KR102309272B1 - Substrate drying chamber - Google Patents

Abstract

A substrate drying chamber according to the present invention includes: an upper housing; a lower housing that is coupled to the upper housing to be opened or closed; a substrate mounting board coupled to the lower housing and having a first outer protrusion area and a second outer protrusion area formed on both outer sides of the upper surface facing the upper housing, in which a recessed area lower than the first outer protruding area and the second outer protrusion area and having a rectangular groove shape is formed between the first outer protrusion area and the second outer protrusion area; a substrate support part having one end coupled to the first outer protruding area or the second outer protruding area of the substrate mounting board and the other end coupled to the substrate carried in by a robot hand to support the substrate while separating the substrate from the upper surface of the substrate mounting board; an integrated supply/discharge port extending from one side of the lower housing to the other side of the lower housing, and configured to face the substrate mounting board in the middle region between the one side and the other side to provide a supply path of supercritical fluid for initial pressurization and a discharge path of mixed fluid in which an organic solvent formed on the substrate after drying is dissolved; and an upper supply port on the central region of the upper housing to face the substrate mounting board to provide a supply path of the supercritical fluid for drying. According to the present invention, it is possible to increase the throughput of the supercritical drying process and reduce the processing time by minimizing the excess space inside the chamber while enabling the robot hand to perform the operation for loading or unloading the substrate in the supercritical drying process.

Description

Substrate drying chamber {SUBSTRATE DRYING CHAMBER}

The present invention relates to a substrate drying chamber. More specifically, the present invention enables the operation of the robot hand for loading and unloading substrates in the supercritical drying process while minimizing the surplus space inside the chamber to increase the throughput of the supercritical drying process and process time It relates to a substrate drying chamber that can reduce the

The semiconductor device manufacturing process includes various processes such as a lithography process, an etching process, and an ion implantation process. After each process, before moving to the next process, impurities and residues remaining on the surface of the substrate are removed to remove A cleaning process and a drying process for cleaning the surface are being performed.

For example, in the cleaning treatment of the substrate after the etching process, a chemical solution for the cleaning treatment is supplied to the surface of the substrate, and thereafter, deionized water (DIW) is supplied to perform a rinse treatment. After the rinse treatment, a drying treatment of drying the substrate by removing the deionized water remaining on the surface of the substrate is performed.

As a method of performing the drying treatment, for example, a technique of drying the substrate by replacing deionized water on the substrate with isopropyl alcohol (IPA) is known.

However, according to this conventional drying technique, as shown in FIG. 1 , during the drying process, a pattern formed on a substrate such as a wafer is collapsed due to the surface tension of the liquid IPA.

In order to solve this problem, a supercritical drying technique in which the surface tension becomes zero has been proposed.

According to this supercritical drying technique, IPA on the substrate is dissolved in the _{supercritical carbon dioxide (CO 2} ) fluid by supplying carbon dioxide in a supercritical state to the substrate whose surface is wetted with isopropyl alcohol (IPA) in a chamber. In addition, the supercritical carbon dioxide (CO ₂ ) fluid dissolving the IPA is gradually discharged from the chamber, thereby drying the substrate without destroying the pattern.

FIG. 2 shows a substrate processing chamber disclosed in Korean Patent Application Laid-Open No. 10-2017-0137243, which is a prior art related to a substrate processing apparatus using such a supercritical fluid.

Referring to FIG. 2 , in the process of removing the organic solvent in the supercritical drying process, the organic solvent may be introduced into the contact bonding surface of the upper body 430 and the lower body 420 constituting the high-pressure chamber 410 . . In this way, the organic solvent introduced into the coupling surface of the upper body 430 and the lower body 420 becomes particles and accumulates around them.

After the supercritical drying process is finished, the chamber is opened to transport the treated substrate to the outside, and at this time, due to the pressure difference between the inside and outside of the chamber, particles around the bonding surface of the upper body 430 and the lower body 420 . may be introduced into the chamber.

According to Korean Patent Application Laid-Open No. 10-2017-0137243, since the substrate is located below the coupling surface of the upper body 430 and the lower body 420, the coupling surface of the upper body 430 and the lower body 420 is provided. There is a high possibility that some of the particles are introduced into the substrate due to gravity while the surrounding particles are introduced into the chamber.

In this way, since particles flowing into the substrate cause process defects, there is a need to additionally install a blocking film around the coupling surface of the upper body 430 and the lower body 420 to prevent the inflow of particles, Accordingly, there is a problem in that the overall structure of the device becomes complicated.

In addition, according to the prior art including Korean Patent Application Laid-Open No. 10-2017-0137243 No., a lower supply port 422 for supplying a supercritical fluid for initial pressurization, an exhaust port for exhausting the supercritical fluid after drying ( 426) is not located in the center of the lower body 420, thereby forming an asymmetrical flow when supplying and discharging the fluid, so that it is difficult to uniformly disperse the supercritical fluid in the chamber to supply and discharge it, and this reduces the drying efficiency problems arise.

In addition, according to the prior art including Korean Patent Application Laid-Open No. 10-2017-0137243, when the temperature inside the chamber becomes less than the critical point for maintaining the supercritical state in the process of supplying the supercritical fluid for drying, the pattern formed on the substrate In the drying process of dissolving the organic solvent wetted in the supercritical fluid and discharging to the outside, the pattern formed on the substrate may be destroyed, and there is a problem in that the supercritical drying efficiency is lowered.

On the other hand, before and after supercritical drying, that is, when the supercritical drying process is started or the supercritical drying process is completed, the substrate is brought into the chamber by using a substrate transfer robot and taken out to the outside.

In order to enable the loading and unloading of the substrate, a space corresponding to the volume of the robot hand constituting the substrate transfer robot under the substrate inside the chamber, that is, the volume occupied by the robot hand and the control of the robot hand A space including the free space margin is required. This space occupies about 30% or more of the working volume of the chamber. During drying, the internal volume of the chamber is closely related to the throughput, and as the internal volume increases, the processing time increases and the throughput decreases.

Republic of Korea Patent Publication No. 10-2017-0137243 (published date: December 13, 2017, title: substrate processing apparatus and method)

The technical problem of the present invention is to reduce the surplus space except for the space essential for performing the supercritical drying process among the internal volume of the chamber in which the supercritical drying process is performed, thereby reducing the throughput of the supercritical drying process. ) and reduce the processing time.

Specifically, in the lower part of the substrate disposed inside the chamber in which the supercritical drying process is performed, a space corresponding to the volume of the robot hand constituting the substrate transfer robot, that is, the volume occupied by the robot hand and the robot hand control and A space is required that includes the associated free space margin. This space occupies about 30% or more of the working volume of the chamber. This space is only needed in the process of bringing the substrate into and out of the chamber using the robot hand, and in terms of the supercritical drying process excluding the loading and unloading of the substrate, the efficiency of the supercritical drying process is lowered. act as a triggering factor. That is, there is a problem in that the throughput of the supercritical drying process is reduced and the process time is increased due to the space.

The present invention is to solve this problem, and the technical problem of the present invention is to enable the operation of the robot hand for loading and unloading the substrate in the supercritical drying process and at the same time minimize the surplus space inside the chamber for supercritical drying This is to increase the throughput of the process and reduce the process time.

In addition, the technical problem of the present invention is to provide a supply path of the supercritical fluid for initial pressurization and a discharge path of the supercritical fluid in which the organic solvent formed on the substrate after drying is dissolved through one integrated supply/discharge port, so that the supercritical fluid It is to increase the substrate drying efficiency by inducing a symmetrical flow when supplying and discharging the supercritical fluid and uniformly dispersing it in the chamber to supply and discharge it.

In addition, the technical problem of the present invention is to block particles re-introduced when the chamber is opened after completion of the drying process by using the substrate placement plate, which is essential for arranging the substrate, and initial pressure directed directly to the surface of the substrate at the beginning of the drying process. Prevents the collapse of the pattern formed on the substrate by preventing the flow of the supercritical fluid for initial pressurization, prevents the problem of particles that may be contained in the supercritical fluid for initial pressurization, or reduces the deposition amount on the substrate, The drying process time is shortened by reducing the working volume of the chamber due to the volume.

In addition, the technical problem of the present invention is to place the substrate on the substrate mounting plate so as to be positioned higher than the coupling surface of the lower housing and the upper housing, so that when the drying process is completed and the chamber is opened, it is provided on the coupling surface of the lower housing and the upper housing It is a technical task to prevent the particles around the sealing part from flowing into the substrate due to gravity according to the height difference between the substrate and the bonding surface.

The substrate drying chamber according to the present invention for solving the above technical problem includes an upper housing, a lower housing operably coupled to the upper housing, and a first outer periphery on both sides of an upper surface coupled to the lower housing and facing the upper housing. A protrusion area and a second outer protrusion area are formed, and a rectangular groove is formed between the first outer protrusion area and the second outer protrusion area and has a height lower than that of the first outer protrusion area and the second outer protrusion area. A substrate arrangement plate having a recessed region having a shape formed therein, one end is coupled to the first or second outer protrusion region of the substrate arrangement plate, and the other end is coupled to the substrate loaded by the robot hand to support the substrate A substrate support portion for spacing the substrate apart from the upper surface of the substrate placement plate, extending from one side to the other side of the lower housing, and formed to face the substrate placement plate in an intermediate region between the one side and the other side. An integrated supply/discharge port that provides a supply path of the supercritical fluid for pressurization and a discharge path of the mixed fluid in which the organic solvent formed on the substrate is dissolved after drying, and a central region of the upper housing toward the substrate arrangement plate and an upper supply port providing a supply path of the supercritical fluid for drying.

In the substrate drying chamber according to the present invention, an internal working volume is reduced by the first outer protruding region and the second outer protruding region formed on the upper surface of the substrate arrangement plate, so that the drying process time is shortened. do.

In the substrate drying chamber according to the present invention, the robot hand enters and exits the carry-in/out space existing between the lower surface of the substrate and the recessed area formed on the upper surface of the substrate arrangement plate to carry the substrate into the substrate support unit or It characterized in that the substrate is carried out from the substrate support.

In the substrate drying chamber according to the present invention, the separation distance between the lower surface of the substrate and the recessed area is greater than the separation distance between the lower surface of the substrate and the first outer protruding area or the second outer protruding area.

In the substrate drying chamber according to the present invention, a lower surface facing the lower housing among both surfaces of the substrate arrangement plate is characterized in that it has a flat shape.

In the substrate drying chamber according to the present invention, a lower surface facing the lower housing among both surfaces of the substrate arrangement plate has a cone shape inclined toward the middle region of the lower housing.

In the substrate drying chamber according to the present invention, the integrated supply/discharge port includes a first conduit formed from one side of the lower housing to the intermediate region, and is communicated with the first conduit in the intermediate region to communicate with the substrate arrangement plate. It characterized in that it comprises a common port portion formed to face and a second conduit portion formed to the other side of the lower housing in communication with the common port portion and the first conduit portion in the intermediate region.

In the substrate drying chamber according to the present invention, the first conduit portion and the common port portion provide a supply path of the supercritical fluid for initial pressurization, and the common port portion and the second conduit portion are mixed in which the organic solvent is dissolved. It is characterized in that it provides a discharge path of the fluid.

In the substrate drying chamber according to the present invention, the supercritical fluid for initial pressurization supplied through the first conduit portion and the common port portion is blocked by the substrate arrangement plate to prevent direct injection to the substrate.

The substrate drying chamber according to the present invention further includes a sealing part provided on a coupling surface of the lower housing and the upper housing, and the substrate is disposed on the substrate arrangement plate to be positioned higher than the coupling surface of the lower housing and the upper housing. When the drying process is completed and the lower housing and the upper housing are opened, the particles around the sealing part provided on the coupling surface are moved to the substrate by gravity according to the height difference between the substrate and the coupling surface. It is characterized in that the inflow is prevented.

In the substrate drying chamber according to the present invention, one end is coupled to the bottom surface of the lower housing and the other end is coupled to the substrate placement plate, and the substrate placement plate is spaced apart from the bottom surface of the lower housing while supporting the substrate placement plate. It characterized in that it further comprises a substrate arrangement plate support.

In the substrate drying chamber according to the present invention, the first separation space existing between the bottom surface of the lower housing and the substrate placement plate by the substrate placement plate support part is for initial pressurization supplied through the integrated supply/discharge port. It is characterized in that the supercritical fluid moves along the lower surface of the substrate arrangement plate to induce it to gradually diffuse into the processing area on which the substrate is disposed.

In the substrate drying chamber according to the present invention, the second separation space existing between the upper surface of the substrate arrangement plate and the substrate by the substrate support part is the initial pressure supplied to the lower surface of the substrate through the integrated supply/discharge port. It is characterized in that it shortens the drying process time by exposing it to the supercritical fluid for drying and the supercritical fluid for drying supplied through the upper supply port.

According to the present invention, by reducing the surplus space excluding the space essential for performing the supercritical drying process among the internal volume of the chamber in which the supercritical drying process is performed, the throughput of the supercritical drying process (throughput) can be increased and the processing time can be reduced.

Specifically, in the lower part of the substrate disposed inside the chamber in which the supercritical drying process is performed, a space corresponding to the volume of the robot hand constituting the substrate transfer robot, that is, the volume occupied by the robot hand and the robot hand control and A space is required that includes the associated free space margin. This space occupies about 30% or more of the working volume of the chamber. This space is only needed in the process of bringing the substrate into and out of the chamber using the robot hand, and in terms of the supercritical drying process excluding the loading and unloading of the substrate, the efficiency of the supercritical drying process is lowered. act as a triggering factor. That is, there is a problem in that the throughput of the supercritical drying process is reduced and the process time is increased due to the space.

The present invention is to solve this problem, and according to the present invention, it is possible to perform the operation of the robot hand for loading and unloading the substrate in the supercritical drying process, and at the same time, by minimizing the surplus space inside the chamber, the supercritical drying process It is possible to increase the throughput (throughput) and reduce the processing time.

In addition, by providing the supply path of the supercritical fluid for initial pressurization and the discharge path of the supercritical fluid in which the organic solvent formed on the substrate after drying is dissolved through one integrated supply/discharge port, the supply and discharge of the supercritical fluid are symmetrical. The substrate drying efficiency can be increased by supplying and discharging the supercritical fluid by inducing a positive flow to uniformly disperse the supercritical fluid inside the chamber.

In addition, the flow of supercritical fluid for initial pressurization directed directly to the surface of the substrate at the beginning of the drying process by blocking particles re-introduced when the chamber is opened after completion of the drying process by using the substrate placement plate, which is essential for arranging the substrate prevents the collapse of the pattern formed on the substrate by preventing The drying process time can be shortened by reducing the working volume.

In addition, when the drying process is completed and the chamber is opened by disposing the substrate on the substrate placing plate to be positioned higher than the coupling surface of the lower housing and the upper housing, particles around the sealing part provided on the coupling surface of the lower housing and the upper housing It is possible to prevent a problem from flowing into the substrate due to gravity according to the height difference between the substrate and the bonding surface.

1 is a view showing a pattern collapse phenomenon that occurs in a substrate drying process according to the prior art;
2 is a view showing a conventional substrate drying chamber,
3 is a view showing a substrate drying chamber according to an embodiment of the present invention,
4 is a view showing an exemplary external shape of a substrate arrangement plate according to an embodiment of the present invention;
5 is a view showing the robot hand entering and exiting the carry-in/out space existing on the recessed area between the first outer protruding area and the second outer protruding area formed on the upper surface of the substrate arrangement plate to remove the substrate according to an embodiment of the present invention. It is a drawing for explaining the configuration for carrying in or carrying out by way of example,
6 is a view showing an exemplary cross-sectional shape of a substrate arrangement plate according to an embodiment of the present invention,
7 is a view showing another exemplary cross-sectional shape of a substrate arrangement plate according to an embodiment of the present invention,
8 is a view showing a diffusion path of a supercritical fluid for initial pressurization in an embodiment of the present invention;
9 is a view showing a diffusion path of a supercritical fluid for drying in an embodiment of the present invention;
10 is a view showing a discharge path of a mixed fluid in which an organic solvent is dissolved in an embodiment of the present invention;
11 is a diagram illustrating a sealing portion provided on a coupling surface of an upper housing and a lower housing and a substrate of particles present in the vicinity thereof when the drying process is completed and the lower housing and the upper housing are opened according to an embodiment of the present invention; It is a diagram for explaining the principle of preventing the inflow of.

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 can 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.

Figure 3 is a view showing a substrate drying chamber according to an embodiment of the present invention, Figure 4 is a view showing an exemplary external shape of the substrate arrangement plate, Figure 5 is a robot hand formed on the upper surface of the substrate arrangement plate It is a view for exemplarily explaining a configuration in which a substrate is brought in or taken out by entering and exiting the carry-in/out space existing on the recessed area between the first outer protruding area and the second outer protruding area, and FIG. 6 is one of the substrate arrangement plates. is a view showing an exemplary cross-sectional shape of , FIG. 7 is a view showing another exemplary cross-sectional shape of the substrate arrangement plate, FIG. 8 is a view showing the diffusion path of the supercritical fluid for initial pressurization, and FIG. 9 is a drying candle It is a view showing the diffusion path of the critical fluid, FIG. 10 is a view showing the discharge path of the mixed fluid in which the organic solvent is dissolved, and FIG. 11 is the upper housing and the lower part when the drying process is completed and the lower housing and the upper housing are opened It is a view for explaining the principle of preventing the inflow of the sealing part provided on the coupling surface of the housing and the particles existing in the vicinity to the substrate.

3 to 11 , the substrate drying chamber 1 according to an embodiment of the present invention includes an upper housing 10 , a lower housing 20 , a sealing part 30 , a substrate arrangement plate 40 , and an integrated body. It includes a supply/discharge port 50 , an upper supply port 60 , a substrate placement plate support part 70 , a substrate support part 80 , and a housing driving part 90 .

The upper housing 10 and the lower housing 20 are connected to each other so as to open and close, and provide a space in which the drying process is performed. For example, the upper housing 10 and the lower housing 20 may be configured to have a cylindrical shape, but is not limited thereto. As will be described later, an upper supply port 60 is formed in the upper housing 10 , and an integrated supply/discharge port 50 is formed in the lower housing 20 .

The sealing part 30 is provided on the coupling surface C of the lower housing 20 and the upper housing 10, and maintains the airtightness of the coupling surface C of the lower housing 20 and the upper housing 10. The inner area of the substrate drying chamber 1 is blocked from the outside.

For example, when the drying process is completed and the lower housing 20 and the upper housing 10 are opened, the sealing part 30 provided on the coupling surface C of the upper housing 10 and the lower housing 20 . And as illustrated in FIG. 11 for explaining the principle of preventing the inflow of particles existing around the substrate W into the substrate W, the substrate W is the coupling surface of the lower housing 20 and the upper housing 10 . It is disposed on the substrate arrangement plate 40 so as to be positioned higher than (C), and when the drying process is completed and the lower housing 20 and the upper housing 10 are opened, the sealing part provided on the coupling surface (C) (30) The surrounding particles may be configured to prevent inflow into the substrate (W) by gravity according to the height difference between the substrate (W) and the coupling surface (C).

The substrate arrangement plate 40 is coupled to the lower housing 20 and is a component on which the substrate W on which the organic solvent is formed is disposed.

As described above, in the lower portion of the substrate W disposed inside the substrate drying chamber 1 in which the supercritical drying process is performed, a space corresponding to the volume of the robot hand RH constituting the substrate transfer robot, that is, the robot A space including the volume occupied by the hand RH and the free space margin related to the control of the robot hand RH is required. This space occupies about 30% or more of the working volume of the substrate drying chamber 1 . This space is only necessary in the process of carrying in the substrate (W) into and out of the substrate drying chamber (1) using the robot hand (RH), and from the viewpoint of the supercritical drying process excluding the loading and unloading of the substrate (W) In the case of , it acts as a factor to reduce the efficiency of the supercritical drying process. That is, there is a problem in that the throughput of the supercritical drying process is reduced and the process time is increased due to the space.

One embodiment of the present invention is to solve this problem, and by optimizing the shape of the substrate arrangement plate 40, the operation of the robot hand RH for loading and unloading the substrate W in the supercritical drying process is performed. It is configured to increase the throughput and reduce the processing time of the supercritical drying process by enabling and minimizing the surplus space inside the substrate drying chamber 1 at the same time.

As an example of such a configuration, referring to FIGS. 4 to 7 , a first outer protruding region 44-1 and a second outer protruding region 44-1 and a second outer periphery are located on both sides of the upper surface facing the upper housing 10 among both surfaces of the substrate arrangement plate 40 . A protrusion area 44-2 is formed, and a first outer protrusion area 44-1 and a second outer protrusion area 44-1 and a second outer protrusion area 44-1 are formed between the first outer protrusion area 44-1 and the second outer protrusion area 44-2. A recessed region 42 having a lower height than the region 44-2 and having a rectangular groove shape is formed.

For example, the separation distance between the lower surface of the substrate W and the recessed region 42 is the separation distance between the lower surface of the substrate W and the first outer protruding region 44-1 or the second outer protruding region 44-2. It may be configured to be larger.

The substrate support part 80 has one end coupled to the first outer protruding region 44-1 or the second outer protruding region 44-2 of the substrate arrangement plate 40, and the other end is loaded by the robot hand RH. It is coupled to the substrate (W). The substrate support 80 separates the substrate W from the upper surface of the substrate arrangement plate 40 while supporting the substrate W.

For example, the working volume of the substrate drying chamber 1 is increased by the first outer protruding area 44 - 1 and the second outer protruding area 44 - 2 formed on the upper surface of the substrate arrangement plate 40 . This can be reduced so that the time of the drying process can be shortened.

For example, the robot hand RH enters and exits the carry-in/out space R that exists between the lower surface of the substrate W and the recessed region 42 formed on the upper surface of the substrate arrangement plate 40 to move the substrate W. may be configured to load into the substrate support unit 80 or transport the substrate W out of the substrate support unit 80 .

As an example, as illustrated in FIG. 6 , a lower surface facing the lower housing 20 among both surfaces of the substrate arrangement plate 40 may be configured to have a flat shape.

As another example, as illustrated in FIG. 7 , the lower surface facing the lower housing 20 among both surfaces of the substrate arrangement plate 40 has a cone shape inclined toward the middle region 28 of the lower housing 20 . can be configured to have.

For example, the supercritical fluid for initial pressurization supplied through the first conduit portion 510 and the common port portion 520 constituting the integrated supply/discharge port 50 is blocked by the substrate arrangement plate 40 and the substrate ( Direct injection into W) may be prevented.

More specifically, as illustrated in FIG. 8 showing the diffusion path of the supercritical fluid for initial pressurization and FIG. 10 showing the discharge path of the mixed fluid in which the organic solvent is dissolved, in order to place the substrate W, the target of the drying process. Block particles re-introduced when the substrate drying chamber 1 is opened after the completion of the drying process by using the essential substrate arrangement plate 40, and the initial pressure candle directed directly to the surface of the substrate W at the beginning of the drying process It is possible to prevent the collapse of the pattern formed on the substrate (W) by preventing the flow of the critical fluid, and to prevent the problem of particles that may be contained in the supercritical fluid for initial pressurization being deposited on the substrate (W) or to reduce the amount of deposition The drying process time can be shortened by reducing the internal volume of the substrate drying chamber 1 due to the volume occupied by the substrate arrangement plate 40 .

The integrated supply/discharge port 50 is formed to extend from one side 24 to the other side 26 of the lower housing 20 , and the substrate is disposed in the middle region 28 of the one side 24 and the other side 26 . It is formed to face the plate 40 and is a component that provides a supply path of the supercritical fluid for initial pressurization and a discharge path of the mixed fluid in which the organic solvent formed on the substrate W after drying is dissolved.

By providing the supply path of the supercritical fluid for initial pressurization and the discharge path of the mixed fluid in which the organic solvent formed on the substrate W after drying through one integrated supply/discharge port 50 is provided, the supply of the supercritical fluid And by inducing a symmetrical flow when the mixed fluid is discharged, the supercritical fluid is uniformly distributed in the substrate drying chamber 1 and supplied, and the substrate drying efficiency can be increased by discharging the mixed fluid.

For example, this integrated supply/discharge port 50 is a first conduit portion 510 formed from one side 24 of the lower housing 20 to the intermediate region 28, and the first in the intermediate region 28. The lower housing is in communication with the common port part 520 and the first conduit part 510 in communication with the conduit part 510 and the common port part 520 and the intermediate area 28 formed to face the substrate arrangement plate 40 . (20) including a second pipe section 530 formed up to the other side 26, the first pipe section 510 and the common port section 520 provide a supply path of the supercritical fluid for initial pressurization, The common port 520 and the second conduit 530 may be configured to provide a discharge path of the mixed fluid in which the organic solvent is dissolved.

The upper supply port 60 is a component that is formed to face the substrate arrangement plate 40 in the central region of the upper housing 10 to provide a supply path of the supercritical fluid for drying.

The substrate placement plate support part 70 has one end coupled to the bottom surface 22 of the lower housing 20 and the other end coupled to the substrate placement plate 40, while supporting the substrate placement plate 40, the substrate placement plate ( 40) from the bottom surface 22 of the lower housing 20.

For example, the first separation space (R1) existing between the bottom surface 22 of the lower housing 20 and the substrate placement plate 40 by the substrate placement plate support part 70 is an integrated supply/discharge port 50 ) may perform a function of inducing that the supercritical fluid for initial pressurization supplied through the substrate moves along the lower surface of the substrate placement plate 40 and gradually diffuses into the processing area on which the substrate W is disposed.

One end of the substrate support 80 is coupled to the outer region 44 formed on the upper surface of the substrate arrangement plate 40 and the other end is coupled to the substrate W loaded by the robot hand RH. The substrate support part 80 is a component that supports the substrate W and separates the substrate W from the upper surface of the substrate arrangement plate 40 .

For example, the second separation space (R2) existing between the upper surface of the substrate arrangement plate 40 and the substrate (W) by the substrate support part (80) forms the lower surface of the substrate (W) through the integrated supply/discharge port ( 50) performs a function of shortening the drying process time by exposing it to the supercritical fluid for initial pressurization supplied through and the supercritical fluid for drying supplied through the upper supply port 60 .

The housing driving unit 90 is a means for opening and closing the housing, and after the drying process is completed, the lower housing 20 is driven to separate the lower housing 20 from the upper housing 10 to open the substrate drying chamber 1 or , when the drying process is started, the lower housing 20 is driven to couple the lower housing 20 to the upper housing 10 to close the substrate drying chamber 1 . In the drawings, the housing driving unit 90 is expressed as driving the lower housing 20 , but this is only an example, and the housing driving unit 90 may be configured to drive the upper housing 10 .

For example, the supercritical fluid for initial pressurization and the supercritical fluid for drying may include carbon dioxide (CO ₂ ), and the organic solvent may include alcohol, but is not limited thereto. As a specific example, the alcohol may include methanol, ethanol, 1-propanol (1-propanol), 2-propanol (IPA), and 1-butanol (1-butanol). not limited

For example, according to the supercritical drying technique performed in the substrate drying chamber 1 for drying the substrate according to an embodiment of the present invention, the surface of the substrate is wetted with an organic solvent such as alcohol in the substrate drying chamber 1 . By supplying carbon dioxide in a supercritical state to (W), the alcohol on the substrate is dissolved in the supercritical carbon dioxide fluid. In addition, by gradually discharging the carbon dioxide fluid in which the alcohol is dissolved from the substrate drying chamber 1 , the substrate W can be dried without destroying the pattern.

1: substrate drying chamber
10: upper housing
20: lower housing
22: bottom surface
24: one side
26: the other side
28: middle area
30: sealing part
40: substrate placement plate
42: depression area
44-1: first outer protrusion area
44-2: second outer protrusion area
50: integrated supply/discharge port
60: upper supply port
70: substrate arrangement plate support part
80: substrate support
90: housing drive unit
510: first conduit unit
520: common port part
530: second conduit unit
C: mating surface
R: Import/export space
R1: first separation space
R2: second separation space
RH: Robot Hand
W: substrate

Claims (13)

upper housing;
a lower housing operably coupled to the upper housing;
It is coupled to the lower housing and has a first outer protrusion region and a second outer protrusion region formed on both sides of an upper surface facing the upper housing, and the first outer protrusion region and the second outer protrusion region are disposed between the first outer protrusion region and the second outer protrusion region. a substrate arrangement plate having an outer protruding area and a recessed area lower than the second outer protruding area and having a rectangular groove shape;
One end is coupled to the first outer protruding region or the second outer protruding region of the substrate arrangement plate, and the other end is coupled to the substrate carried in by the robot hand to support the substrate while separating the substrate from the upper surface of the substrate arrangement plate substrate support;
The organic formed on the substrate after the supply path of the supercritical fluid for initial pressurization and drying is formed to extend from one side to the other side of the lower housing and to face the substrate arrangement plate in an intermediate region between the one side and the other side. an integrated supply/discharge port providing a discharge path of the mixed fluid in which the solvent is dissolved; and
and an upper supply port formed to face the substrate arrangement plate in the central region of the upper housing and providing a supply path of the supercritical fluid for drying.
According to claim 1,
The substrate drying chamber, characterized in that the internal volume (working volume) is reduced by the first outer protruding region and the second outer protruding region formed on the upper surface of the substrate arrangement plate, thereby shortening the drying process time.
According to claim 1,
The robot hand enters and exits the carry-in/out space existing between the lower surface of the substrate and the recessed area formed on the upper surface of the substrate arrangement plate to load the substrate into the substrate support unit or to unload the substrate from the substrate support unit. to the substrate drying chamber.
According to claim 1,
The substrate drying chamber, characterized in that the separation distance between the lower surface of the substrate and the recessed area is greater than the separation distance between the lower surface of the substrate and the first outer protruding area or the second outer protruding area.
According to claim 1,
Among both surfaces of the substrate arrangement plate, a lower surface facing the lower housing has a flat shape, the substrate drying chamber.
According to claim 1,
A substrate drying chamber, characterized in that the lower surface facing the lower housing among both surfaces of the substrate arrangement plate has a cone shape inclined toward the middle region of the lower housing.
According to claim 1,
The integrated supply/discharge port is
a first conduit portion formed from one side of the lower housing to the middle region;
a common port portion communicating with the first conduit portion in the intermediate region to face the substrate arrangement plate; and
and a second conduit portion communicating with the common port portion and the first conduit portion in the intermediate region and formed up to the other side of the lower housing.
8. The method of claim 7,
The first conduit portion and the common port portion provide a supply path of the supercritical fluid for initial pressurization,
The substrate drying chamber, characterized in that the common port portion and the second conduit portion provide a discharge path for the mixed fluid in which the organic solvent is dissolved.
8. The method of claim 7,
The substrate drying chamber, characterized in that the supercritical fluid for initial pressurization supplied through the first conduit portion and the common port portion is blocked by the substrate arrangement plate to prevent direct injection to the substrate.
According to claim 1,
Further comprising a sealing portion provided on the coupling surface of the lower housing and the upper housing,
The substrate is disposed on the substrate mounting plate to be positioned higher than the coupling surface of the lower housing and the upper housing, and when the drying process is completed and the lower housing and the upper housing are opened, a sealing provided on the coupling surface The substrate drying chamber, characterized in that the particles around the part are prevented from flowing into the substrate by gravity according to the height difference between the substrate and the bonding surface.
According to claim 1,
One end is coupled to the bottom surface of the lower housing and the other end is coupled to the substrate placement plate, and further comprising a substrate placement plate support part to space the substrate placement plate from the bottom surface of the lower housing while supporting the substrate placement plate Characterized in that, the substrate drying chamber.
12. The method of claim 11,
The first separation space existing between the bottom surface of the lower housing and the substrate arrangement plate by the substrate arrangement plate support part is a supercritical fluid for initial pressurization supplied through the integrated supply/discharge port is the lower surface of the substrate arrangement plate The substrate drying chamber, characterized in that it moves along and induces the substrate to gradually diffuse into the disposed processing area.
According to claim 1,
The second separation space existing between the upper surface of the substrate arrangement plate and the substrate by the substrate support part is a supercritical fluid for initial pressurization supplied through the integrated supply/discharge port to the lower surface of the substrate and the upper supply port. A substrate drying chamber, characterized in that it shortens the drying process time by exposing it to a drying supercritical fluid supplied through it.

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