KR102305331B1 - Substrate processing apparatus using light source built in spin chuck - Google Patents

Abstract

The present invention relates to a substrate processing apparatus using a light source built in a spin chuck. The present invention includes: a spin chuck rotating while supporting a substrate; a heating module including a light source unit built in the spin chuck not to come into contact with the spin chuck to emit light to a lower surface of the substrate supported and rotated by the spin chuck, and a light source substrate mounted thereon with the light source unit; a light source substrate temperature measuring unit installed on the light source substrate not to overlap the light source unit to measure a temperature of the light source substrate; a light transmitting plate coupled to the spin chuck to allow light emitted from the light source unit constituting the heating module toward the substrate to pass therethrough; and a control module configured to control the amount of the light emitted by the light source unit constituting the heating module to the lower surface of the substrate to control the temperature of the substrate, wherein the temperature of the light source substrate received from the light source substrate temperature measuring unit is compared to a set temperature critical range, and the operation of the light source unit constituting the heating module is controlled according to the comparison result between the temperature of the light source substrate and the temperature critical range. Accordingly, damage to the light source due to overheating of the light source substrate is prevented, and the temperature of the substrate is precisely controlled and maintained.

Description

A substrate processing device using a light source built into a rotary chuck {SUBSTRATE PROCESSING APPARATUS USING LIGHT SOURCE BUILT IN SPIN CHUCK}

The present invention relates to a substrate processing apparatus using a light source embedded in a rotary chuck. More specifically, the present invention can precisely control and maintain the temperature of the substrate while preventing damage to the light source due to overheating of the light source substrate in the process of controlling the temperature of the substrate to be processed in the semiconductor process using the light source mounted on the light source substrate. An object of the present invention is to provide a substrate processing apparatus using a light source embedded in a rotary chuck.

In general, during a process of processing a semiconductor substrate, the temperature of the fluid in the process of cleaning, etching, drying, etc. of the substrate performed using a specific fluid has a significant effect on the performance of the semiconductor process.

As one of the prior art for controlling the fluid temperature to an appropriate range, a technique of supplying a fluid heated to a required temperature to a substrate rotating at a high speed by being disposed on a rotating chuck through a dispenser is known.

However, according to the prior art, there is a problem that a deviation occurs between the actual temperature of the fluid supplied to the surface of the substrate and the process target temperature due to a temperature deviation existing between the surface temperature of the substrate and the temperature of the fluid supplied by the dispenser. do.

In addition, when the substrate disposed on the rotation chuck rotates, since the temperature is lowered while the high-temperature fluid spreads from the center to the edge of the substrate, there is a problem in that the uniformity of the temperature to be maintained with respect to the entire surface of the substrate is broken. .

The decrease in the temperature of the fluid on the surface of the substrate, the deviation from the target temperature, and the temperature non-uniformity on the entire surface of the substrate act as factors degrading the efficiency of the semiconductor process.

Republic of Korea Patent Publication No. 10-2004-0070635 (published date: August 11, 2004, name: process chamber of a rapid heat treatment apparatus capable of uniformly transferring heat to the loaded wafer) Republic of Korea Patent Publication No. 10-2018-0014438 (published date: February 08, 2018, name: electrostatic chuck with LED heating part)

The technical problem of the present invention is to precisely control and maintain the temperature of the substrate while preventing damage to the light source due to overheating of the light source substrate in the process of controlling the temperature of the substrate, which is the processing target of the semiconductor process, using the light source mounted on the light source substrate. An object of the present invention is to provide a substrate processing apparatus using a light source embedded in a rotary chuck.

In addition, the technical problem of the present invention is to divide the light source substrate on which a light source such as LED is mounted into a plurality of driving regions, measure the temperature of each driving region, and control the operation of the light source in units of driving regions according to the temperature measurement result It is an object of the present invention to provide a substrate processing apparatus using a light source built in a rotary chuck capable of precisely controlling and maintaining the temperature of a substrate to be processed in a semiconductor process.

In addition, the technical problem of the present invention is to configure a light source for heating the substrate into a plurality of LED channel groups arranged in a concentric circle, and by controlling whether or not the plurality of LED channel groups operate and the intensity of operation as a whole or individually, the temperature of the substrate An object of the present invention is to provide a substrate processing apparatus using a light source embedded in a rotary chuck that can precisely and quickly control the temperature to a level corresponding to a target temperature in a semiconductor process.

A substrate processing apparatus using a light source built in a rotary chuck according to the present invention for solving these technical problems is a rotary chuck that rotates while supporting a substrate, and is built in the rotary chuck so as not to come into contact with the rotary chuck and is formed by the rotary chuck A heating module including a light source unit for emitting light to the lower surface of the supported and rotating substrate and a light source substrate on which the light source unit is mounted, installed on the light source substrate so as not to overlap the light source unit and measuring the temperature of the light source substrate A measurement unit, a light transmitting plate coupled to the rotary chuck and allowing the light source unit constituting the heating module to pass the light emitted toward the substrate, and a light source unit constituting the heating module to the lower surface of the substrate of light) by controlling the temperature of the substrate, but comparing the temperature of the light source substrate received from the light source substrate temperature measuring unit with a set temperature critical range, and comparing the temperature of the light source substrate with the temperature critical range according to the control module for controlling the operation of the light source constituting the heating module.

In the substrate processing apparatus using the light source built in the rotary chuck according to the present invention, the control module is characterized in that the light source state alarm information is output when the temperature of the light source substrate is out of the temperature threshold range.

In the apparatus for processing a substrate using a light source built in a rotary chuck according to the present invention, the control module controls so that the light emission amount of the light source unit is reduced when the temperature of the light source substrate exceeds an upper temperature limit constituting the temperature critical range. characterized in that

In the substrate processing apparatus using the light source built in the rotary chuck according to the present invention, the control module controls so that the light emission amount of the light source unit is increased when the temperature of the light source substrate is less than the lower limit of the temperature constituting the temperature critical range. characterized.

In the substrate processing apparatus using a light source built in a rotary chuck according to the present invention, a plurality of LEDs constituting the light source unit are mounted in a plurality of driving areas partitioned to be electrically separated from each other on the light source substrate, and the control The module drives the plurality of LEDs constituting the light source unit independently for each of the plurality of driving regions partitioned on the light source substrate, and the light source substrate temperature measuring unit is installed for each of the plurality of driving regions partitioned on the light source substrate. and temperature sensors for measuring the temperature of the light source substrate for each of the plurality of driving regions.

In the apparatus for processing a substrate using a light source built in a rotary chuck according to the present invention, the control module is mounted in a driving region in which the temperature of the light source substrate exceeds an upper temperature limit constituting the temperature critical range among the plurality of driving regions. It is characterized in that the plurality of LEDs are turned off at once.

In the substrate processing apparatus using the light source built in the rotary chuck according to the present invention, the rotary chuck is recessed lower than the outer body and the outer body in which the substrate support portion for supporting the substrate is formed, the heating module is built-in It is characterized in that it includes an inner body that provides a space and a hollow is formed in the central region.

In the substrate processing apparatus using the light source built in the rotary chuck according to the present invention, the light source substrate does not directly contact the inner body of the rotary chuck, but in the built-in space generated by the height difference between the outer body and the inner body. is disposed, and the light source unit includes a plurality of LED channel groups that are arranged in a concentric circle from a central region of an upper surface facing the substrate to an edge region among both surfaces of the light source substrate and are driven independently of each other.

In the substrate processing apparatus using the light source built in the rotary chuck according to the present invention, the heating module has an upper surface coupled to the lower surface of the light source substrate, and a cooling passage through which cooling water for preventing overheating of the light source substrate flows therein It characterized in that it further comprises a heating module support for supporting the light source substrate coupled to the cooling unit while passing through the hollow formed in the inner body constituting the rotary chuck in a state coupled to the cooling unit and the lower surface of the cooling unit. do.

A substrate processing apparatus using a light source built in a rotary chuck according to the present invention includes an inflow coolant temperature measuring unit that measures the temperature of coolant flowing into an inlet, which is one end of the cooling passage, and an outlet that is the other end of the cooling passage. and an outlet coolant temperature measuring unit configured to measure a temperature of the coolant, wherein the control module is configured to include: a temperature of the coolant flowing into the inlet outside a set first reference temperature range or a second temperature of the coolant discharged through the outlet being set It is characterized in that the control so that the coolant status alarm information is output when it is out of the reference temperature range.

In the apparatus for processing a substrate using a light source built in a rotary chuck according to the present invention, the control module controls whether at least one of a plurality of LED channel groups constituting the light source unit operates and the light emission intensity of the LED channel group in operation. characterized in that

In the substrate processing apparatus using the light source built in the rotary chuck according to the present invention, the light source substrate and the cooling unit constituting the heating module are characterized in that they have a thermally conductive material.

In the substrate processing apparatus using the light source built in the rotary chuck according to the present invention, the lower surface of the light source substrate constituting the heating module and the upper surface of the cooling unit are bonded to each other without a space.

In the substrate processing apparatus using the light source built in the rotary chuck according to the present invention, the area of the lower surface of the light source substrate and the upper surface of the cooling unit is the same.

According to the present invention, rotation that can precisely control and maintain the temperature of the substrate while preventing damage to the light source due to overheating of the light source substrate in the process of controlling the temperature of the substrate, which is the processing target of the semiconductor process, using the light source mounted on the light source substrate There is an effect that a substrate processing apparatus using a light source built in a chuck is provided.

In addition, the light source substrate on which a light source such as an LED is mounted is divided into a plurality of driving regions, the temperature of each driving region is measured, and the operation of the light source is controlled in units of the driving region according to the temperature measurement result. There is an effect that a substrate processing apparatus using a light source built in a rotary chuck capable of precisely controlling and maintaining the temperature of the substrate is provided.

In addition, by configuring the light source for heating the substrate with a plurality of LED channel groups arranged in a concentric circle, and controlling whether or not the plurality of LED channel groups operate and the operation intensity as a whole or individually, the temperature of the substrate is adjusted to the target temperature in the semiconductor process. There is an effect that a substrate processing apparatus using a light source built in a rotary chuck that can be precisely and quickly adjusted to a level corresponding to the present invention is provided.

1 is a top view of a substrate processing apparatus using a light source built in a rotary chuck according to an embodiment of the present invention;
2 is a cross-sectional view of a substrate processing apparatus using a light source built in a rotary chuck according to an embodiment of the present invention;
3 is an enlarged view of part A of FIG. 2;
4 is a combined perspective view of a substrate processing apparatus using a light source built in a rotary chuck according to an embodiment of the present invention;
5 is an exploded perspective view of a substrate processing apparatus using a light source built in a rotary chuck according to an embodiment of the present invention;
6 is a view for explaining an exemplary configuration in which the control module controls the light source unit constituting the heating module according to an embodiment of the present invention;
7 is a view for explaining an exemplary configuration in which the control module controls the light source unit according to the temperature of the light source substrate received from the light source substrate temperature measuring unit according to an embodiment of the present invention;
8 is a view showing an exemplary configuration for measuring the temperature of the cooling unit coupled to the light source substrate and the cooling water flowing through the cooling unit according to an embodiment of the present invention.

Specific structural or functional descriptions of the embodiments according to the concept of the present invention disclosed in this specification are only exemplified for the purpose of explaining the embodiments according to the concept of the present invention, and the embodiments according to the concept of the present invention may take various forms. It may be implemented with the above and is not limited to the embodiments described herein.

Since the embodiments according to the concept of the present invention may have various changes and may have various forms, the embodiments will be illustrated in the drawings and described in detail herein. However, this is not intended to limit the embodiments according to the concept of the present invention to specific disclosed forms, and includes all modifications, equivalents, or substitutes included in the spirit and scope of the present invention.

Terms such as first or second may be used to describe various elements, but the elements should not be limited by the terms. The above terms are used only for the purpose of distinguishing one element from another, for example, without departing from the scope of the inventive concept, a first element may be termed a second element and similarly a second element. A component may also be referred to as a first component.

When a component is referred to as being “connected” or “connected” to another component, it may be directly connected or connected to the other component, but it should be understood that other components may exist in between. will be. On the other hand, when it is said that a certain element is "directly connected" or "directly connected" to another element, it should be understood that the other element does not exist in the middle. Other expressions describing the relationship between elements, such as "between" and "immediately between" or "neighboring to" and "directly adjacent to", should be interpreted similarly.

The terms used herein are used only to describe specific embodiments, and are not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise. As used herein, terms such as “comprise” or “have” are intended to designate that a feature, number, step, operation, component, part, or combination thereof described herein is present, but one or more other features It is to be understood that it does not preclude the possibility of the presence or addition of numbers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as commonly used dictionary definitions should be interpreted as having meanings consistent with the meanings in the context of the related art, and unless explicitly defined in the present specification, they are not to be interpreted in an ideal or excessively formal meaning. .

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a top view of a substrate processing apparatus using a light source embedded in a rotation chuck according to an embodiment of the present invention, and FIG. 2 is a substrate processing apparatus using a light source embedded in a rotation chuck according to an embodiment of the present invention. It is a cross-sectional view, FIG. 3 is an enlarged view of part A of FIG. 2 , FIG. 4 is a combined perspective view of a substrate processing apparatus using a light source built in a rotary chuck according to an embodiment of the present invention, and FIG. 5 is the present invention An exploded perspective view of a substrate processing apparatus using a light source built in a rotary chuck according to an embodiment of the present invention, FIG. 6 is a view for explaining an exemplary configuration in which the control module controls the light source unit constituting the heating module, FIG. 7 is It is a view for explaining an exemplary configuration in which the control module controls the light source unit according to the temperature of the light source substrate received from the light source substrate temperature measuring unit, and FIG. 8 is a cooling unit coupled to the light source substrate and measuring the temperature of the cooling water flowing through the cooling unit. It is a diagram showing an exemplary configuration.

1 to 8 , a substrate processing apparatus using a light source embedded in a rotation chuck according to an embodiment of the present invention includes a rotation chuck 10 , a substrate support unit 20 , a heating module 30 , and a light transmitting plate. 40 , a control module 50 and a light source substrate temperature measuring unit 60 .

The rotary chuck 10 is a component that is disposed inside a chamber in which a semiconductor process is performed and rotates at a high speed by a rotational driving force provided by a driving means (not shown) while supporting the substrate W, which is the object of the semiconductor process. Although not shown in the drawings, for example, a dispenser for spraying a chemical for performing a specific semiconductor process is disposed on the rotation chuck 10 by a driving means such as a robot arm, and the substrate W ) may be configured so that the substrate W disposed on the rotary chuck 10 in a state of spraying the chemical toward the upper surface of the rotary chuck 10 rotates at a high speed by the rotation of the rotary chuck 10 .

For example, as illustrated in FIG. 5 , the rotary chuck 10 is recessed lower than the outer body 110 and the outer body 110 in which the substrate support 20 for supporting the substrate W is formed. It provides a space in which the heating module 30 is built and may be configured to include an inner body 120 in which a hollow (H) is formed in the central region.

A plurality of substrate support units 20 are provided along the edge of the outer body 110 of the rotating chuck 10, and the substrate W rotating at high speed by the rotation of the rotating chuck 10 is configured to support so as not to be separated. is an element

For example, the substrate support 20 may be configured such that a support pin 22 and a grip pin 24 form a pair, and the support pin 22 primarily supports the substrate W. The grip pin 24 may be configured to secondaryly support the substrate W by rotating by a predetermined angle in the supporting state. For example, the support pin 22 may be configured such that a protrusion is formed at a point spaced apart from its center point, and when the support pin 22 rotates based on the center point, the protrusion strikes the side surface of the substrate W. By pushing and pressing, the substrate W is stably supported by the grip pins 24 , and thus the substrate W may not be separated from the rotation chuck 10 despite the high-speed rotation of the substrate W. .

The heating module 30 is built in the rotation chuck 10 so as not to come into direct contact with the rotation chuck 10, and the heating module 30 itself is fixed in a chamber (not shown) by the rotation chuck 10 It is a component that uniformly heats the lower surface of the supported and rotated high-speed substrate W by a luminous radiation method.

For example, as illustrated in FIGS. 5, 6 and 7 , the heating module 30 includes a light source substrate 310 , a light source unit 320 , a cooling unit 330 and a heating module support unit 340 . can be configured.

The light source substrate 310 is disposed in the built-in space generated by the height difference between the outer body 110 and the inner body 120 without directly contacting the inner body 120 of the rotary chuck 10 . The light source board 310 is a component on which the light source unit 320 is mounted, and may be, for example, a printed circuit board.

The light source unit 320 is a plurality of LED channel groups that are arranged in a concentric circle from both sides of the light source substrate 310 to the edge region of the upper surface facing the substrate W disposed on the rotary chuck 10 and driven independently of each other. (CH1, CH2, ..., CHn).

The cooling unit 330 functions to prevent overheating of the light source substrate 310 .

5 and 8 , the upper surface of the cooling unit 330 is coupled to the lower surface of the light source substrate 310 , and cooling water for preventing overheating of the light source substrate 310 flows inside the cooling unit 330 . A cooling passage 332 is formed, and an inlet 334 through which the cooling water flows in and an outlet 336 through which the cooling water flows out may be provided at both ends of the cooling passage 332 .

For example, the light source substrate 310 and the cooling unit 330 constituting the heating module 30 may be configured to have a thermally conductive material.

As a specific example, at least the lower surface of the light source substrate 310 and the entire or at least the upper surface of the cooling unit 330 and the cooling passage 332 are made of a material having excellent thermal conductivity, such as metal, and the lower surface of the light source substrate 310 and the The upper surface of the cooling unit 330 is configured to be bonded to each other without a spaced space, and the area of the lower surface of the light source substrate 310 and the upper surface of the cooling unit 330 may be the same.

According to this configuration, by increasing the thermal conductivity between the light source substrate 310 and the cooling unit 330, the temperature of the light source substrate 310 can be rapidly reduced by using the cooling water or cooling gas flowing through the cooling passage 332 .

The heating module support 340 is coupled to the cooling unit 330 while passing through the hollow H formed in the inner body 120 constituting the rotary chuck 10 with one end coupled to the lower surface of the cooling unit 330 . It is a component that supports the light source substrate 310 . The other end of the heating module support part 340 may be coupled to a chamber (not shown) to stably fix and support the heating module 30 . As described above, the light source substrate 310 and the cooling unit 330 bonded to the light source substrate 310 do not directly contact the inner body 120 of the rotary chuck 10 while not directly contacting the outer body 110 and the inner body. Since it is disposed in the built-in space caused by the height difference of 120, the heating module 30 is supported by the heating module support 340 and is coupled to the chamber without moving despite the high-speed rotation of the rotary chuck 10. keep the state stable.

The light source substrate temperature measuring unit 60 is installed on the light source substrate 310 so as not to overlap the light source unit 320 , measures the temperature of the light source substrate 310 , and transmits the measured temperature data to the control module 50 . A detailed and exemplary configuration of the light source substrate temperature measuring unit 60 will be described later in conjunction with the configuration of the light source substrate 310 , the light source unit 320 , and the control module 50 .

The light transmitting plate 40 is coupled to the rotary chuck 10, and the heating module 30 built into the rotary chuck 10 passes the light emitted toward the substrate W, and at the same time, including the chemical solution inside the chamber. Prevents a problem that various materials are introduced into the heating module 30 to contaminate the light source substrate 310 and the light source unit 320 constituting the heating module 30 .

For example, the light transmitting plate 40 may be a circular plate-shaped member having the same diameter as the diameter of the rotating chuck 10, and the outer body of the rotating chuck 10 is located at the edge of the light transmitting plate 40 ( A plurality of grooves curved inwardly so as not to overlap with the plurality of support pins 22 and the grip pins 24 formed on 110 , may be formed in the edge area of the light transmitting plate 40 , except for these grooves. It may be configured to be coupled to the upper surface of the outer body 110 of the rotary chuck 10 .

For example, quartz may be applied as the material of the light transmitting plate 40, but the material of the light transmitting plate 40 is not limited thereto, and any material having excellent light transmittance and excellent heat resistance and corrosion resistance A material may be applied to the light transmitting plate 40 .

The control module 50 controls the temperature of the substrate W by controlling the quantity of light that the light source unit 320 constituting the heating module 30 radiates to the lower surface of the substrate W, but the light source substrate temperature The temperature of the light source substrate 310 received from the measurement unit 60 and the set temperature critical range are compared, and the temperature of the light source substrate 310 measured by the light source substrate temperature measurement unit 60 and the control module 50 are The operation of the light source unit 320 constituting the heating module 30 is controlled according to the comparison result of the set temperature critical range.

Various control operations by the control module 50 will be described as follows.

For example, when the temperature of the light source substrate 310 is out of a temperature threshold range, the control module 50 may control the light source state alarm information to be output.

For example, when the temperature of the light source substrate 310 exceeds an upper temperature limit constituting the critical temperature range, the control module 50 may control the light emission amount of the light source unit 320 to be reduced.

For example, when the temperature of the light source substrate 310 is less than the lower limit of the temperature constituting the critical temperature range, the control module 50 may control the light emission amount of the light source unit 320 to increase.

For example, as illustrated in FIGS. 5 to 7 , the plurality of LEDs constituting the light source unit 320 includes a plurality of driving regions R1 , R2 , R3 partitioned to be electrically separated from each other on the light source substrate 310 . ), and the control module 50 drives the plurality of LEDs constituting the light source unit 320 independently of each other for each of the plurality of driving regions R1, R2, R3 partitioned on the light source substrate 310, The light source substrate temperature measuring unit 60 is installed in each of the plurality of driving regions R1 , R2 , R3 partitioned on the light source substrate 310 to measure the temperature of the light source substrate 310 in the plurality of driving regions R1 , R2 , R3 . ) may include temperature sensors that measure each star.

5 to 7, the light source substrate 310 is divided into a first driving region R1, a second driving region R2, and a third driving region R3, and the light source substrate temperature measuring unit 60 is 1 temperature sensor unit 61, a second temperature sensor unit 62, and a third temperature sensor unit 63, the first temperature sensor unit 61 is a first inner temperature sensor 61-1, 1 is composed of an outer temperature sensor 61-2, and the second temperature sensor unit 62 is composed of a second inner temperature sensor 62-1 and a second outer temperature sensor 62-2, and the third temperature An example of the sensor unit 63 including the third inner temperature sensor 63-1 and the third outer temperature sensor 63-2 is disclosed, but this is only an example, and the division method and the sensor arrangement method are shown in FIG. 5 It is not limited to the example disclosed in FIG. 7 .

For example, if the condition of not obstructing the radiation path of light emitted by the LED constituting the light source unit 320 is satisfied, the sensors constituting the light source substrate temperature measuring unit 60 are the upper or lower surfaces of the light source substrate 310 . can be installed on Reference numeral T61-1 of FIG. 7 denotes temperature data measured by the first inner temperature sensor 61-1 and transmitted to the control module 50, and reference numeral T61-2 denotes the first outer temperature sensor 61-2. ) is temperature data measured by and transmitted to the control module 50, and reference numeral T62-1 is temperature data measured by the second inner temperature sensor 62-1 and transmitted to the control module 50, in the figure Reference numeral T62-2 denotes temperature data measured by the second external temperature sensor 62-2 and transmitted to the control module 50, and reference numeral T63-1 denotes measured by the third internal temperature sensor 63-1. and temperature data transmitted to the control module 50 , and reference numeral T63-2 is temperature data measured by the third external temperature sensor 63-2 and transmitted to the control module 50 .

For example, the control module 50 includes a plurality of LEDs mounted in a driving region in which the temperature of the light source substrate 310 exceeds the upper limit of the temperature constituting the critical temperature range among the plurality of driving regions R1, R2, and R3. It may be configured to turn off all at once.

For example, the control module 50 controls whether one or more of the plurality of LED channel groups (CH1, CH2, ..., CHn) constituting the light source unit 320 operates and the light emission intensity of the LED channel group in operation. can be configured to control.

More specifically, the light source unit 320 is a plurality of LED channel groups (CH1, CH2, ..., CHn) that are uniformly arranged in a concentric circle form from the central area to the edge area of the upper surface of the light source substrate 310 and driven independently of each other. ), and each LED channel group (CH1, CH2, ..., CHn) in the form of a concentric circle is configured to be connected to the control module 50 and an electrically independent channel, and the control module 50 is an LED channel All of the groups CH1, CH2, ..., CHn may be operated, or a part thereof may be operated. In addition, the control module 50 may uniformly control the light emission intensity of the entire LED channel group (CH1, CH2, ..., CHn) or differently for each channel.

5 and 8 , the upper surface of the cooling unit 330 is coupled to the lower surface of the light source substrate 310 , and cooling water for preventing overheating of the light source substrate 310 flows inside the cooling unit 330 . A cooling passage 332 is formed, and an inlet 334 through which the cooling water is introduced and an outlet 336 through which the cooling water is discharged may be provided at both ends of the cooling passage 332 .

The inflow cooling water temperature measuring unit 71 measures the temperature of the cooling water flowing into the inlet 334, which is one end of the cooling passage 332 constituting the cooling unit 330, and transmits it to the control module 50, and the outflow cooling water The temperature measuring unit 72 measures the temperature of the cooling water discharged to the outlet 336 , which is the other end of the cooling passage 332 constituting the cooling unit 330 , and transmits it to the control module 50 .

For example, the control module 50 may determine that the temperature of the coolant flowing into the inlet 334 is outside the set first reference temperature range or the temperature of the coolant discharged through the outlet 336 is outside the set second reference temperature range. In this case, it is possible to control the cooling water status alarm information to be output.

As described in detail above, the temperature of the substrate can be precisely controlled and maintained while preventing damage to the light source due to overheating of the light source substrate in the process of controlling the temperature of the substrate, which is the processing target of the semiconductor process, using the light source mounted on the light source substrate. There is an effect that a substrate processing apparatus using a light source built in a rotary chuck is provided.

In addition, the light source substrate on which a light source such as an LED is mounted is divided into a plurality of driving regions, the temperature of each driving region is measured, and the operation of the light source is controlled in units of the driving region according to the temperature measurement result. There is an effect that a substrate processing apparatus using a light source built in a rotary chuck capable of precisely controlling and maintaining the temperature of the substrate is provided.

In addition, by configuring the light source for heating the substrate with a plurality of LED channel groups arranged in a concentric circle, and controlling whether or not the plurality of LED channel groups operate and the operation intensity as a whole or individually, the temperature of the substrate is adjusted to the target temperature in the semiconductor process. There is an effect that a substrate processing apparatus using a light source built in a rotary chuck that can be precisely and quickly adjusted to a level corresponding to the present invention is provided.

10: rotary chuck
20: substrate support
22: support pin
24: grip pin
30: heating module
40: light transmitting plate
50: control module
60: light source substrate temperature measurement unit
61: first temperature sensor unit
61-1: first inner temperature sensor
61-2: first outside temperature sensor
62: second temperature sensor unit
62-1: second inner temperature sensor
62-2: second outer temperature sensor
63: third temperature sensor
63-1: third inner temperature sensor
63-2: third outer temperature sensor
71: inlet coolant temperature measurement unit
72: effluent coolant temperature measurement unit
110: outer body
120: inner body
310: light source substrate
320: light source unit
330: cooling unit
332: cooling flow path
334: inlet
336: outlet
340: heating module support
CH1, CH2, ..., CHn: LED channel group
H: hollow
R1: first driving region
R2: second driving region
R3: third driving region
W: substrate

Claims (14)

A substrate processing apparatus using a light source built in a rotary chuck, comprising:
a rotary chuck that rotates while supporting the substrate;
a heating module including a light source unit embedded in the rotating chuck so as not to contact the rotating chuck and emitting light to a lower surface of a rotating substrate supported by the rotating chuck and a light source substrate mounted thereon;
a light source substrate temperature measuring unit installed on the light source substrate so as not to overlap the light source unit and measuring a temperature of the light source substrate;
a light transmission plate coupled to the rotary chuck and passing light emitted from the light source unit constituting the heating module toward the substrate; and
The light source unit constituting the heating module controls the temperature of the substrate by controlling the quantity of light emitted to the lower surface of the substrate, but the temperature of the light source substrate received from the light source substrate temperature measuring unit and the set temperature threshold and a control module for comparing the ranges and controlling the operation of the light source unit constituting the heating module according to the comparison result between the temperature of the light source substrate and the temperature critical range. According to claim 1,
Wherein the control module controls the light source state alarm information to be output when the temperature of the light source substrate is out of the temperature critical range. According to claim 1,
The control module is a substrate processing apparatus using a light source embedded in a chuck, characterized in that when the temperature of the light source substrate exceeds an upper temperature limit constituting the temperature critical range, the light emission amount of the light source unit is controlled to decrease. 4. The method of claim 3,
The control module is a substrate processing apparatus using a light source embedded in a chuck, characterized in that when the temperature of the light source substrate is less than the lower temperature limit constituting the temperature critical range, the light emission amount of the light source unit is controlled to increase. According to claim 1,
The plurality of LEDs constituting the light source unit is mounted on the light source substrate in a plurality of driving regions partitioned to be electrically separated from each other,
The control module drives the plurality of LEDs constituting the light source unit independently for each of the plurality of driving regions partitioned on the light source substrate,
The light source substrate temperature measuring unit is installed in each of the plurality of driving regions partitioned on the light source substrate, characterized in that it comprises temperature sensors for measuring the temperature of the light source substrate for each of the plurality of driving regions, substrate processing apparatus used. 6. The method of claim 5,
The control module is
Among the plurality of driving regions, a plurality of LEDs mounted in a driving region in which the temperature of the light source substrate exceeds an upper temperature limit constituting the temperature critical range is turned off at once. substrate processing equipment. According to claim 1,
The rotary chuck is
an outer body in which a substrate support for supporting the substrate is formed; and
A substrate processing apparatus using a light source built in a rotary chuck, characterized in that it includes an inner body that is recessed lower than the outer body to provide a space in which the heating module is built and a hollow is formed in a central region. 8. The method of claim 7,
The light source substrate is disposed in a built-in space generated by a height difference between the outer body and the inner body without directly contacting the inner body of the rotary chuck,
Wherein the light source unit comprises a plurality of LED channel groups which are arranged in a concentric circle form from the central region to the edge region of the upper surface facing the substrate among both sides of the light source substrate and are driven independently of each other, the light source built in the rotation chuck substrate processing apparatus using 9. The method of claim 8,
The heating module,
a cooling unit having an upper surface coupled to a lower surface of the light source substrate and having a cooling passage through which cooling water flows to prevent overheating of the light source substrate; and
Built in the rotating chuck, characterized in that it further comprises a heating module support for supporting the light source substrate coupled to the cooling unit while passing through the hollow formed in the inner body constituting the rotating chuck in a state coupled to the lower surface of the cooling unit A substrate processing apparatus using a light source. 10. The method of claim 9,
an inflow cooling water temperature measuring unit for measuring a temperature of the cooling water flowing into an inlet that is one end of the cooling passage; and
Further comprising an outlet cooling water temperature measuring unit for measuring the temperature of the cooling water discharged to the outlet which is the other end of the cooling passage,
The control module is
Controlling the cooling water status alarm information to be output when the temperature of the coolant flowing into the inlet is out of a set first reference temperature range or when the temperature of the coolant discharged to the outlet is out of a set second reference temperature range, A substrate processing apparatus using a light source built into a chuck. 9. The method of claim 8,
The control module is
A substrate processing apparatus using a light source built in a rotary chuck, characterized in that it controls whether at least one of the plurality of LED channel groups constituting the light source unit operates and the light emission intensity of the LED channel group in operation. 10. The method of claim 9,
A substrate processing apparatus using a light source built in a rotary chuck, characterized in that the light source substrate and the cooling unit constituting the heating module have a thermally conductive material. 13. The method of claim 12,
A substrate processing apparatus using a light source built in a rotary chuck, characterized in that the lower surface of the light source substrate constituting the heating module and the upper surface of the cooling unit are bonded to each other without a separation space. 14. The method of claim 13,
A substrate processing apparatus using a light source built in a rotary chuck, characterized in that the area of the lower surface of the light source substrate and the upper surface of the cooling unit is the same.

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