaust pump (not shown) and is connected to a main exhaust line buried in a floor space of a semiconductor production line (fab).

On the other hand, the processing container 100 is coupled with an elevating unit 600 that changes the vertical position of the processing container 100. The lifting unit 600 linearly moves the processing container 100 in the vertical direction. As the processing container 100 is moved up and down, the relative height of the processing container 100 with respect to the substrate heating unit 200 is changed.

The lifting unit 600 has a bracket 612, a moving shaft 614, and a driver 616. The bracket 612 is fixedly installed on the outer wall of the processing container 100, and a moving shaft 614 that is moved in the vertical direction by the actuator 616 is fixedly coupled to the bracket 612. When the substrate W is loaded onto the spin head 210 or unloaded from the spin head 210, the processing vessel 100 descends so that the spin head 210 protrudes from the top of the processing vessel 100. In addition, when the process proceeds, the height of the processing container 100 is adjusted so that the processing liquid can be introduced into the predetermined suction ducts 110, 120, and 130 according to the type of the processing liquid supplied to the substrate W. Accordingly, the relative vertical position between the processing container 100 and the substrate w is changed. Accordingly, the treatment vessel 100 may have different types of the treatment liquid and the polluted gas recovered for each of the recovery spaces RS1, RS2, and RS3.

In this embodiment, the processing apparatus 1 vertically moves the processing vessel 100 to change the relative vertical position between the processing vessel 100 and the substrate heating unit 200. However, the processing apparatus 1 may vertically move the substrate heating unit 200 to change a relative vertical position between the processing vessel 100 and the substrate heating unit 200.

The fixed nozzles 900 are installed on the top of the processing container 100. The fixed nozzle 900 injects a processing fluid onto the substrate W placed on the spin head 210. The fixed nozzle 900 can adjust the spray angle according to the processing position of the substrate.

The chemical solution supply member 300 discharges a high-temperature chemical for etching the surface of the substrate W. Here, the chemical may be sulfuric acid, phosphoric acid, or a mixture of sulfuric acid and phosphoric acid.

The chemical liquid nozzle member 310 includes a nozzle 311, a nozzle arm 313, a support rod 315, and a nozzle driver 317. The nozzle 311 receives phosphoric acid through the supply unit 320. The nozzle 311 discharges phosphoric acid to the surface of the substrate. The nozzle arm 313 is an arm that is provided with a length in one direction, and a nozzle 311 is mounted at the tip. The nozzle arm 313 supports the nozzle 311. A support rod 315 is mounted at the rear end of the nozzle arm 313. The support rod 315 is located under the nozzle arm 313 and is disposed perpendicular to the nozzle arm 313. The nozzle driver 317 is provided at the lower end of the support rod 315. The nozzle driver 317 rotates the support rod 315 about the longitudinal axis of the support rod 315. The rotation of the support rod 315 causes the nozzle arm 313 and the nozzle 311 to swing around the support rod 315 along the axis. The nozzle 311 may swing between the outside and the inside of the processing container 210. In addition, the nozzle 311 may swing a section between the center of the substrate W and the edge region and discharge phosphoric acid.

Although not shown, the single-leaf processing apparatus 1 may include supply members for injecting various processing fluids to the substrate in addition to the chemical solution supply member 300.

4 is a cross-sectional view showing a substrate heating unit, and FIG. 5 is a view showing a main part of FIG. 4.

2 to 5, the substrate heating unit 200 is installed inside the processing container 100. The substrate heating unit 200 heats the substrate during the process. In addition, the substrate heating unit 200 supports the substrate W during the process, and may be rotated by the driving unit 240 to be described later while the process is in progress.

The substrate heating unit 200 includes a chuck stage 210, a quartz window 220, a rotating part 230, a back nozzle part 240, a heating part 250, a reflective plate 260, and a temperature sensor assembly 270. Includes.

The chuck stage 210 has a circular upper surface, and is rotated by being coupled to the rotating part 230. Chucking pins 212 are installed at the edge of the chuck stage 210. The chucking pins 212 are provided to penetrate the quartz window 220 and protrude upward from the quartz window 220. The chucking pins 212 align the substrate W such that the substrate W supported by the plurality of support pins 224 is placed in a correct position. In addition, during the process, the chucking pins 212 are in contact with the side of the substrate W to prevent the substrate W from being separated from the original position.

The rotating part 230 has a hollow shape, and is coupled to the chuck stage 210 to rotate the chuck stage 210.

A heating unit 250 for heating the substrate to 150-250° C. is installed on the chuck stage 210. The heating unit 250 has a different diameter and is disposed to be spaced apart from each other, and includes a plurality of IR lamps 252 provided in a ring shape. Each of the IR lamps 252 includes a temperature sensor assembly 270 so that each can be controlled.

The heating unit 250 may be subdivided into a plurality of concentric regions. Each zone is provided with IR lamps 252 capable of individually heating each zone. The IR lamps 252 are made of a ring shape arranged concentrically at different radial distances with respect to the center of the chuck stage 210. Although six IR lamps 252 are shown in this embodiment, it will be appreciated that this is only an example and the number of IR lamps can be added or subtracted depending on the degree of temperature control desired. As such, the heating unit 250 provides the ability to control the temperature monotonically (i.e., continuous increase or decrease in temperature) according to the radius of the substrate during the process by controlling the temperature of each individual zone. do. To this end, a temperature sensor assembly 270 for individually checking the temperature of each of the IR lamps 252 is installed on the reflective plate 26.

For example, in a structure in which the IR lamps 252 are rotated together with the chuck stage 210, a method of supplying power to the heating unit 250 may use a slip ring.

A reflective plate 260 may be provided between the heating unit 250 and the chuck stage 210 to transfer heat generated from the IR lamps 252 to the top (toward the substrate). The reflective plate 260 may be supported by a nozzle body installed through the central space of the rotating part 230. In addition, the reflective plate 260 includes a support end 268 that is formed to extend downwardly at an inner end for stable support and is supported by a bearing 232 to the rotating part 230. The reflective plate 260 is provided in a fixed manner that does not rotate together with the chuck stage 210.

Although not shown, cooling fins may be installed on the reflective plate 260 for the purpose of heat dissipation. In addition, in order to suppress heat generation of the reflective plate 260, the cooling gas may be configured to flow through the bottom of the reflective plate. For example, the nozzle body 242 has an injection port 248 for injecting cooling gas to the bottom of the reflective plate toward the direction in which the temperature sensor assemblies are arranged.

Meanwhile, a quartz window 220 for protecting the IR lamps 252 may be installed between the heating unit 250 and the substrate W. The quartz window 220 may be transparent and may be rotated together with the chuck stage 210. The quartz window 220 includes support pins 224. The support pins 224 are disposed in a predetermined arrangement at a predetermined distance apart from the edge of the upper surface of the quartz window 220, and are provided to protrude upward from the quartz window 220. The support pins 224 support the lower surface of the substrate W so that the substrate W is supported in a state spaced from the quartz window 220 in the upward direction.

The back nozzle part 240 is for spraying a chemical liquid onto the rear surface of the substrate, and has a nozzle body 242 and a chemical liquid spraying part 244. The chemical liquid injection part 244 is located in the upper center of the chuck stage 210 and the quartz window 220. The nozzle body 242 is provided through the hollow rotary part 200, and although not shown, a chemical liquid movement line, a gas supply line, and a purge gas supply line may be provided inside the nozzle body 242. The chemical liquid transfer line supplies an etchant for etching the backside of the substrate W to the chemical sprayer 244, and the gas supply line supplies nitrogen gas to the backside of the substrate W for etch uniformity control, and a purge gas. The supply line supplies nitrogen purge gas to prevent penetration of the etchant between the quartz window and the nozzle body.

The temperature sensor assemblies 270 are installed in a line on a straight line of the reflective plate 260 to measure the temperature of each of the IR lamps 252.

6A and 6B are views illustrating a temperature sensor assembly installed on a reflective plate.

The temperature sensor assembly 270 includes a fixing block 271, a support plate 272, a temperature sensor element 273, a cover plate 274, and an insulating spacer 278. The temperature sensor assembly having the above structure may perform measurement and temperature control by mounting a thin temperature sensor assembly on the reflective plate 260 near the IR lamp in order to accurately measure the temperature of the IR lamp. That is, the temperature sensor assembly has a structure that is very suitable for a narrow space.

The fixing block 271 has a bolt fastening hole 271a to fix it to the reflective plate 260. The support plate 272 is formed to extend to one side of the fixing block 271 in a silm shape. The support plate 272 is disposed to be spaced apart from the upper surface of the reflective plate 260, and a through hole 269 is formed in the reflective plate 260 in a portion facing the support plate 272. Accordingly, the cooling gas flowing through the bottom of the reflective plate 260 may cool the temperature sensor assembly 270 through the through hole 269. The temperature sensor element 273 is connected to the lead wire 273a for signal extraction, and is located on the bottom surface of the support plate 272. The temperature sensor element 273 is surrounded and supported by a cover plate 274 whose edge is fixed to the bottom surface of the support plate 272 by welding. That is, the temperature sensor element 273 is not directly fixed to the support plate 272 but is mounted in a state supported by the cover plate 274.

The insulating spacer 278 is installed on the bottom of the fixing block 271, that is, the insulating spacer 278 is inserted between the fixing block 271 and the reflective plate 260 to form the temperature sensor assembly 170 from the reflective plate 260. Blocks the conductive heat transmitted to ).

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.

1: processing device 100: processing vessel
200: substrate heating unit 250: heating unit
252; IR lamp 260: reflective plate
270: temperature sensor assembly

Claims (20)

In a substrate heating unit supporting and heating a substrate:
Chuck stage;
A rotating unit having a hollow shape and being coupled to the chuck stage to rotate the chuck stage;
A heating unit having lamps disposed between a substrate supported by the substrate heating unit and an upper surface of the chuck stage;
A reflective plate provided between the heating part and the chuck stage, reflecting heat energy radiated from the heating part toward a substrate, and provided in a fixed manner that is not rotated together with the chuck stage; And
And temperature sensor assemblies measuring the temperature of each of the lamps. The method of claim 1,
The temperature sensor assemblies are a substrate heating unit installed on the reflective plate. In a substrate heating unit supporting and heating a substrate:
Chuck stage;
A rotating unit coupled to the chuck stage to rotate the chuck stage;
A heating unit having lamps disposed between a substrate supported by the substrate heating unit and an upper surface of the chuck stage;
A reflective plate provided between the heating part and the chuck stage and reflecting thermal energy radiated from the heating part toward a substrate; And
It characterized in that it comprises temperature sensor assemblies for measuring the temperature of each of the lamps,
The temperature sensor assemblies are installed on the reflective plate,
The temperature sensor assembly,
A fixing block having a bolt fastening hole formed therein to fix it to the reflective plate;
A support plate formed to extend from the fixed block to one side and provided to be spaced apart from the reflective plate; And
A substrate heating unit comprising a temperature sensor element to which a signal lead wire is connected and positioned on a bottom surface of the support plate. The method of claim 3,
The temperature sensor assembly,
The substrate heating unit further comprises a cover plate provided to surround the temperature sensor element and fixed to a bottom surface of the support plate. The method of claim 3,
The temperature sensor assembly
The substrate heating unit further comprises an insulating spacer installed between the fixing block and the reflective plate to block heat transmitted from the reflective plate. The method of claim 4,
The substrate heating unit, wherein the fixing block, the support plate, and the cover plate have a gold plating layer. The method of claim 4,
A substrate heating unit provided to allow a cooling gas to flow between the chuck stage and the reflective plate to suppress heat generation of the reflective plate. The method of claim 7,
The reflective plate,
The substrate heating unit further comprises a through hole formed in a portion facing the support plate so that the cooling gas flowing under the reflective plate cools the temperature sensor assembly. The method according to any one of claims 1 to 8,
The substrate heating unit further comprises a back nozzle installed to pass through the hollow of the rotating part and spraying the processing liquid to the rear surface of the substrate. The method according to any one of claims 1 to 8,
The lamps are arranged concentrically at different radial distances with respect to the center of the chuck stage. The method according to any one of claims 1 to 8,
The heating unit is a substrate heating unit disposed to be spaced apart from the upper surface of the chuck stage. In the substrate processing apparatus,
A processing container;
A substrate heating unit for supporting and heating a substrate positioned in the processing container;
A processing liquid supply unit for supplying a processing liquid to a substrate placed on the substrate heating unit,
The substrate heating unit,
A chuck stage;
A rotating part having a hollow shape and coupled to the chuck stage to rotate the chuck stage;
A lamp disposed between a substrate supported by the substrate heating unit and an upper surface of the chuck stage;
A reflective plate provided between the lamp and the chuck stage, reflecting heat energy radiated from the lamp toward a substrate, and provided in a fixed manner that is not rotated together with the chuck stage; And
A substrate processing apparatus comprising temperature sensor assemblies measuring the temperature of each of the lamps. The method of claim 12,
The temperature sensor assemblies are installed on the reflective plate. In the substrate processing apparatus,
A processing container;
A substrate heating unit for supporting and heating a substrate positioned in the processing container;
A processing liquid supply unit for supplying a processing liquid to a substrate placed on the substrate heating unit,
The substrate heating unit,
A chuck stage;
A rotating part coupled with the chuck stage to rotate the chuck stage;
A lamp disposed between a substrate supported by the substrate heating unit and an upper surface of the chuck stage;
A reflective plate provided between the lamp and the chuck stage and configured to reflect heat energy radiated from the lamp toward a substrate; And
Including temperature sensor assemblies for measuring the temperature of each of the lamps,
The temperature sensor assemblies are installed on the reflective plate,
The temperature sensor assembly.
A fixing block having a bolt fastening hole formed therein to fix it to the reflective plate;
A support plate extending to one side from the fixed block and provided to be spaced apart from the reflective plate; And
A substrate processing apparatus comprising a temperature sensor element to which a lead wire for signal extraction is connected and positioned on a bottom surface of the support plate. The method of claim 14,
The temperature sensor assembly
The substrate processing apparatus further comprises a cover plate provided to surround the temperature sensor element and fixed to a bottom surface of the support plate. The method of claim 14,
The temperature sensor assembly,
A substrate processing apparatus further comprising an insulating spacer installed between the fixing block and the reflective plate to block heat transmitted from the reflective plate. The method of claim 15,
The substrate processing apparatus, wherein the fixing block, the support plate, and the cover plate have a gold plating layer. The method of claim 15,
The substrate processing apparatus is provided to allow a cooling gas to flow between the chuck stage and the reflective plate to suppress heat generation of the reflective plate. The method of claim 18,
The reflective plate,
The substrate processing apparatus further comprises a through hole formed in a portion facing the support plate so that the cooling gas flowing under the reflective plate cools the temperature sensor assembly. The method of claim 12,
The lamps are arranged concentrically at different radial distances with respect to the center of the chuck stage.

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