KR20220054081A - Moisture condensation preventing apparatus of temperature control module - Google Patents

Abstract

The present invention relates to a moisture condensation preventing apparatus of a temperature control module and, more particularly, to a device for preventing condensation of moisture that may occur in a temperature control module of a semiconductor chuck due to long-time operation. The moisture condensation preventing apparatus includes: a temperature control module; and a metal condensation prevention case.

Description

Moisture condensation preventing apparatus of temperature control module

The present invention relates to an apparatus for preventing moisture condensation of a temperature control module. Specifically, it relates to a device for preventing moisture condensation that may occur in a temperature control module of a semiconductor chuck due to long-term operation.

As semiconductor devices become more sophisticated, the requirements in the process for manufacturing them are also becoming stricter. In particular, temperature control in deposition and etching processes is the most basic and most important process variable.

Thermoelectric elements are widely used for temperature control of semiconductor chucks because they can respond quickly to a desired temperature change and there is no vibration. A thermoelectric element includes a pair of ceramic panels spaced apart from each other by a predetermined distance, a plurality of N-type and P-type thermoelectric semiconductors arranged in a predetermined pattern and provided between the pair of ceramic panels, and the plurality of N-type and P-type thermoelectric semiconductors. A conductive electrode electrically connecting the in series and an electrode terminal respectively joined to an end of the conductive electrode to apply power to a plurality of N-type and P-type thermoelectric semiconductors.

A silicon layer is filled in the space between the pair of ceramic panels to prevent the components from being spaced apart from each other by an external force, and also to prevent moisture from entering the inside.

A plurality of thermoelectric elements is mounted on a printed circuit board on which a conductive pattern is formed and used as a thermoelectric element module. Patent Document 1 is a technology related to a thermoelectric element and a printed circuit board on which the thermoelectric element is mounted. 1 schematically schematically illustrates the technique of Patent Document 1. As shown in FIG. An upper surface heat exchanger and a lower surface heat exchanger are attached to the upper ceramic panel and the lower ceramic panel of the thermoelectric element, respectively (refer to FIG. 1). A flow path through which the heat exchange medium can circulate is attached to one side of the heat exchanger, so that the heat exchange medium can circulate inside the heat exchanger. One of the two heat exchangers simulated in FIG. 1 obtains heat from the thermoelectric element and the other heat exchanger supplies heat to the thermoelectric element.

When energy is exchanged with a heat exchanger, moisture in the air is condensed due to the low temperature of one surface of the thermoelectric element. Condensation of moisture can cause fatal failure of thermoelectric elements that heat/cool using electricity, so it must be prevented.

In the prior art, in order to solve this problem, polyurethane foam was injected into the space between the upper heat exchanger and the lower heat exchanger to fill the space, and the outer shell was sealed with Teflon or the like. The semi-permanent fixing method as described above not only makes it very difficult to assemble/disassemble the temperature control module including the heat exchanger, but also has a problem that the recycling of the thermoelectric element and the printed circuit board is practically impossible due to the polyurethane foam attached to the surface. there is. For each temperature control module, since polyurethane foam is manually injected and the outer shell is sealed, there are disadvantages in that the occurrence of defects is high, and a lot of time and manpower are required. Even if the seal is made with polyurethane foam as described above, an electrical short may occur even with a small amount of moisture inside when a long-term operation of more than one year is performed.

Patent Document 2 relates to a cooling device for heat exchange of semiconductor manufacturing equipment. In order to prevent a thermoelectric element from being destroyed by moisture, a silicon layer is disposed only on the outer rim (refer to FIG. 5 of Patent Document 2). Nevertheless, there is still air remaining in the very small voids inside, which can cause condensation of moisture.

Patent Documents 3 and 4 are a method of simply sealing the thermoelectric element itself, and have a configuration different from the temperature control module of the present invention.

Patent Document 5 is a prior art by the applicant of the present invention. Patent Document 5 discloses a thermoelectric element module including a printed circuit board on which a plurality of thermoelectric elements are mounted and a conductive pattern for electrically connecting the plurality of thermoelectric elements is formed, a ceramic panel on upper and lower surfaces of the plurality of thermoelectric elements, and It relates to a temperature control module that is easy to assemble and disassemble, including a contacting top heat exchanger and a bottom heat exchanger. and a spacer that fills 90% or more of the spaced space between the upper surface heat exchanger and the lower surface heat exchanger, and the temperature control module further includes a fastening member for fixing the thermoelectric element module, the upper surface heat exchanger, and the lower surface heat exchanger, , The spacer is a non-conductive, elastic material and is any one or more of rubber, polymer resin, and wood that does not substantially deform even at 100° C. It relates to a temperature control module in the form of a flat plate formed by

Patent Document 5 has dramatically improved many problems caused by moisture compared to the conventional temperature control module, but, nevertheless, the following problems still exist.

1) Physical stress from an asymmetric structure having only one thermoelectric module (one layer) in the middle, and only an upper and lower heat exchanger in contact with upper and lower ceramic panels of the plurality of thermoelectric elements, and micro-gap caused by this Occurs.

Due to the asymmetric structure, when viewed as a whole, one side of the temperature control module is always in a high temperature state and the opposite side is always in a low temperature state. As a result, a force that bends in only one direction is continuously applied to the heat exchanger and the entire thermoelectric module. Patent Document 5 solves this problem with a screw and a spring of a fastening member. Due to the characteristics of the temperature control module, the temperature is inevitably changed, and this causes strength and weakness in the magnitude of the bending force in only one direction. The asymmetric structure and force fluctuations weaken the coupling force between the fastening screw and the spring, resulting in micro-play.

A very small amount of outside air is introduced through such a fine clearance. Once introduced, the air is condensed directly in the cooling part of the temperature control module to form very fine water droplets, and these water droplets continuously move to the inside along the minute gaps in the rather elaborately designed structure according to the capillary phenomenon. Moisture, which exists only in the outer periphery of the temperature control module in the beginning, gradually moves to the inside as time goes by, eventually causing electrical disconnection of the thermoelectric element.

2) Even though the above gap is reduced by using a bolt with a spring, a space between the spacer and the thermoelectric soda occurs, and the ceramic is damaged when the tightening strength of the bolt is increased due to the characteristics of the thermoelectric element made of ceramic. do. Due to these restrictions, there are restrictions in changing the material or strength of the fastening member.

This problem was not discovered in a short time, and the problem was discovered through a very long operation. Ultimately, controlling a very minute amount of moisture over a long period of time is the key, but there is no technology that offers a clear solution for this.

The semiconductor manufacturing process is a huge multi-step process in which several processes interlock. If a problem occurs in one process, it also affects subsequent processes, so the yield in each process must be raised to a very high level. For example, in the case of 50 processes, even if the yield of each process is 99.9%, the yield of all 50 processes is significantly lowered to 95.1%, which is 50 squared of 99.9%.

Due to these characteristics, the temperature control module in the semiconductor field not only has to respond to fast temperature control, but also requires very high durability. The temperature control module usually requires more than 2 years of trouble-free operation time. Patent Document 5 does not satisfy the level required by the continuously developing semiconductor technology despite the fact that the defect rate is lowered and the operating time is significantly increased compared to the prior art.

In order to solve the problem of a very minute amount of moisture occurring over a long period of time, a method of completely sealing the entire temperature control module with urethane foam has been attempted in the past. A short circuit occurred. The above problems cannot be solved by changing the material or increasing the precision of the product, so a solution of a new concept should be proposed.

Republic of Korea Patent Publication No. 0772201 ('Patent Document 1') Republic of Korea Patent Publication No. 0542862 ('Patent Document 2') Republic of Korea Patent Publication No. 0620913 ('Patent Document 3') Republic of Korea Patent Publication No. 1357731 ('Patent Document 4') Republic of Korea Patent Publication No. 1959874 ('Patent Document 5')

As described above, in the temperature control module including a plurality of thermoelectric elements, the present invention provides a temperature control module including a moisture condensation prevention device of a novel concept that does not cause defects due to moisture even during long-term operation. The purpose.

In order to solve the above problems, the present invention provides a temperature control module for heating or cooling a heat exchange medium by a thermoelectric element; It provides a condensation prevention device of the temperature control module including a condensation prevention case made of a metal material for sealing all parts except for the input and output ports of the temperature control module.

In the temperature control module, at least three heat exchangers in a rectangular parallelepiped form in which a heat exchange medium flows and the thermoelectric element heats or cools the heat exchange medium are vertically or horizontally stacked, and the thermoelectric element is disposed between the stacked heat exchangers. may be placed.

The heat exchanger includes at least two heat exchange medium input/output ports; an internal flow path through which the heat exchange medium input and output through the heat exchange medium input/output port flows along the inside; and a heat exchange surface in contact with the ceramic panel of the thermoelectric element.

The anti-condensation case may include: a case body in which the temperature control module is built; a case cover coupled to the case body to completely seal the built-in temperature control module; a port hole for protruding the heat exchange medium input/output port of the temperature control module to the outside; a gas input/output port capable of inputting and outputting dry gas into the sealed case; and a power supply port capable of supplying power to the thermoelectric element.

The case body and the case cover may be coupled by welding or a separate screw after embedding the temperature control module to seal the temperature control module.

The heat exchange medium input/output port and the port hole may be sealed by welding, and the gas input/output port may be coupled to the case body. can

The power supply port may be a vacuum connector.

The gas supplied through the gas input/output port may include at least one or more from the group including dry inert gas and carbon dioxide, and after the temperature control module is built into the condensation prevention case and sealed, the gas input/output port A control unit for maintaining the atmospheric pressure inside the condensation prevention case by the dry gas supplied through it to be at least the atmospheric pressure or more may be added.

The temperature control module may further include a fastening member for fixing the thermoelectric element and the heat exchanger, in which case the fastening part may be fastened through the fastening hole.

a plurality of partition walls through which the heat exchange medium can be divided into a plurality of channels to flow through the internal passage; and a wing portion provided on the partition wall through which the heat exchange medium can move to another channel.

The present invention also provides a semiconductor manufacturing equipment including a moisture condensation prevention device of the temperature control module.

The present invention also provides a method for controlling the temperature of semiconductor manufacturing equipment using the moisture condensation prevention device of the temperature control module.

The present invention can also be provided in various combinations that can be combined among the means for solving the above problems.

As described above, in the temperature control module including a plurality of thermoelectric elements, the present invention can provide a temperature control module including a moisture condensation prevention device of a novel concept that does not cause defects due to moisture even during long-time operation. there is. Unlike the existing temperature control module, the temperature control module according to the present invention has no problem in the operation of the device even after using it for 2 years or more.

1 is a perspective view of a temperature control module of Patent Document 1, which is a prior art.
2 is a perspective view of an apparatus for preventing moisture condensation of a temperature control module according to the present invention.
3 is an exploded perspective view of an apparatus for preventing moisture condensation of a temperature control module according to the present invention.
4 is a perspective view of a temperature control module according to the present invention.
5 is a front, side, and top view of a temperature control module according to the present invention.
6 is a schematic diagram of a cross-sectional view along AA' and BB' of a temperature control module according to the present invention and an internal channel.

Hereinafter, embodiments in which those of ordinary skill in the art to which the present invention pertains can easily practice the present invention will be described in detail with reference to the accompanying drawings. However, when it is determined that a detailed description of a related well-known function or configuration may unnecessarily obscure the gist of the present invention in describing the operating principle of the preferred embodiment of the present invention in detail, the detailed description thereof will be omitted.

In addition, the same reference numerals are used throughout the drawings for parts having similar functions and functions. Throughout the specification, when it is said that a certain part is connected to another part, it includes not only a case in which it is directly connected, but also a case in which it is indirectly connected with another element interposed therebetween. In addition, the inclusion of any component does not exclude other components unless otherwise stated, but means that other components may be further included.

In addition, descriptions that limit or add elements may be applied to all inventions unless there are special limitations, and are not limited to descriptions of specific inventions.

Also, throughout the description and claims of the present application, the singular includes the plural unless otherwise indicated.

Also, throughout the description and claims herein, "or" is intended to include "and" unless stated otherwise. Therefore, "comprising A or B" means all three cases including A, including B, or including A and B.

In addition, all numerical ranges include the values at both ends and all intermediate values therebetween, unless expressly stated otherwise.

The present invention will be described along with detailed examples according to the drawings.

2 is a perspective view of a device for preventing moisture condensation of a temperature control module according to the present invention, FIG. 3 is an exploded perspective view of a device for preventing moisture condensation of a temperature control module according to the present invention, and FIG. 4 is a temperature control module according to the present invention It is a perspective view, FIG. 5 is a front view, a side view, and a top view of the temperature control module according to the present invention, and FIG. 6 is a cross-sectional view along AA′ and BB′ of the temperature control module according to the present invention and a schematic view of an internal channel.

2 to 6, the present invention provides a temperature control module 100 for heating or cooling a heat exchange medium by a thermoelectric element 110; It relates to a condensation prevention device (10) of a temperature control module including a condensation prevention case (50) made of a metal material for sealing all parts except for the entry and exit ports (112, 122) of the temperature control module (100).

The difference from the temperature control module of FIG. 1 is that the temperature control module 100 includes three heat exchangers 120 instead of two. The temperature control module 100 has a heat exchange medium flowing therein and the thermoelectric element 110 heats or cools the heat exchange medium. At least three or more rectangular heat exchangers 120 are stacked vertically or horizontally, The thermoelectric element 110 is disposed between the stacked heat exchangers 120 .

The thermoelectric element 110 according to the present invention may be mounted on a printed circuit board on which a conductive pattern is formed as in the prior art, in particular, Patent Document 5, but the thermoelectric element 110 itself is simply a wire without a separate printed circuit board. It is also possible to configure a connection only with . In the prior art such as Patent Document 1, since the thermoelectric element is in contact with air containing moisture, it is preferable to exclude a space in which air containing moisture may exist around the thermoelectric element if possible. Therefore, after mounting the thermoelectric element on the printed circuit board, polyurethane foam or spacers were introduced in the remaining space. Since the present invention creates a space without moisture itself, it is not necessary to use a separate printed circuit board, foam urethane, and spacer.

Rather, in the present invention, since a gas such as nitrogen without moisture is continuously circulated, rather than inhibiting the air flow around the thermoelectric element, it leaves a space for circulation, during the process of inserting the temperature control module into the condensation prevention case. It is preferable to remove the remaining moisture using circulating nitrogen gas.

The heat exchanger 120 includes at least two heat exchange medium input/output ports 122; an internal flow path 124 through which the heat exchange medium input and output through the heat exchange medium input/output port 122 flows along the inside; and a heat exchange surface 126 in contact with the ceramic panel of the thermoelectric element 110 .

The temperature control module 100 illustrated in the drawings of the present invention includes three heat exchangers 120 , and each heat exchanger 120 has a total of two input/output ports 122 . In addition, 6 thermoelectric elements 110 are disposed between the heat exchanger 120, and a total of 12 thermoelectric elements 110 are disposed in two rows. , which is merely an example and is not limited thereto.

Although it is sufficient if the thermoelectric element 110 according to the present invention is disposed between the heat exchangers 120, it is preferable to arrange the thermoelectric element 110 at regular intervals for uniform heat transfer. It is preferable to arrange|position as two or more rows in a preferable structure.

The wires connected to each thermoelectric element 110 are all connected to the thermoelectric element power supply line 112, and power is supplied therethrough.

In order to ensure that there is no empty space in the internal flow path 124 and for heat exchange efficiency, it is preferable to insert the heat exchange medium through the input/output port 122 at the bottom and to take it out through the input/output port 122 at the top.

As the heat exchange medium, water or silicone oil having a high heat capacity among water, oil, and gas is preferable, but water is preferable due to oxidation problems due to long-term use. Meanwhile, a pump (not shown) may be used to send the heat exchange medium to the heat exchanger 120 , and preferably, a pump without pulsation is used.

The anti-condensation case 50 is a case body 520 in which the temperature control module 100 is built in one embodiment according to the present invention; a case cover 530 coupled to the case body 520 to completely seal the built-in temperature control module 100; a port hole 540 for protruding the heat exchange medium input/output port 122 of the temperature control module 100 to the outside; a gas input/output port 560 for inputting and outputting dry gas into the sealed case; and a power supply port 580 capable of supplying power to the thermoelectric element.

The anti-condensation case 50 according to the present invention is presented as an example of a configuration capable of sealing the temperature control module 100 in a small volume in the form of a rectangular parallelepiped, but is not necessarily limited to this shape.

The case body 520 and the case cover 530 are coupled by welding or a separate screw after embedding the temperature control module 100 to seal the temperature control module 100 . The sealing method may vary depending on the period of application, but in order to achieve the most complete sealing, it is preferable to weld all the parts and determine whether there is a leak using the gas input/output port 560.

The heat exchange medium input/output port 122 and the port hole 540 may also be sealed by welding.

Although the welding or joining by welding is also made on the outer surface of the anti-condensation case 50, it is preferable for sealing to be performed also on the inner surface of the anti-condensation case. In addition, since the conventional sealing method using a resin containing Teflon and the like and sealing using an elastic rubber material O-ring may not completely solve the problem of the present invention, it is completely fixed through metal welding. It is desirable to seal it with an airtight seal, and through this, the operating time of 2 years or more can be guaranteed.

In particular, since the heat exchange medium moves, the temperature of the heat exchange medium input/output port 122 is lowered to minus 10 degrees Celsius or higher or higher than 50 degrees Celsius because the heat exchange medium moves. , since there is a problem that the sealing for a long time that is desired in the present invention cannot be guaranteed, this part must be welded.

The gas input/output port 560 may be coupled to the case body 520 , and it is preferable to use the same method as the sealing method of the heat exchange medium input/output port 122 and the port hole 540 .

All of the gas input/output ports 560 according to the present invention are disposed on the upper end of the case body 520, but this may be changed according to the convenience of operation and the environment. Since the drying gas is continuously circulated, the position of the input and output can be selected according to the user's environment.

The power supply port 580 is a vacuum connector. The power supply port 580 can ensure long-term sealing by using a vacuum connector. Unlike the heat exchange medium input/output port 122 and the port hole 540, the corresponding portion does not have a large temperature change, so it is possible to maintain the sealing for a long time by using a vacuum connector. When a vacuum connector is used, there is an advantage of easy separation when repairing the condensation prevention device 10 of an individual temperature control module. Since the vacuum connector is a connector used in a vacuum chamber, a high-pressure reactor, and the like, a detailed description thereof will be omitted.

The gas supplied through the gas input/output port 560 may include at least one or more from the group including dry inert gas and carbon dioxide.

After the temperature control module 100 is built into the condensation prevention case 50 and sealed, the atmospheric pressure inside the condensation prevention case 50 by the dry gas supplied through the gas input/output port 560 is at least normal pressure. A control unit (not shown) that maintains the abnormality is added. The control unit refers to a role of maintaining the above function regardless of the form of a separate control panel, and corresponds to a simple pressure control valve.

After the temperature control module 100 is built into the condensation prevention case 50 and sealed, a process of purging the internal air using a drying gas is required to remove the air remaining therein. In addition, the drying gas should be supplied at all times after sealing, and the pressure at this time is preferably above atmospheric pressure and 1 to 1.5 atmospheres.

The temperature control module 100 may additionally include a fastening member for fixing the thermoelectric element and the heat exchanger. At this time, the fastening part is fastened through the fastening part hole 114 .

On the other hand, the temperature control module 100 of the present invention can also use the fastening method used in the conventional Patent Document 5. A thermoelectric element module including a printed circuit board on which a plurality of thermoelectric elements are mounted and a conductive pattern for electrically connecting the plurality of thermoelectric elements is formed, and a heat exchanger 2 in contact with upper and lower surface ceramic panels of the plurality of thermoelectric elements More than one and and these can be used by fastening them into one.

6 is a cross-sectional view along AA' and BB' of the temperature control module according to the present invention and a schematic view of an internal channel. ); and a wing portion 128 provided on the partition wall 127 through which the heat exchange medium can move to another channel. Here, the channel refers to a space divided by each partition wall 127 .

The present invention may also provide semiconductor manufacturing equipment including the moisture condensation prevention device 10 of the temperature control module, and control the temperature of the semiconductor manufacturing equipment using the moisture condensation prevention device 10 of the temperature control module A method can also be provided.

As described above in detail a specific part of the content of the present invention, for those of ordinary skill in the art, these specific descriptions are only preferred embodiments, and the scope of the present invention is not limited thereto. It is obvious to those skilled in the art that various changes and modifications can be made within the scope and spirit of the present invention, and it is natural that such variations and modifications fall within the scope of the appended claims.

10: moisture condensation prevention device of temperature control module
50 Anti-condensation case
100: temperature control module
110: thermoelectric element
112: thermoelectric element power supply line
114: fastening hole
120: heat exchanger
122: heat exchange medium input/output port
124: internal flow path
126: heat exchange surface
127: bulkhead
128: wing
520: case body
530: case cover
540: port hole
560: gas input/output port;
580: power supply port

Claims (12)

a temperature control module for heating or cooling a heat exchange medium by means of a thermoelectric element;
Condensation prevention device of the temperature control module including a condensation prevention case made of a metal material for sealing all parts except for the entry and exit ports of the temperature control module. According to claim 1,
The temperature control module
At least three heat exchangers in the form of a cuboid in which a heat exchange medium flows and the thermoelectric element heats or cools the heat exchange medium are vertically or horizontally stacked,
A device for preventing condensation of a temperature control module in which the thermoelectric element is disposed between the stacked heat exchangers. 3. The method of claim 2,
the heat exchanger
at least two heat exchange medium input/output ports;
an internal flow path through which the heat exchange medium input and output through the heat exchange medium input/output port flows along the inside;
a heat exchange surface in contact with the ceramic panel of the thermoelectric element;
Condensation prevention device of the temperature control module comprising a. According to claim 1,
The anti-condensation case
a case body in which the temperature control module is built;
a case cover coupled to the case body to completely seal the built-in temperature control module;
a port hole for protruding the heat exchange medium input/output port of the temperature control module to the outside;
a gas input/output port capable of inputting and outputting dry gas into the sealed case;
a power supply port capable of supplying power to the thermoelectric element;
A device for preventing moisture condensation of a temperature control module comprising a. 5. The method of claim 4,
The case body and the case cover are coupled by welding or a separate screw after embedding the temperature control module to seal the temperature control module. 5. The method of claim 4,
The heat exchange medium input/output port and the port hole are sealed by welding. 5. The method of claim 4,
The power supply port is a vacuum connector, a moisture condensation prevention device of the temperature control module. 5. The method of claim 4,
The gas supplied through the gas input/output port is an apparatus for preventing moisture condensation of a temperature control module comprising at least one or more from the group including dry inert gas and carbon dioxide. 5. The method of claim 4,
After the temperature control module is built into the anti-condensation case and sealed, a temperature control module with a control unit for maintaining the air pressure inside the anti-condensation case by the dry gas supplied through the gas input/output port to be at least equal to or higher than atmospheric pressure of moisture condensation prevention device. 4. The method of claim 3,
a plurality of partition walls through which the heat exchange medium can be divided into a plurality of channels to flow through the internal passage;
a wing portion provided on the partition wall through which the heat exchange medium can move to another channel;
A device for preventing moisture condensation of a temperature control module comprising a. 11. A semiconductor manufacturing equipment comprising a device for preventing moisture condensation of a temperature control module according to any one of claims 1 to 10. A method for controlling the temperature of semiconductor manufacturing equipment by using the moisture condensation prevention device of the temperature control module according to any one of claims 1 to 10.

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