KR100414860B1 - Cooling device of thin plate type - Google Patents

Abstract

Disclosed is a thin plate type cooling device which naturally circulates without being influenced by gravity, stabilizes refrigerant flow, suppresses mixing limits, improves cooling efficiency, and reduces contact thermal resistance. The cooling apparatus of the present invention includes a thin-plate housing in which a circulation loop of a fluid is embedded and a refrigerant circulating in the circulation loop in the housing. The circulation loop includes a refrigerant storage unit capable of storing a liquid refrigerant; At least one first microchannel connected to one end of the refrigerant storage unit, wherein the liquid refrigerant in the first microchannel is predetermined by the surface tension with the inner wall of the first microchannel from the refrigerant storage unit of the first microchannel An evaporation part filled up to a part and set to have a surface tension greater than gravity; A condenser that is spaced apart from the first microchannel in the longitudinal direction by a predetermined distance in the same plane and has a surface tension greater than gravity; A gas phase refrigerant moving unit positioned between the first microchannel and the second microchannel; And a liquid refrigerant moving part which is transferred from the liquid phase refrigerant condensed in the condensation part to the refrigerant storage part and separated from the gas phase refrigerant moving part.

Description

Cooling device of thin plate type

The present invention relates to a thin plate cooling device, and more particularly, to a thin plate cooling device using a phase change of the working fluid to remove heat generated in a high density integrated circuit.

As the trend toward higher integration of semiconductor devices reduces design rules, and as line widths of electronic circuits forming semiconductor devices decrease, the number of transistors per unit area increases, resulting in miniaturization and high performance of electronic equipment. However, with this, the heat dissipation rate per unit area of the semiconductor chip is further increased. This increase in heat dissipation rate degrades the performance of the semiconductor device, shortens its lifespan and ultimately lowers the reliability of the system employing the semiconductor device. In particular, in the semiconductor device, various parameter values are sensitively changed according to the operating temperature, thereby deteriorating the characteristics of the integrated circuit.

As the heat dissipation rate is increased, cooling technology has also been developed. As a conventional cooling technology, a fin fan cooling method, a peltier cooling method, a liquid-jet cooling method, and an immersion are used. ) Cooling method, heat pipe cooling method, etc.

The fin fan cooling method has been widely used for decades as a method of forced cooling using a fin and a fan, but has a problem of low cooling efficiency compared to noise, vibration, and a large volume, and requires a separate power source for the fan. In recent years, due to the problem that the heat generated from the fan itself has been avoided. The thermoelectric element cooling method using the Peltier effect has no noise and vibration, but requires a large driving power source, which requires a large amount of heat dissipation device that is more than necessary on the hot juction by the energy conservation law. In addition, the liquid injection cooling method is the efficiency of the mainstream of the cooler research, but the structure is complicated and there is a problem that requires a pump drive power for injection. On the other hand, in the case of the submersible cooling method, there is a natural circulation thermosiphon (thermosyphon) that does not require a separate driving power, but it is difficult to be robust when applied to personal portable electronic equipment because it is heavily influenced by gravity. There is a problem.

Due to the above problems, the heat pipe cooling method has been widely applied in various shapes as a compact cooling device due to the advantages that the structure is simple and easy to manufacture.

However, in the conventional heat pipe structure as described above, since the flow directions of gas and liquid are opposite to each other, there is a problem that strong liquid surface waves and shear stresses are generated at the interface to inhibit the smooth flow of the refrigerant. The evaporator in contact with the heat source still suffers from a sudden dry out due to an entrainment limit in which the liquid refrigerant flows into the vapor side. In addition, the vaporized refrigerant inside the inner pipe is moved depending on the buoyancy and pressure difference, and there is a problem that there are a lot of limitations to the location that can be installed because the liquefied refrigerant is dependent on gravity in the outer pipe.

SUMMARY OF THE INVENTION An object of the present invention is to improve the problems of the prior art, and to provide a compact thin plate cooling device that naturally circulates without being affected by gravity without supplying external power.

Another object of the present invention is to provide a thin plate type cooling device which improves the cooling efficiency by increasing the mass flow rate of the refrigerant by reducing the mixing limit to reduce the mixing limit by separating the liquid refrigerant moving part from the liquid phase moving part. There is.

It is still another object of the present invention to provide a thin plate type cooling device that improves cooling efficiency by reducing contact thermal resistance by forming a housing in a thin plate shape and improving adhesion and fixing property on a flat heat source without a separate heat conductor.

1 is a cross-sectional view schematically showing a cross section in the XY plane of a thin plate cooling apparatus according to a first embodiment of the present invention.

FIG. 2 is a cross-sectional view schematically illustrating a cross section in the XZ plane of the thin plate cooling apparatus according to the first embodiment of the present invention, taken along line AA ′ of FIG. 1.

3 is a cross-sectional view schematically illustrating a cross section in the YZ plane of the thin plate cooling apparatus according to the first embodiment of the present invention, taken along line BB ′ of FIG. 1.

4 is a cross-sectional view schematically illustrating a cross section in the YZ plane of the thin plate cooling apparatus according to the first embodiment of the present invention, taken along line CC ′ of FIG. 1.

FIG. 5 is a schematic cross-sectional view of a thin plate cooling apparatus according to a second exemplary embodiment of the present invention, taken along line BB ′ of FIG.

FIG. 6 is a schematic cross-sectional view of a thin plate cooling apparatus according to a third exemplary embodiment of the present invention, taken along line BB ′ of FIG. 1 in a YZ plane.

FIG. 7 is a schematic cross-sectional view of a thin plate cooling apparatus according to a fourth exemplary embodiment of the present invention, taken along line BB ′ of FIG.

FIG. 8 is an enlarged cross-sectional view of a unit microchannel cut in the AA ′ direction of FIG. 1.

The thin plate cooling apparatus according to the present invention for achieving the objects of the present invention, the plate-shaped housing and the phase change is built in the circulation loop of the fluid therein, the refrigerant circulating in the circulation loop in the housing It includes.

The circulation loop in the housing may include a refrigerant storage unit formed at one end of the housing and configured to store a liquid refrigerant; And at least one first microchannel connected to one end of the refrigerant storage unit, wherein the liquid phase refrigerant flows from the refrigerant storage unit by surface tension with an inner wall of the first microchannel in the first microchannel. The liquid refrigerant partially filled to a predetermined portion of the first microchannel, the surface tension in the first microchannel being greater than gravity, and filled in the first microchannel by heat absorbed from a heat source. Evaporation unit capable of vaporizing; At least one second microchannel spaced apart from the first microchannel in the longitudinal direction by a predetermined distance in the longitudinal direction and capable of condensing the refrigerant in the vaporized and moved gas in the first microchannel, A condenser configured to have a surface tension between the inner wall of the second microchannel and the condensed refrigerant greater than gravity; A gas phase refrigerant moving unit positioned between the first microchannel of the evaporator and the second microchannel of the condenser; And a liquid refrigerant moving part which transfers the liquid refrigerant condensed in the condensation part to the refrigerant storage part and is separated from the gas phase refrigerant moving part.

Preferably, the gaseous phase refrigerant moving part and the liquid phase refrigerant moving part are separated from each other by a heat insulating part, and the heat insulating part is configured to be sealed in the housing or open to penetrate the upper and lower parts of the housing. can do.

On the other hand, in order to increase the supercooling effect of the refrigerant and smooth the flow of the refrigerant when the refrigerant is not circulated to one of the liquid refrigerant moving portion due to gravity head, disturbance, the gas phase refrigerant moving portion is located in the center of the thin housing, The liquid refrigerant moving unit is preferably located in both directions along the outer sides of the housing.

In addition, it may further include a fixing means for directly fixing the evaporator to the heat source adjacent to the evaporator without interposing a thermal conductor in the middle to reduce the contact heat resistance, the evaporation on an external heat source The bottom bottom surface of the part may be integrated.

In addition, the liquid refrigerant moving part may include at least one third microchannel in which the surface tension between the liquid refrigerant and the inner wall of the liquid refrigerant moving part is greater than gravity so that the liquid refrigerant moving part is hardly affected by gravity. The liquid coolant moving part may be formed in the liquid coolant moving part to form a plurality of grooves in the moving direction of the liquid coolant or separated into two or more flow paths.

Meanwhile, the housing may be made of a semiconductor material, a metal material, a plastic material, a ceramic material, a metal alloy material, or a glass, and may be formed of an external heat source contacting the bottom surface of the evaporator of the housing to reduce contact thermal resistance. It may be made of the same material as the surface material.

On the other hand, the first micro-channel and the second micro-channel has a surface tension of the liquid refrigerant and the inner wall of the channel is set larger than the gravity therein, more specifically to be formed to a depth of 10 ^-9 m to 10 ^-3 m The length of the first microchannel may be set to be in a range of 0.5 cm to 5 cm.

In addition, in order to reduce the contact angle of the meniscus by the liquid refrigerant in the first microchannel and the second microchannel, the inner wall thereof has a constant treatment, for example, a plating treatment, a coating treatment, a coating treatment, a coloring treatment, an anodizing treatment, Plasma treatment, laser treatment, and the like are preferable, and the surface roughness of the first microchannel and the second microchannel may be adjusted to improve the heat transfer rate, and preferably to have a range of 1 μm to 100 μm.

Meanwhile, the first microchannel array may be formed in a single layer arrangement in which a plurality of the first microchannels are arranged on the same surface, and the plurality of first microchannels may be arranged on the same surface and may be formed so that the upper portions of the adjacent first microchannels are opened and connected to each other. It can be arranged in multiple layers above and below.

In addition, in a direction perpendicular to the heat flow direction on the bottom surface of the housing in contact with the heat source at the boundary between the refrigerant storage unit and the evaporation unit in order to suppress heat transfer to the refrigerant storage unit so as to prevent dry out from the evaporation unit. It is preferable to form a thin thickness of the bottom surface of the housing, more specifically, a groove may be formed on the bottom surface of the housing.

Meanwhile, a plurality of first guides may be further formed in the gas phase refrigerant moving part to uniformly move the gaseous refrigerant in the condensation part, and a boundary between the refrigerant storage part and the liquid refrigerant moving part, and the condensation part; A plurality of second guides for guiding the movement of the refrigerant in the liquid phase may be further formed at the boundary of the liquid refrigerant moving part to reduce the loss caused by the rapid rotation of the refrigerant.

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

The embodiments described below may be modified in many different forms, and the scope of the present invention is not limited to the embodiments described below. The embodiments of the present invention are provided to more completely explain the present invention to those skilled in the art.

1 is a cross-sectional view schematically showing a cross section in the XY plane of the thin-film cooling apparatus 100 according to the first embodiment of the present invention, Figure 2 is a first embodiment of the present invention cut the AA 'line of FIG. 3 is a cross-sectional view schematically showing a cross-sectional view in the XZ plane of the thin plate cooling apparatus according to the present invention, FIG. 3 is a cross-sectional view schematically showing a cross section in the YZ plane taken along the line BB ′ of FIG. 1, and FIG. 4 is a CC of FIG. 1. FIG. 8 is a cross-sectional view schematically illustrating a cross section in the YZ plane taken along a line, and FIG. 8 is an enlarged cross-sectional view of a cross section of a unit microchannel taken along the AA line in FIG. 1.

1 to 4 and 8, the thin plate cooling apparatus 100 is configured such that a circulation loop of the refrigerant is formed inside the rectangular housing 112. The refrigerant is circulated in the direction of the arrow, by using the latent heat during the phase change between the liquid phase and the gas phase to transfer the heat of the external heat source in contact with the cooling device 100 to cool.

The housing 112 may include a semiconductor material such as silicon or gallium, a new material laminated material such as a self-assembled monolayer (SAM), a metal material such as copper or aluminum having excellent thermal conductivity, an alloy material thereof, a ceramic material, It may be made of various materials such as high molecular materials such as plastic and crystalline materials such as diamond. In particular, when the external heat source is a semiconductor chip, the contact heat resistance may be minimized by forming the same material as the surface material of the external heat source. In addition, the housing 112 may be formed to be integral with the surface material of the external heat source in the manufacturing process of the semiconductor chip.

On the other hand, the refrigerant used in the present invention may be selected from a variety of refrigerants that can cause a phase change between the liquid phase and the gas phase by the external heat, in particular, in the present embodiment uses a latent heat and a large surface tension water, environmental pollution In consideration of this, it is preferable to use a non-freon (CFC) series refrigerant. Since the magnitude of the surface tension varies depending on the material of the housing 112, a refrigerant suitable for the material of the housing 112 is selected. In an electronic product such as an integrated circuit, water or an alcohol-based refrigerant such as methanol or ethanol may be used as the refrigerant. In the case of the water or alcohol-based refrigerant as described above, the heat capacity is large, and the contact angle due to the surface tension with the inner wall of the semiconductor material is small, so that the flow rate of the refrigerant is increased, which is advantageous to transfer a large amount of heat. In addition, since there is no problem of environmental pollution unlike the freon refrigerant, even if leaked by the minute crack of the circulating loop-like housing 112, the problem of environmental pollution does not occur.

On the other hand, the circulation loop of the coolant, the evaporator 104 is connected to one end of the coolant storage unit 102 from the coolant storage unit 102 formed in one end of the inside of the housing 112 in the direction of the arrow in the drawing ), The gaseous phase refrigerant moving unit 106, the condensation unit 108, and the liquid phase liquid moving unit 110 are configured to circulate back to the refrigerant storage unit 102.

The refrigerant storage unit 102 has an appropriate volume so that a predetermined amount of liquid refrigerant can be stored.

An evaporation unit 104 is connected to an outlet side of the refrigerant storage unit 102, and the evaporation unit 104 has a plurality of first microchannels 120 on the same plane as illustrated in FIG. 3. Are arranged in a monolayer. The evaporator 104 vaporizes the liquid refrigerant 120a filled in the first microchannel 120 by heat absorbed from an external heat source to evaporate the refrigerant 120b in the gas phase.

In addition, as shown in FIG. 2, the depth of the first microchannel 120 is formed to be thinner than the depth of the refrigerant storage unit 102. In the first microchannel 120, the liquid refrigerant stored in the refrigerant storage unit 102 is discharged from the refrigerant storage unit 102 by the surface tension and the capillary phenomenon with the inner wall of the first microchannel 120. Partially filled to a predetermined portion of the first microchannel 120 (see FIG. 8), the depth of the first microchannel 120 so that the surface tension in the first microchannel 120 is greater than gravity Or the cross-sectional area is set. In the present embodiment, the first microchannel 120 is formed to a depth in the range of 10 ⁻⁹ m to 10 ⁻³ m (that is, the channel height of the first microchannel 120), and the first microchannel 120 is formed. ) Length was set within the range of 0.5 cm to 5 cm.

On the other hand, in order to reduce the contact angle of the meniscus by the liquid refrigerant in the first microchannel 120 denoted by "A" in Fig. 8, the inner wall is hydrophilic, for example plating, painting treatment , Coating treatment, coloring treatment, anodizing treatment, plasma treatment, laser treatment, and the like, and the surface roughness of the inner wall of the first microchannel 120 can be adjusted to improve heat transfer rate from an external heat source. In the range of 1 μm to 100 μm.

In addition, the cross section of the first microchannel 120 may be formed in various shapes such as a circle, an oval, a rectangle, a square, and a polygon as well as a quadrangle as shown in FIG. 3. By increasing or decreasing the cross-sectional area along the longitudinal direction, it is possible to control the magnitude of the surface tension between the inner wall of the first microchannel 120 and the refrigerant, and a plurality of grooves are formed on the inner wall of the first channel 120, or 1 A plurality of nodes may be provided to change the cross-sectional area of the channel along the longitudinal direction of the microchannel 120 to determine the movement direction of the refrigerant or control the movement speed of the refrigerant.

Meanwhile, the condenser 108 is formed at a position spaced apart from the first microchannels 120 of the evaporator 104 in the longitudinal direction by a predetermined distance on the same plane. As shown in FIG. 4, the condensation unit 108 includes a plurality of second fine particles arranged in a single layer on the same plane to condense the refrigerant in the gaseous phase vaporized and moved in the first microchannel 120. Channel 122.

In addition, as shown in FIG. 2, the depth of the second microchannel 122 is formed deeper than the depth of the first microchannel 120, but is not limited thereto, and within the second microchannel 122. The liquefied liquid refrigerant condensed in the condenser 108 is partially filled to a predetermined portion of the second microchannel 122 by surface tension with the inner wall of the second microchannel 122 and capillary phenomenon. The depth or cross-sectional area of the second microchannel 122 is set such that the surface tension of the second microchannel 122 is greater than gravity. In the present embodiment, like the first microchannel 120, the second microchannel 122 is formed to have a depth in the range of 10 ⁻⁹ m to 10 ⁻³ m (that is, the channel height of the second microchannel 122). The length of the second microchannel 122 is set within the range of 0.5 cm to 5 cm.

In addition, the cross section of the second microchannel 120 may be formed in various shapes such as a circle, an oval, a rectangle, a square, and a polygon, in addition to being formed in a quadrangle as shown in FIG. 4. By increasing or decreasing the cross-sectional area along the longitudinal direction, the magnitude of the surface tension between the inner wall of the second microchannel 122 and the refrigerant can be controlled, and a plurality of grooves are formed on the inner wall of the second channel 122, or The plurality of nodes may be installed to determine the moving direction of the refrigerant or control the moving speed of the refrigerant so that the cross-sectional area of the channel may change along the length direction of the second microchannel 122.

In addition, in order to improve the effect of heat dissipation, a plurality of fins may be formed on the outside of the housing 112 adjacent to the condensation unit 108, and when the fins are formed of fins including a micro actuator, 108 may be driven to circulate the surrounding air by recycling the heat released to the outside. In addition, when the fin is formed in a microstructure including a thermoelectric element, the heat emitted from the condenser 108 may be converted into electrical energy and used as energy for fine driving.

In addition, by forming the volume of the condensation unit 108 to be larger than the volume of the evaporation unit 104, the refrigerant in the gas phase can be easily condensed in the condensation unit 108 even by surrounding convection.

On the other hand, between the first microchannel 120 of the evaporator 104 and the second microchannel 122 of the condensation unit 108, the gas phase refrigerant moving unit serving as a passage through which the refrigerant in the gas phase can move ( 106 is located. A plurality of first guides 118 are formed in the gas phase refrigerant moving part 106 to allow the vaporized gaseous refrigerant to move uniformly toward the condensation part 108. As shown in FIG. Compared with the cross-sectional area of the exit side of the first microchannel 120, the cross-sectional area thereof is widened.

Meanwhile, a liquid phase refrigerant moving unit in which the liquid refrigerant condensed in the second microchannel 122 is moved between the outlet side of the second microchannel 122 of the condenser 108 and the refrigerant storage unit 102. 110 is formed. The liquid phase refrigerant moving unit 110 is separated from the gas phase refrigerant moving unit 106 and configured to have a different flow direction of the refrigerant.

The gas phase refrigerant moving part 106 and the liquid refrigerant moving part 110 are thermally and physically separated from each other by the heat insulating part 116, and the heat insulating part 116 is sealed in the housing 112. It may be configured in the form that is present or may be configured to open to penetrate the upper and lower sides of the housing 112. When sealed in the housing 112, the heat insulating part 116 may be maintained in a vacuum or filled with a heat insulating material.

On the other hand, as shown in Figure 1, the liquid refrigerant moving part 110 is located symmetrically in both directions along the outer sides of the housing 112. The refrigerant circulation loop symmetrically formed along the outer side of the housing 112 is a very advantageous structure in the case of a thin plate shape, especially when the aspect ratio of the cross section is large, and effectively conducts convective diffusion of heat flow in the radial direction. Can be. By disposing two liquid refrigerant moving parts 110 along the edge of the cooling device 100, it is advantageous for subcooling the refrigerant in the flow path and lowering the inlet temperature of the evaporator 104. It means that it can transfer heat energy. In addition, the bidirectional circulation loop is inclined such that the gravitational position of the liquid refrigerant moving part 110 in both directions is different from the cooling device 100 based on the X-axis direction according to the installation position of the cooling device 100. In this case, when the refrigerant is not circulated to one of the liquid refrigerant moving parts 110 by the gravity head, it is advantageous in that the refrigerant can be smoothly flowed through the other liquid refrigerant moving parts 110.

In addition, the liquid refrigerant moving part 110 includes at least one third microchannel in which the surface tension between the liquid refrigerant and the inner wall of the liquid refrigerant moving part 110 is greater than gravity so that the liquid refrigerant moving part 110 is hardly affected by gravity. The liquid refrigerant moving part 110 may include a plurality of grooves (not shown) in the liquid refrigerant moving part 110 or separated into two or more flow paths so as to reduce the influence of gravity.

On the other hand, a plurality of guide the movement of the liquid refrigerant to the boundary portion of the refrigerant storage unit 102 and the liquid refrigerant moving unit 110 and the boundary portion of the condensation unit 108 and the liquid refrigerant moving unit 110 The second guide (not shown) may be further formed to reduce the loss caused by the rapid turning of the refrigerant flow.

On the other hand, as described above, the refrigerant storage unit 102 is configured to have an appropriate volume enough to supply a sufficient amount of refrigerant even under a heat load of a variable heat source, and rapid drying in the evaporator 104. In order to prevent the out phenomenon, it is preferable to install close to the inlet side of the evaporator 104 which can supply the coolant quickly, but when installed too close to the evaporator 104 of the housing 112 in contact with the external heat source Unnecessary bubbles may be generated by the heat transferred to the bottom surface. The growth of the bubble blocks the inlet of the first microchannel 120 of the evaporator 104 and the coolant storage part because the supply of the coolant may be stopped to cause dry out of the coolant in the evaporator 104. The housing in a direction orthogonal to the heat flow direction on the bottom surface of the housing 112 in contact with an external heat source at the boundary between the refrigerant storage unit 102 and the evaporator unit 104 to suppress heat transfer to the 102. It is preferable to form a thin thickness of the bottom surface of the, for example, a groove may be formed on the bottom surface of the housing 112.

Meanwhile, in order to reduce contact thermal resistance, it is preferable to directly fix the evaporator 104 to a heat source (not shown) adjacent to the evaporator 104 without interposing a thermal conductor in the middle. In this embodiment, the fixing means 114 is installed adjacent to the evaporator 104 to fix the cooling device 100 to an external heat source, so that it can be fastened by bolts or rivets.

5 is a cross-sectional view schematically illustrating a cross section in the YZ plane of the thin film type cooling apparatus according to the second embodiment of the present invention, taken along line BB ′ of FIG. 1. Referring to FIG. 5, the first microchannels 120 included in the evaporator 104 are arranged in a matrix form in a vertical array. By forming the first microchannel 120 in such a multilayer arrangement, the circulation amount of the refrigerant may be improved to improve the cooling efficiency of the cooling apparatus.

FIG. 6 is a cross-sectional view schematically illustrating a cross section in the YZ plane of the thin film type cooling apparatus according to the third embodiment of the present invention, taken along the line BB ′ of FIG. 1, and the first microchannel 120 in the evaporator 104. These are arranged in the upper and lower multilayer arrays, and are arranged in a zigzag form. This arrangement is a structure that can further improve the cooling efficiency than in FIG. 5 because the heat transferred between the first microchannel 120 arranged in the lower side and the first microchannel 120 arranged in the upper portion. .

FIG. 7 is a cross-sectional view schematically illustrating a cross section in the YZ plane of the thin film type cooling apparatus according to the fourth embodiment of the present invention, taken along the line BB ′ of FIG. 1, wherein an upper portion of the first microchannel 120 is adjacent thereto. 1 is a structure having a connecting portion 124 is opened and connected to the top of the microchannel 120.

The method of manufacturing the cooling apparatus 100 of each embodiment of the present invention described above may be manufactured by various methods currently known, for example, MEMS (Micro Electro Mechanical System) method using a semiconductor device manufacturing process or It can be manufactured by applying SAM (Self Assembled Monolayer) method. Referring to FIG. 3, the manufacturing method thereof will be briefly described. First, the surface of the housing 112 under the cooling device 100 is etched to cool the refrigerant storage 102, the first microchannel 120, and the gaseous refrigerant moving unit. 106, the second refrigerant channel 122 of the liquid refrigerant moving part 110 and the condensation part 108, and the like, and the upper housing having a predetermined pattern shape corresponding to the lower housing 112 ( The upper and lower housings 112 are anodic bonded by applying voltage to the upper and lower housings 112 after contacting each other, thereby integrating the upper and lower housings 112, and separately storing the refrigerant. Through the refrigerant injection hole (not shown) provided in the housing 112 adjacent to the part 102, the inside of the circulation loop is vacuumed, the refrigerant is injected, and the production is completed by sealing the refrigerant injection hole. do.

Although the present invention has been described in detail with respect to the above embodiments, it is not limited thereto, and various modifications can be made by those skilled in the art. For example, although the first microchannels 120 and the second microchannels 122 are formed in a straight line shape, the first microchannels 120 and the second microchannels 122 may be formed in a curved shape, and of course, various shapes of the heat insulating part 116 may be formed. In addition, the coolant and the housing may be selected and used as well as appropriate materials, and the dimensions and shapes thereof may be appropriately designed and used.

According to the present invention, the microchannels of the evaporator and the condenser have a surface tension greater than that of gravity, so that the refrigerant can be naturally circulated without the influence of gravity without supplying external power, thereby providing an installation location and a method of installation. It is not restricted to.

In addition, according to the present invention, by the thermal insulation to thermally and physically separate the liquid refrigerant moving part and the gaseous refrigerant moving part to achieve the stability of the refrigerant flow, and to suppress the mixing limit to increase the mass flow rate of the refrigerant to increase the cooling efficiency Improved.

In addition, according to the present invention, the evaporator and the condenser are arranged on the same plane to form a housing in the form of a thin plate, and the contact heat resistance is reduced by fixing the cooling device on the flat external heat source by fixing means without a separate heat conductor. Improved cooling efficiency

Further, according to the present invention, the liquid coolant moving unit is disposed along both outer sides of the cooling apparatus, and is configured as a circulation loop in both directions to increase the supercooling effect of the coolant, and to the liquid coolant moving unit to one liquid coolant moving unit by gravity head. When the circulation is not circulated, the liquid phase moving part on the opposite side smoothly flows the refrigerant, thereby improving the cooling efficiency.

Claims (19)

A thin plate-shaped housing having a circulation loop of the fluid inside; And It may cause a phase change, and comprises a refrigerant circulating in the circulation loop in the housing, The circulation loop in the housing, A refrigerant storage unit formed at one end of the housing and configured to store a liquid refrigerant; And at least one first microchannel connected to one end of the refrigerant storage unit, wherein the liquid phase refrigerant flows from the refrigerant storage unit by surface tension with an inner wall of the first microchannel in the first microchannel. The liquid refrigerant partially filled to a predetermined portion of the first microchannel, the surface tension in the first microchannel being greater than gravity, and filled in the first microchannel by heat absorbed from a heat source. Evaporation unit capable of vaporizing; At least one second microchannel spaced apart from the first microchannel in the longitudinal direction by a predetermined distance in the longitudinal direction and capable of condensing the refrigerant in the vaporized and moved gas in the first microchannel, A condenser configured to have a surface tension between the inner wall of the second microchannel and the condensed refrigerant greater than gravity; A gas phase refrigerant moving unit positioned between the first microchannel of the evaporator and the second microchannel of the condenser; And And a liquid phase refrigerant moving unit which transfers the liquid refrigerant condensed in the condensation unit to the refrigerant storage unit and is separated from the gas phase refrigerant moving unit. The thin plate cooling apparatus according to claim 1, wherein the gas phase refrigerant moving part and the liquid phase refrigerant moving part are separated from each other by a heat insulating part. 3. The thin plate cooling device according to claim 2, wherein the heat insulating part is sealed in the housing. 3. The thin plate cooling device according to claim 2, wherein the heat insulating part is opened to pass through the housing. The apparatus of claim 1, wherein the gaseous refrigerant moving part is located at the center of the thin plate housing, and the liquid refrigerant moving part is located in both directions along the outer sides of the housing. The thin plate cooling apparatus according to claim 1, further comprising a fixing unit adjacent to the evaporating unit and capable of closely fixing the evaporating unit to a heat source. The thin plate cooling apparatus according to claim 1, wherein the liquid refrigerant moving unit comprises at least one third microchannel in which the surface tension between the liquid refrigerant and the inner wall of the liquid refrigerant moving unit is greater than gravity. The thin plate cooling apparatus of claim 1, wherein the housing is made of any one of a semiconductor material, a metal material, a plastic material, a ceramic material, glass, and a metal alloy material. The thin plate cooling apparatus according to claim 1, wherein the first microchannel and the second microchannel are formed at a depth in a range of 10 ^-9 m to 10 ^-3 m. The thin plate cooling apparatus according to claim 1, wherein the inner wall of the first microchannel is hydrophilic. The thin plate cooling apparatus according to claim 1, wherein the surface roughness of the first microchannel and the second microchannel is in a range of about 1 μm to about 100 μm. The thin plate cooling apparatus of claim 1, wherein the first microchannels are formed in a single layer arrangement in which a plurality of the first microchannels are arranged on the same surface. The thin plate cooling apparatus according to claim 1, wherein a plurality of the first microchannels are arranged on the same surface, and the upper portions of the adjacent first microchannels are opened and connected to each other. The thin plate cooling apparatus according to claim 1, wherein the first microchannels are arranged in multiple layers above and below. The thin plate cooling according to claim 1, wherein a thickness of a bottom surface of the housing is formed on the bottom surface of the housing in contact with a heat source at a boundary between the refrigerant storage portion and the evaporation portion in a direction orthogonal to a heat flow direction. Device. The thin plate type cooling apparatus of claim 1, wherein the gaseous refrigerant moving unit further includes a plurality of first guides for uniformly moving the gaseous refrigerant to the condensation unit. The thin plate cooling apparatus according to claim 1, wherein the liquid coolant moving part has a plurality of grooves formed in a moving direction of the liquid coolant. The method of claim 1, wherein the plurality of second guides for guiding the movement of the liquid refrigerant in the boundary portion of the refrigerant reservoir and the liquid refrigerant moving portion and the boundary portion of the condensation portion and the liquid refrigerant movement portion is further formed. Thin plate chiller. The thin plate type cooling apparatus of claim 1, wherein a cross-sectional area of the gaseous refrigerant moving part is wider than a cross-sectional area of the outlet side of the first microchannel of the evaporator.