KR102045278B1 - Cooling Apparatus using thermoelectric module, and motor operated valve coupled with the same - Google Patents

Abstract

The present invention relates to a cooling apparatus using a thermoelectric module and an electric valve coupled thereto, and more particularly, to a cooling apparatus using a thermoelectric module for cooling a cooling target positioned in a high temperature environment using a thermoelectric module and an electric motor coupled thereto. It is about a valve.
The present invention, the thermoelectric module unit including at least one thermoelectric module 300, the first heat exchange unit 310 and the second heat exchange unit 320 coupled to the heat dissipation unit and the heat absorbing unit of the thermoelectric module 300, respectively. Wow; A first heat exchange space is formed for heat exchange with the first heat exchange unit 310, and at least one opening 110 is formed to suck air from the outside and flow to the first heat exchange unit 310 to be discharged to the outside after heat exchange. A first housing 100; An air inlet 210 and an air outlet 220 are formed to form a first heat exchange space for heat exchange with the first heat exchanger 310, and form the second air flow path P2 in the first heat exchanger 310. It discloses a cooling device using a thermoelectric module characterized in that it comprises a second housing 200 is formed.

Description

Cooling Apparatus using thermoelectric module, and motor operated valve coupled with the same}

The present invention relates to a cooling apparatus using a thermoelectric module and an electric valve coupled thereto, and more particularly, to a cooling apparatus using a thermoelectric module for cooling a cooling target positioned in a high temperature environment using a thermoelectric module and an electric motor coupled thereto. It is about a valve.

An electric valve is a valve that is provided for remote control or automatic control of a valve for controlling steam, air, gas, water, oil, etc., which is a combination of a connecting mechanism and a valve body for an electric motor for operation. Is on the rise.

However, the electric valve has a problem in that a high temperature environment is formed inside the electric valve due to overheating of the valve housing for controlling the electric motor and the motor installed in the electric valve while the continuous use and the frequency of use increase.

In particular, in the case of the electric valve for regulating the flow of heat-sensitive content, such as gas or oil, such a high temperature environment has a problem that can cause a big accident.

Therefore, the cooling device for the cooling of the motor and the valve housing for the control of the motor has been additionally installed, but in the case of the existing cooling device is additionally attached to the outside of the electric valve to cool the electric valve installation is inconvenient to install have.

In addition, there is a problem in that the cooling efficiency is lowered in the case of the electric valve of the additional form attached to the outside.

Korean Patent Registration No. 10-1811299 (published Dec. 15, 2017)

It is an object of the present invention to provide a cooling device using a thermoelectric module that can maximize the cooling efficiency of the control unit for controlling the electric valve, and an electric valve coupled thereto in order to solve the above problems.

The present invention has been created in order to achieve the object of the present invention as described above, the present invention, one or more thermoelectric module 300, the first heat exchange is respectively coupled to the heat dissipation portion and the heat absorbing portion of the thermoelectric module 300 A thermoelectric module unit including a unit 310 and a second heat exchange unit 320; A first heat exchange space is formed for heat exchange with the first heat exchange unit 310, and at least one opening 110 is formed to suck air from the outside and flow to the first heat exchange unit 310 to be discharged to the outside after heat exchange. A first housing 100; An air inlet 210 and an air outlet 220 are formed to form a second heat exchange space for heat exchange with the second heat exchange part 320, and form a second air flow path P2 passing through the second heat exchange part 320. Disclosed is a cooling apparatus using a thermoelectric module, characterized in that it comprises a second housing (200) formed.

The first housing 100 and the second housing 200 are stacked on each other to have a rectangular parallelepiped shape, and the first housing 100 is formed of the first housing 100 and the second housing 200. A pair of the openings 110 for inflow and outflow of air are formed on a pair of side surfaces facing each other perpendicular to the stacking direction, and the air inlet 210 and the air outlet 220 are the It may be formed on the bottom surface of the second housing 200 facing the portion coupled to the first housing 100.

Air flow along the first air passage (P1) is formed so that heat exchange with the first heat exchange part (310) is performed by the air flow of the first air passage (P1) connecting the pair of openings (110). The first air flow forming unit 130 may be installed in at least one of the pair of openings 110.

Between the air inlet 210 and the second heat exchange part 320 of the second air flow path (P2) is a temperature measuring unit 400 for measuring the temperature of the air flowing through the air inlet 210 It can be installed additionally.

The second housing 200 forms the second air flow path P2 such that the air sucked through the air inlet 210 flows through the second heat exchange part 320 to the air outlet 220. One or more flow path forming housing 330 may be further included.

The first heat exchange part 310, the first heat exchange plate 311 is fixed to the first housing 100 and one surface is in surface contact with the heat dissipation portion of the thermoelectric module 300; A plurality of heat exchange members 312 are coupled to the other surface of the first heat exchange plate 311 to perform heat exchange by air flow along the first air flow path P1.

The plurality of heat exchange members 312 may be stacked in a direction parallel to the other surface of the first heat exchange plate 311.

The heat exchange member 312 has a main plate 312b and an upper end and a lower end of the main body plate 312b such that a cross section in the normal direction of the other surface of the first heat exchange plate 311 forms a 'c' shape. And a top portion 312a and a bottom portion 312c protruding in one direction, and at least one of the top portion 312a and the bottom portion 312c is provided with a coupling portion 313 for coupling with an adjacent heat exchange member 312. Can be.

The coupling portion 313 may further have an annular shape so as to be further protruded from at least one of the upper end portion 312a and the lower end portion 312c so as to be caught by the protrusion 314 formed in the adjacent heat exchange member 312.

The first heat exchange part 310 may include at least one first heat exchange plate 311 whose surface is in surface contact with the heat dissipation part of the thermoelectric module 300; A plurality of heat pipes 612 having one end coupled to the first heat exchange plate 311 and disposed in parallel to each other; The plurality of heat dissipation fin members 613 are sequentially inserted into the plurality of heat pipes 612 to perform heat exchange by air flow along the first air passage P1 together with the plurality of heat pipes 612. It may include.

One or more first heat exchange plates 311 may be in surface contact with a heat radiating portion of the thermoelectric module 300.

The first heat exchange plate 311 includes a plurality of inserts in which each of the plurality of heat pipes 612 is inserted into one surface of the upper and lower surfaces of the first heat exchange plate 311 that is in close contact with the thermoelectric module 300. Grooves 611a may be formed.

The insertion groove 611a may be formed on one surface of the upper surface and the lower surface of the first heat exchange plate 311 that are in close contact with the thermoelectric module 300 so that each of the plurality of heat pipes 612 may be inserted therein.

The heat pipe 612 has a rod shape having a length and a flat portion 612a is formed to form one surface together with one surface of the first heat exchange plate 311 in a state of being inserted into the insertion groove 611a. Can be.

The present invention also provides a cooling device having the above configuration; At least one cooling object 1 for driving and controlling the electric valve is installed therein and corresponding to the air inlet 210 and the air outlet 220 to cool the cooling object 1. 11) and a valve housing 10 formed with an inlet 12 is disclosed.

The electric valve is coupled between the air inlet 210 and the outlet 11, between the air outlet 220 and the inlet 12, respectively, the valve housing together with the second air passage (P2) ( 10) may include a pair of connecting members 21 and 22 forming an air circulation passage connecting the inside of the apparatus.

The cooling device may be fixed to the valve housing 10 by one or more coupling belts 500 installed to surround the valve housing 10 and the cooling device.

The coupling belt 500 may be fitted to a ring portion 140 protruding outward from at least one of the first housing 100 and the second housing to fix the cooling device to the valve housing 10. .

Cooling apparatus using a thermoelectric module according to the present invention and the electric valve coupled thereto, the first heat exchanger and the second heat exchanger are respectively installed in the first housing for heat dissipation and the second housing coupled to the structure for cooling heat exchange By doing so, there is an advantage that can significantly increase the cooling efficiency.

In addition, the cooling device using the thermoelectric module according to the present invention and the electric valve coupled thereto, there is an advantage that can be maximized heat exchange efficiency of the heat exchange members by having a plurality of heat exchange members installed in parallel to the direction of the formation of the first flow path. .

In addition, the cooling device using the thermoelectric module according to the present invention and the electric valve coupled thereto, there is an advantage that can maximize the heat exchange efficiency by installing an air flow forming unit on one side of the first housing in which the first flow path is formed.

In addition, the cooling device using the thermoelectric module according to the present invention and the electric valve coupled thereto, the heat exchange member for at least one of the heat absorbing portion and the heat dissipating portion of the thermoelectric module is bent at least one of the top and bottom ' It has a c-shaped shape, and has an annular shape so as to protrude from at least one of the upper end and the lower end so as to be locked to the protrusion formed on the adjacent heat exchange member.

In particular, the heat exchange member is formed of a sheet metal member of a metal material, as shown in Figure 4, by pressing the heat exchange member in order to combine as shown in FIG. .

1 is a perspective view showing an example of an electric valve equipped with a cooling device using a thermoelectric module according to a first embodiment of the present invention.
FIG. 2 is an exploded perspective view showing the cooling device and the electric valve of FIG. 1.
3 is a cross-sectional view showing a cross section of the cooling device and the electric valve of FIG. 1 viewed in the III-III direction.
4 is a partial perspective view showing a part of a second heat exchange part of the cooling device of FIG. 1.
FIG. 5 is an enlarged partial perspective view illustrating a coupling structure of heat exchange members forming the second heat exchange unit of FIG. 4.
6 is a perspective view showing an example of an electric valve provided with a cooling device using a thermoelectric module according to a second embodiment of the present invention.
FIG. 7 is an exploded perspective view showing the cooling device and the electric valve of FIG. 6.
FIG. 8 is a cross-sectional view showing a cross section of the cooling device and the electric valve of FIG. 6 as viewed from the Ⅷ-Ⅷ direction.
FIG. 9 is a plan view showing a part of a first heat exchange part of the cooling apparatus of FIG. 6.
FIG. 10 is a cross-sectional view showing a cross section taken along the Ⅹ-Ⅹ direction in FIG. 9.

Hereinafter, a cooling apparatus using a thermoelectric module according to the present invention and an electric valve coupled thereto will be described in detail with reference to the accompanying drawings.

Cooling apparatus using a thermoelectric module according to the present invention, as shown in Figures 1 to 5, one or more thermoelectric module 300, the first heat exchanger is coupled to each of the heat dissipating portion and the heat absorbing portion of the thermoelectric module 300 A thermoelectric module unit including a 310 and a second heat exchange unit 320; A first heat exchange space is formed for heat exchange with the first heat exchange unit 310, and the first heat exchange space is formed so that one or more openings 110 are formed to suck air from the outside and flow to the first heat exchange unit 310 to be discharged to the outside after heat exchange. A housing 100; An air inlet 210 and an air outlet 220 are formed to form a second heat exchange space for heat exchange with the second heat exchanger 320, and form a second air flow path P2 passing through the second heat exchanger 320. It includes a second housing 200 formed.

The thermoelectric module unit may include one or more thermoelectric modules 300 and a first heat exchanger 310 and a second heat exchanger 320 coupled to the heat dissipation unit and the heat absorbing unit of the thermoelectric module 300, respectively. Configuration is possible.

For example, the one or more thermoelectric modules 300 may be connected to a pair of substrates, a plurality of thermoelectric elements (not shown) installed between the pair of substrates, and a thermoelectric element (not shown) to supply power. It may include a power applying unit (not shown).

In this case, a variety of materials such as metal and ceramic may be used for the substrate, but a ceramic material is preferably used in consideration of thermal expansion.

Here, the pair of substrates function as a heat dissipation unit and one as a heat absorbing unit according to the arrangement of the thermoelectric elements.

In addition, the thermoelectric module 300 is preferably installed in plural in consideration of cooling or heating capacity, such as two or four for the convenience of manufacturing, in order to prevent the parts other than the power supply unit from being exposed to the outside, It may be inserted into each of the openings formed in the heat insulating member 301 such as styrofoam.

For example, as illustrated in FIG. 2, a plurality of thermoelectric modules 300 may be installed along a direction of the first air flow path P1 to which a thermoelectric module 300 having a planar shape is formed in a rectangle. The thermoelectric module formed in a rectangular shape may be inserted into an opening formed in the heat insulating member 301 so as to prevent portions other than the power applying unit from being exposed to the outside.

The first heat exchange part 310 and the second heat exchange part 320 are respectively coupled to the heat dissipation part and the heat absorbing part of the thermoelectric module 300 to each of the first housing 100 and the second housing 200 which will be described later. Various configurations are possible as the configuration for heat exchange with the air flowing along the formed first air passage (P1) and the second air passage (P2).

In particular, the first heat exchanger 310 and the second heat exchanger 320 may have various structures according to a heat exchange method.

For example, the first heat exchange part 310 may include: a first heat exchange plate 311 fixed to the first housing 100 and having one surface thereof in surface contact with the heat dissipation part of the thermoelectric module 300; A plurality of heat exchange members 312 may be coupled to the other surface of the first heat exchange plate 311 to perform heat exchange by air flow along the first air flow path P1.

The first heat exchange plate 311 is a member fixed to the first housing 100 and one surface of the first heat exchange plate 311 is in surface contact with the heat dissipation portion of the thermoelectric module 300, and a metal material such as aluminum and copper having a high heat transfer rate is preferably used. .

The plurality of heat exchange members 312 are coupled to the other surface of the first heat exchange plate 311 to perform heat exchange by air flow along the first air flow path P1. Various configurations are possible according to a heat exchange method. .

For example, the plurality of heat exchange members 312 may be stacked in a direction parallel to the other surface of the first heat exchange plate 311 as a plate member.

In particular, the heat exchange member 312, the main plate 312b and the top and bottom of the main body plate 312b such that the cross section in the normal direction of the other surface of the first heat exchange plate 311 forms a '' 'shape The upper portion 312a and the lower portion 312c protruding in one direction, and at least one of the upper portion 312a and the lower portion 312c may be formed with a coupling portion 313 for coupling with the adjacent heat exchange member 312. have.

The coupling portion 313 is formed on at least one of the upper end portion 312a and the lower end portion 312c of the body plate 312b and is configured to couple with the adjacent heat exchange member 312. It is possible.

As an example, the coupling part 313 is configured to have an annular shape so as to be further protruded from at least one of the upper end part 312a and the lower end part 312c so as to be caught by the protrusion part 314 formed in the adjacent heat exchange member 312. Can be.

The heat exchange member 312 having the above configuration may be simply fitted by pressing the adjacent heat exchange member 312 by the structure of the coupling portion 313 after being formed by press working or the like.

By assembling a plurality of heat exchange members 312 sequentially by the simple assembly as described above, the assembly is easy and the heat exchange with the air and the coupling with the first heat exchange plate 311 is easy.

Meanwhile, the lower end 312c of the heat exchange member 312 may be coupled to the first heat exchange plate 311 through brazing or the like.

In addition, the heat exchange member 312, the body plate 312b may be coupled to form a perpendicular to the other surface of the first heat exchange plate (311).

Meanwhile, the second heat exchange part 320 may be configured in various ways according to a heat exchange method, and may have the same or similar structure as the first heat exchange part 310 described above.

For example, the second heat exchange part 320 may include a second heat exchange plate 321 having one surface thereof in surface contact with an endothermic portion of the thermoelectric module 300; It may include a plurality of heat exchange members 322 coupled to the other surface of the second heat exchange plate 321 to perform heat exchange by air flow along the second air flow path P2.

Here, the second heat exchange part 320 is different from the first heat exchange part 310, and the second heat exchange plate 321 is formed to protrude at a position corresponding to the thermoelectric module 300 to provide the thermoelectric module 300. Protruding portion 323 in contact with the surface may be additionally installed.

The protrusion 323 is formed to protrude at a position corresponding to the thermoelectric module 300 to maintain the distance from the first heat exchange plate 311 described above with respect to the second heat exchange plate 321, the thermoelectric module 300 ) And various configurations are possible.

For example, the protrusion 323 may have various structures as long as the protrusion 323 is formed at a position where the thermoelectric module 300 is in surface contact with the thermoelectric module 300 and is formed to be insertable into the heat transfer member 301.

Meanwhile, the second heat exchange plate 321 maintains a sufficient distance from the first heat exchange plate 311 to the second heat exchange plate 321 by forming the protrusion 323, that is, the first heat exchange plate 311. In addition, by increasing the thickness formed by the thermoelectric module 300 and the second heat exchange plate 321, the upper end of the flow path forming housing 330 to be described later can be stably fixed to the side of the second heat exchange plate 321.

The first housing 100 forms a first heat exchange space for heat exchange with the first heat exchanger 310, and sucks air from the outside to flow to the first heat exchanger 310 to be discharged to the outside after heat exchange. Various configurations are possible with the above configuration in which the opening 110 is formed.

For example, the first housing 100 and the second housing 200 may be stacked on each other to have a rectangular parallelepiped shape, and the first housing 100 may include the first housing 100 and the second housing 200. A pair of the openings 110 may be formed on the pair of side surfaces of the pair opposite to each other perpendicular to the stacking direction of the air inlet).

That is, the pair of openings 110 may be formed on a pair of side surfaces which face each other to form a vertical direction, so that the pair of openings 110 may be perpendicular to a stacking direction of the first housing 100 and the second housing 200. An air flow path P1 can be formed.

On the other hand, the first housing 100, the first air flow path (P1) so that the heat exchange with the first heat exchange unit 310 by the air flow of the first air flow path (P1) connecting the pair of openings (110). The first air flow forming unit 130 forming the air flow along the) may be installed in at least one of the pair of openings (110).

The first air flow forming unit 130 is configured to form an air flow in the first air flow path (P1) so that heat exchange with the first heat exchange unit 310 is possible in various configurations.

The first air flow forming unit 130 may have various configurations such as a fan as a configuration for forming air flow.

The second housing 200 forms a second heat exchange space for heat exchange with the second heat exchange part 320, and forms a second air flow path P2 passing through the second heat exchange part 320. As a configuration in which the 210 and the air outlet 220 are formed, various configurations are possible.

Here, the second housing 200 may have a rectangular parallelepiped shape similar to the first housing 100 having the rectangular parallelepiped shape described above.

In particular, the second housing 200 may be formed on the bottom surface of the second housing 200 in which the air inlet 210 and the air outlet 220 are opposed to the portion where the air inlet 210 is coupled to the first housing 100.

The second housing 200 may include one or more flow paths forming the second air flow path P2 such that the air sucked through the air inlet 210 flows through the second heat exchange part 320 to the air outlet 220. Forming housing 330 may further include.

The flow path forming housing 330 is configured to form a second air flow path P2 such that the air sucked through the air inlet 210 flows through the second heat exchange part 320 to the air outlet 220. Any configuration can be used as long as it is a good configuration.

For example, the flow path forming housing 330 may have an upper side such that the second heat exchange plate 321 and the second heat exchange part 320 coupled thereto may be penetrated into the flow path forming housing 330. An opening and an air inlet 210 and an air outlet 220 may be formed at the lower side.

In addition, the flow path forming housing 330 allows the second air flow path P2 to be formed in an inverted 'U' shape connecting the air inlet 210 and the air outlet 220 to form a smooth air flow. This is preferred.

In addition, the flow path forming housing 330 may have an air guide inlet 331 connected to the air inlet 210 and an air guide outlet 332 connected to the air outlet 220.

Here, the air guide inlet 331 and the air guide outlet 332, of course, may form an air inlet 210 and the air outlet 220, respectively.

In addition, at least one of the guide inlet 331 and the guide outlet 332 may be provided with a second air flow forming unit 340 for increasing the air flow rate of the second air flow path (P2).

The second air flow forming unit 340 may have various configurations such as a fan as a configuration for forming air flow.

On the other hand, between the air inlet 210 and the second heat exchanger 320 of the second air flow path (P2), a temperature measuring unit 400 for measuring the temperature of the air flowing through the air inlet 210 is added Can be installed as

The temperature measuring unit 400 is installed between the air inlet 210 and the second heat exchanger 320 of the second air flow path P2 to measure the temperature of the air introduced through the air inlet 210. As a configuration, various sensors such as a temperature sensor can be used.

The temperature measuring unit 400 may be utilized to control the operation of the cooling device (on off, cooling rate, etc.) by measuring the temperature of the air flowing through the air inlet 210.

On the other hand, the cooling device having the configuration as described above, can be used to cool the inside of the cooling target is coupled to the cooling target formed with the outlet and the inlet and the air inlet 210 and the air outlet 220 is in communication.

Here, the cooling target is a device used in a high temperature environment such as a power plant, a steel mill, a tropics, a desert, etc., and an outlet and an inlet communicating with the air inlet 210 and the air outlet 220 are formed and a PCB installed therein. It can be utilized to cool the members installed therein.

Hereinafter, as an example in which the cooling device according to the present invention is combined, an electric valve will be described.

In the electric valve to which the cooling device according to the present invention is coupled, the cooling device described above and at least one cooling object 1 for driving and controlling the electric valve are installed therein, and an air inlet for cooling the cooling object 1 is provided. Corresponding to the 210 and the air outlet 220 may include a valve housing 10 is formed with an outlet 11 and the inlet 12 on the side.

Here, the electric valve is an electric valve for opening and closing the pipe through rotation, linear movement, and the like, as shown in FIGS. 1 to 3, and various configurations are possible according to its driving method.

For example, the electric valve may include a valve housing 10 having one or more cooling objects 1 installed therein for driving and controlling the electric valve, and protrudes out of the valve housing 10 to rotate, move linearly, and the like. It may include a driving rod (2) to implement.

The valve housing 10 has at least one cooling object 1 installed therein for driving and controlling the electric valve and corresponds to the air inlet 210 and the air outlet 220 to cool the cooling object 1. As a configuration in which the outlet 11 and the inlet 12 is formed on the side, various configurations are possible.

Here, the outlet 11 and the inlet 12 are openings corresponding to the air inlet 210 and the air outlet 220 as openings formed in the side surfaces of the valve housing 10, and the air inlet 210 and the air outlet 220. In the manufacturing of the electric valve in a position corresponding to the pre-formed, or may be subsequently formed for the coupling of the cooling device in a position corresponding to the air inlet 210 and the air outlet 220 in the ready-made product.

For example, the valve housing 10 may be formed in a cylindrical shape in which an outlet port 11 and an inlet port 12 coupled to each of the connecting members 20 are formed, and the driving rod 2 may protrude outward. The through hole 13 may be formed to be.

In addition, the through hole 13 may further include an extension part 14 for guiding the driving rod 2 to be exposed to the outside.

On the other hand, the valve housing 10, an opening for installing the cooling target 1 therein may be formed at at least one end of the both ends, the opening may be covered by the cover portion (16).

The cover portion 16 is configured to cover the opening of the valve housing 10, and various configurations are possible.

For example, the cover part 16 is a plate installed to cover the opening of the valve housing 10, and the plate may be fastened by a fastening member (not shown).

The fastening member is configured to be coupled to the cover portion 16 and the valve housing 10, and may be configured in various configurations as long as it is a configuration for coupling the valve housing 10 and the cover portion 16 to each other.

For example, the fastening member may be one or more screws coupling one or more coupling assistants 15 and the cover 16 to be radially protruded to the outside of the valve housing 10.

Meanwhile, the air is coupled between the air inlet 210 and the outlet 11, between the air outlet 220 and the inlet 12, respectively, and connects the inside of the valve housing 10 together with the second air passage P2. The pair of connecting members 21 and 22 forming the circulation passage may be additionally installed.

The pair of connecting members 21 and 22 are coupled between the air inlet 210 and the outlet 11, and between the air outlet 220 and the inlet 12, respectively, so that the valve together with the second air passage P2 is provided. Various configurations are possible as a configuration for forming an air circulation passage connecting the inside of the housing 10.

In particular, when the pair of connecting members 21 and 22 have a cylindrical shape, the air inlet 210 and the outlet 11, between the air outlet 220 and the inlet 12, may have a cylindrical shape. It is preferable to be installed for the smooth air flow of.

Meanwhile, when the pair of connecting members 21 and 22 are installed, a sealing member for sealing may be installed at the side of the valve housing 10 and in contact with the second housing 200.

The sealing member is used as an elastic plastic, an O-ring, etc., and is installed on the side of the valve housing 10 and in contact with the second housing 200 when the pair of connecting members 21 and 22 are installed. Can be prevented from leaking to the outside.

On the other hand, the cooling device is preferably fixed to the valve housing 10 by one or more coupling belts 500 installed to surround the valve housing 10 and the cooling device.

The one or more coupling belts 500 are installed to surround the valve housing 10 and the cooling device, and various configurations are possible to fix the cooling device to the valve housing 10.

For example, the coupling belt 500 may be configured to be fitted to a ring portion 140 protruding outward from at least one of the first housing 100 and the second housing to fix the cooling device to the valve housing 10. have.

The coupling belt 500 may be a strap member having elasticity, and the strap member may be fastened by the fastening member coupling part 510.

The fastening member coupling part 510 is configured to be fastened to the coupling belt 500 installed for fixing the first housing 100, the second housing 200, and the valve housing 10. This is possible.

And the ring portion 140 is formed to prevent the separation of the coupling belt 500, if the structure that can prevent the separation of the coupling belt 500, various structures and forms are possible.

The cooling target 1 is installed in the interior space of the valve housing 10 and can be variously configured as a configuration to be cooled.

For example, the cooling object 1 may be any member as long as it is a member that is concerned about damage, malfunction or the like when overheated, such as a drive circuit for driving an electric valve, an electric / electronic device, or the like.

On the other hand, the cooling device according to the present invention may be spatially restricted depending on the installation conditions for the combined electric valve.

For example, there may be various constraints on the installation of the cooling device, such as a restriction on the height of the cooling device that can be installed above the electric valve, a length limitation of the electric valve in the longitudinal direction.

Thus, the cooling device according to the present invention may have various appearance structures depending on installation constraints.

Hereinafter, a second embodiment of a cooling apparatus according to the present invention will be described with reference to the accompanying drawings.

The cooling apparatus according to the present invention is, as a second embodiment, as shown in Figures 1 to 8, the one or more thermoelectric module 300, and the first and second heat coupled to the heat dissipation portion and the heat absorbing portion of the thermoelectric module 300, respectively A thermoelectric module unit including a first heat exchanger 310 and a second heat exchanger 320; A first heat exchange space is formed for heat exchange with the first heat exchange unit 310, and the first heat exchange space is formed so that one or more openings 110 are formed to suck air from the outside and flow to the first heat exchange unit 310 to be discharged to the outside after heat exchange. A housing 100; An air inlet 210 and an air outlet 220 are formed to form a second heat exchange space for heat exchange with the second heat exchanger 320, and form a second air flow path P2 passing through the second heat exchanger 320. It includes a second housing 200 formed.

The thermoelectric module unit may include one or more thermoelectric modules 300 and a first heat exchanger 310 and a second heat exchanger 320 coupled to the heat dissipation unit and the heat absorbing unit of the thermoelectric module 300, respectively. Configuration is possible.

For example, the one or more thermoelectric modules 300 may be connected to a pair of substrates, a plurality of thermoelectric elements (not shown) installed between the pair of substrates, and a thermoelectric element (not shown) to supply power. It may include a power applying unit (not shown).

In this case, a variety of materials such as metal and ceramic may be used for the substrate, but a ceramic material is preferably used in consideration of thermal expansion.

Here, the pair of substrates function as a heat dissipation unit and one as a heat absorbing unit according to the arrangement of the thermoelectric elements.

In addition, the thermoelectric module 300 is preferably installed in plural in consideration of cooling or heating capacity, such as two or four for the convenience of manufacturing, in order to prevent the parts other than the power supply unit from being exposed to the outside, It may be inserted into each of the openings formed in the heat insulating member 301, such as styrofoam.

For example, as illustrated in FIG. 7, a plurality of thermoelectric modules 300 may be installed along a direction of the first air flow path P1 to which a thermoelectric module 300 having a planar shape having a rectangular shape will be described later. The thermoelectric module formed in a rectangular shape may be inserted into an opening formed in the heat insulating member 301 so as to prevent portions other than the power applying unit from being exposed to the outside.

The first heat exchange part 310 and the second heat exchange part 320 are respectively coupled to the heat dissipation part and the heat absorbing part of the thermoelectric module 300 to each of the first housing 100 and the second housing 200 which will be described later. Various configurations are possible as the configuration for heat exchange with the air flowing along the formed first air passage (P1) and the second air passage (P2).

In particular, the first heat exchanger 310 and the second heat exchanger 320 may have various structures according to a heat exchange method.

The first heat exchange part 310 may include at least one first heat exchange plate 311 whose surface is in surface contact with the heat dissipation part of the thermoelectric module 300; A plurality of heat pipes 612 having one end coupled to the first heat exchange plate 311 and disposed in parallel with each other; A plurality of heat dissipation fin members 613 that are sequentially inserted into a plurality of heat pipes 612 to perform heat exchange by air flow along a first air flow path P1 together with the plurality of heat pipes 612. Can be.

The one or more first heat exchange plates 311 may be configured in various ways as one surface thereof is in surface contact with a heat dissipation unit of the thermoelectric module 300.

The first heat exchange plate 311 is a member in which one surface is in surface contact with the heat dissipation portion of the thermoelectric module 300, and a metal material such as aluminum and copper having a high heat transfer rate is preferably used.

Meanwhile, the first heat exchange plate 311 may include a plurality of insertion grooves in which each of the plurality of heat pipes 612 is inserted into one surface of the upper and lower surfaces of the first heat exchange plate 311 that is in close contact with the thermoelectric module 300. 611a may be formed.

The insertion groove 611a is formed on one surface of the upper and lower surfaces of the first heat exchange plate 311 so as to be in close contact with the thermoelectric module 300 so that each of the plurality of heat pipes 612 is inserted by various methods. Can be formed.

In particular, the insertion groove 611a, the heat pipe 612 is in direct contact with the heat dissipation portion of the thermoelectric module 300, so that the heat exchange with the heat dissipation portion of the thermoelectric module 300 efficiently thermoelectric module 300 It is preferably formed on the surface in close contact with the heat radiating portion of the.

As described above, the heat pipe 612 is coupled to one surface in close contact with the thermoelectric module 300, so that the heat pipe 612 is in direct contact with the heat dissipation part of the thermoelectric module 300 and the heat dissipation part of the thermoelectric module 300. By efficiently performing the heat exchange of the cooling efficiency of the cooling apparatus according to the present invention can be greatly improved.

The plurality of heat pipes 612, one end is coupled to the first heat exchange plate 311 and arranged in parallel with each other can be used as long as the heat pipe.

The heat pipe 612 may have a rod shape having a long length as a commodity, and may have various shapes such as a straight line, a curved line, and a '-' shape according to the structure of the first heat exchange part 310.

On the other hand, the heat pipe 612, it is preferable that the flat portion 612a is formed to form one surface with one surface of the first heat exchange plate 311 in the inserted state (611a).

The planar portion 612a is formed as a part of the heat pipe 612 having a circular or polygonal cross section, and the heat pipe 612 of the first heat exchange plate 311 is inserted into the insertion groove 611a. By forming one surface, the contact area of the first heat exchange plate 311 and the heat dissipation unit of the thermoelectric module 300 can be increased to greatly improve the cooling efficiency of the cooling apparatus according to the present invention.

In particular, the heat pipe 612 is effectively coupled to one surface closely contacted with the thermoelectric module 300 by the flat part 612a so that the heat pipe 612 is in direct contact with the heat dissipation part of the thermoelectric module 300 and the thermoelectric module 300 Efficient heat exchange with the heat dissipation unit of the) can greatly improve the cooling efficiency of the cooling apparatus according to the present invention.

That is, when the heat pipe 612 is coupled to one surface of the first heat exchange plate 311 that is in close contact with the heat dissipation portion of the thermoelectric module 300, the first heat exchange plate 311 and the cylindrical heat pipe 612 by The contact area between the heat dissipating parts of the thermoelectric module 300 is reduced, and the heat pipe 612 is effectively coupled to one surface of the heat pipe 612 in close contact with the thermoelectric module 300 by the planar part 612a. Direct contact with the heat dissipation part of the 300 and heat exchange with the heat dissipation part of the thermoelectric module 300 can be efficiently performed.

Meanwhile, the flat part 612a is formed by being deformed to form one surface together with one surface of the first heat exchange plate 311 in a state where the heat pipe 612 is inserted into the insertion groove 611a, or the heat pipe 612. ) May be formed in a portion of the heat pipe 612 by various methods, such as being formed in advance before being inserted into the insertion groove (611a).

7 and 9, the plurality of heat pipes 612 may further protrude outward from an edge of the first heat exchange plate 311 based on the length direction of the plurality of heat pipes 612. Can be.

In this case, it is preferable that the heat dissipation fin members 613 to be described later are coupled at a portion further protruding outward from an edge of the first heat exchange plate 311 among the plurality of heat pipes 612.

As a more specific embodiment, the heat dissipation fin members 613 may be installed to further protrude to one side of both side edges based on the first heat exchange plate 311 having a rectangular planar shape.

This corresponds to the structure of the electric valve to be cooled and optimizes its arrangement.

Here, of course, the heat dissipation fin members 613 may be installed to further protrude outward in pairs from side edges facing each other with respect to the first heat exchange plate 311 having a rectangular planar shape.

Meanwhile, the longitudinal direction of the heat dissipation fin members 613 may be disposed in a direction parallel to the top and bottom surfaces of the first heat exchange plate 311.

The plurality of heat dissipation fin members 613 are sequentially inserted into the plurality of heat pipes 612 to perform heat exchange by air flow along the first air flow path P1 together with the plurality of heat pipes 612. Various configurations are possible.

For example, the plurality of heat dissipation fin members 613 may be vertically stacked in parallel with each other in a vertical direction of the heat pipe 612.

Meanwhile, since the second heat exchange part 320 has the same or similar configuration as that of the first embodiment, detailed description thereof will be omitted.

The first housing 100 forms a first heat exchange space for heat exchange with the first heat exchanger 310, and sucks air from the outside to flow to the first heat exchanger 310 to be discharged to the outside after heat exchange. Various configurations are possible with the above configuration in which the opening 110 is formed.

For example, the first housing 100 and the second housing 200 may be stacked on each other to have a rectangular parallelepiped shape, and the first housing 100 may include the first housing 100 and the second housing 200. One or more openings 110 may be formed corresponding to the installation position of the first heat exchanger 310, in particular, the plurality of heat dissipation fin members 613 in the same direction as the stacking direction of the plurality of layers.

That is, the pair of openings 110 may be formed to penetrate the first housing 100 up and down to form the first air flow path P1 in a direction parallel to the stacking direction.

On the other hand, the first housing 100, the first heat exchange part (1) by the air flow of the first air flow path (P1) passing through the opening 110 and the first heat exchange part 310, in particular a plurality of heat radiation fin member 613. The first air flow forming unit 130, which forms an air flow along the first air flow path P1, may be installed above or preferably below the plurality of heat dissipation fin members 613 to exchange heat with the 310. Can be.

Here, the air flow direction of the first air passage (P1) is preferably made from the upper side to the lower side in consideration of the high temperature of the electric valve side.

The first air flow forming unit 130 is configured to form an air flow in the first air flow path (P1) so that heat exchange with the first heat exchange unit 310 is possible in various configurations.

The first air flow forming unit 130 may have various configurations such as a fan as a configuration for forming air flow.

The second housing 200 forms a second heat exchange space for heat exchange with the second heat exchange part 320, and forms a second air flow path P2 passing through the second heat exchange part 320. As a configuration in which the 210 and the air outlet 220 are formed, various configurations are possible.

Here, the second housing 200 overlaps the opening 110 and the first air flow forming unit 130 in consideration of being able to disturb the air flow by the first air flow forming unit 130. It is preferable to be coupled to the first housing 100 except for the region to be.

In addition, the second housing 200 may have a rectangular parallelepiped shape similar to the first housing 100 having a rectangular parallelepiped shape described above.

In particular, the second housing 200 may be formed on the bottom surface of the second housing 200 in which the air inlet 210 and the air outlet 220 are opposed to the portion where the air inlet 210 is coupled to the first housing 100.

The second housing 200 may include one or more flow paths forming the second air flow path P2 such that the air sucked through the air inlet 210 flows through the second heat exchange part 320 to the air outlet 220. Forming housing 330 may further include.

The flow path forming housing 330 has the same or similar configuration as that of the first embodiment, and thus a detailed description thereof will be omitted.

On the other hand, between the air inlet 210 and the second heat exchanger 320 of the second air flow path (P2), a temperature measuring unit 400 for measuring the temperature of the air flowing through the air inlet 210 is added Can be installed as

Since the temperature measuring unit 400 has the same or similar configuration as that of the first embodiment, detailed description thereof will be omitted.

On the other hand, the cooling device having the configuration as described above, can be used to cool the inside of the cooling target is coupled to the cooling target formed with the outlet and the inlet and the air inlet 210 and the air outlet 220 is in communication.

Here, the cooling target has the same or similar configuration as that of the first embodiment, and thus a detailed description thereof will be omitted.

However, the electric valve 10 to be cooled can be configured in various configurations.

In particular, the electric valve 10, in addition to protecting the outer circumferential surface with respect to the installation of the cooling device may be further provided with an outer housing 30 to prevent heat exchange with the outside air.

The outer housing 30 is installed at intervals from the outer circumferential surface of the electric valve 10 without disturbing the installation of the cooling device, thereby preventing the electric valve 10 from being heated from the outside air when the electric valve 10 is cooled by the cooling device. It can form an isolation space for.

Since the above has been described only with respect to some of the preferred embodiments that can be implemented by the present invention, the scope of the present invention, as is well known, should not be construed as limited to the above embodiments, the present invention described above It will be said that both the technical idea and the technical idea which together with the base are included in the scope of the present invention.

100: first housing 200: second housing
310: first heat exchanger 320: second heat exchanger
300: thermoelectric module

Claims (28)

A thermoelectric module part including at least one thermoelectric module 300 and a first heat exchange part 310 and a second heat exchange part 320 respectively coupled to the heat dissipation part and the heat absorbing part of the thermoelectric module 300;
A first heat exchange space is formed for heat exchange with the first heat exchange unit 310, and the air is sucked from the outside to flow into the first heat exchange unit 310 to discharge the first air flow path P1 discharged to the outside. A first housing 100 in which one or more openings 110 are formed to form;
An air inlet 210 and an air outlet 220 are formed to form a second heat exchange space for heat exchange with the second heat exchange part 320, and form a second air flow path P2 passing through the second heat exchange part 320. ) Is formed a second housing 200,
The first housing 100 and the second housing 200 are stacked on each other to have a rectangular parallelepiped shape,
The first housing 100 has a pair of air inlets and outlets, respectively, on a pair of side surfaces facing each other perpendicular to the stacking direction of the first housing 100 and the second housing 200. The opening 110 is formed,
The first heat exchange unit 310,
A first heat exchange plate 311 fixed to the first housing 100 and having one surface thereof in surface contact with the heat dissipation portion of the thermoelectric module 300; A plurality of heat exchange members 312 coupled to the other surface of the first heat exchange plate 311 to perform heat exchange by air flow along the first air flow path P1,
The plurality of heat exchange members 312 are stacked in a direction parallel to the other surface of the first heat exchange plate 311,
The heat exchange member 312,
The main plate 312b and the upper end 312a protruding in one direction to the upper and lower ends of the main plate 312b so that the cross section in the normal direction of the other surface of the first heat exchange plate 311 forms a 'c' shape. And a lower portion 312c,
The upper portion 312a and the lower portion 312c are formed with a coupling portion 313 for coupling with the adjacent heat exchange member 312,
The coupling part 313 has a ring shape that protrudes further from the upper end part 312a and the lower end part 312c so as to be engaged with the protrusion part 314 formed in the adjacent heat exchange member 312. Cooling device using. A thermoelectric module part including at least one thermoelectric module 300 and a first heat exchange part 310 and a second heat exchange part 320 respectively coupled to the heat dissipation part and the heat absorbing part of the thermoelectric module 300;
A first heat exchange space is formed for heat exchange with the first heat exchange unit 310, and the air is sucked from the outside to flow to the first heat exchange unit 310 to discharge the first air flow path P1 discharged to the outside. A first housing 100 in which one or more openings 110 are formed to form;
An air inlet 210 and an air outlet 220 are formed to form a second heat exchange space for heat exchange with the second heat exchange part 320, and form a second air flow path P2 passing through the second heat exchange part 320. ) Is formed a second housing 200,
The first housing 100 and the second housing 200 are stacked on each other to have a rectangular parallelepiped shape,
The first housing 100 has a pair of air inlets and outlets, respectively, on a pair of side surfaces facing each other perpendicular to the stacking direction of the first housing 100 and the second housing 200. The opening 110 is formed,
The first heat exchange unit 310,
At least one first heat exchange plate 311 whose surface is in surface contact with the heat dissipation portion of the thermoelectric module 300;
A plurality of heat pipes 612 having one end coupled to the first heat exchange plate 311 and disposed in parallel to each other;
The plurality of heat dissipation fin members 613 are sequentially inserted into the plurality of heat pipes 612 to perform heat exchange by air flow along the first air passage P1 together with the plurality of heat pipes 612. Include,
The first heat exchange plate 311 includes a plurality of inserts in which each of the plurality of heat pipes 612 is inserted into one surface of the upper and lower surfaces of the first heat exchange plate 311 that is in close contact with the thermoelectric module 300. Grooves 611a are formed,
The insertion groove 611a is formed on one surface of the upper and lower surfaces of the first heat exchange plate 311 to be in close contact with the thermoelectric module 300 so that each of the plurality of heat pipes 612 is inserted therein.
The heat pipe 612 is,
The thermoelectric module having a rod shape having a length and a flat portion 612a is formed to form one surface together with one surface of the first heat exchange plate 311 in a state of being inserted into the insertion groove 611a. Used chiller. A thermoelectric module part including at least one thermoelectric module 300 and a first heat exchange part 310 and a second heat exchange part 320 respectively coupled to the heat dissipation part and the heat absorbing part of the thermoelectric module 300;
A first heat exchange space is formed for heat exchange with the first heat exchange unit 310, and the air is sucked from the outside to flow to the first heat exchange unit 310 to discharge the first air flow path P1 discharged to the outside. A first housing 100 in which one or more openings 110 are formed to form;
An air inlet 210 and an air outlet 220 are formed to form a second heat exchange space for heat exchange with the second heat exchange part 320, and form a second air flow path P2 passing through the second heat exchange part 320. ) Is formed a second housing 200,
The first heat exchange unit 310,
At least one first heat exchange plate 311 whose surface is in surface contact with the heat dissipation portion of the thermoelectric module 300;
A plurality of heat pipes 612 having one end coupled to the first heat exchange plate 311 and disposed in parallel to each other;
The plurality of heat dissipation fin members 613 are sequentially inserted into the plurality of heat pipes 612 to perform heat exchange by air flow along the first air passage P1 together with the plurality of heat pipes 612. Include,
The first heat exchange plate 311 includes a plurality of inserts in which each of the plurality of heat pipes 612 is inserted into one surface of the upper and lower surfaces of the first heat exchange plate 311 that is in close contact with the thermoelectric module 300. Grooves 611a are formed,
The insertion groove 611a is formed on one surface of the upper and lower surfaces of the first heat exchange plate 311 to be in close contact with the thermoelectric module 300 so that each of the plurality of heat pipes 612 is inserted therein.
The heat pipe 612 has a rod shape having a length and a flat portion 612a is formed to form one surface together with one surface of the first heat exchange plate 311 in a state of being inserted into the insertion groove 611a. ,
The plurality of heat pipes 612 are further protruded to one side of both side edges with respect to the first heat exchange plate 311 having a rectangular planar shape.
The one or more openings 110 are formed to penetrate up and down corresponding to the installation position of the plurality of heat dissipation fin members 613 in the first housing 100,
Cooling apparatus using a thermoelectric module, characterized in that the first air flow forming unit 130 for forming an air flow along the first air flow path (P1) is installed on the upper side or the lower side based on the plurality of heat dissipation fin members (613). The method according to any one of claims 1 to 3,
Air flow along the first air passage (P1) is formed so that heat exchange with the first heat exchange part (310) is performed by the air flow of the first air passage (P1) connecting the pair of openings (110). Cooling apparatus using a thermoelectric module, characterized in that the first air flow forming unit 130 is installed in at least one of the pair of openings (110). The method according to any one of claims 1 to 3,
Between the air inlet 210 and the second heat exchange part 320 of the second air flow path (P2) is a temperature measuring unit 400 for measuring the temperature of the air flowing through the air inlet 210 Cooling apparatus using a thermoelectric module characterized in that the additional installation. The method according to any one of claims 1 to 3,
The second housing 200,
At least one flow path forming housing 330 for forming the second air flow path P2 such that the air sucked through the air inlet 210 flows through the second heat exchange part 320 to the air outlet 220. Cooling apparatus using a thermoelectric module characterized in that it further comprises. delete delete delete delete The method according to any one of claims 2 and 3,
The at least one first heat exchange plate (311), the cooling device using a thermoelectric module, characterized in that one surface is in surface contact with the heat dissipating portion of the thermoelectric module (300). delete delete delete A cooling device;
One or more cooling targets 1 for driving and controlling the electric valve are installed therein and correspond to the air inlet 210 and the air outlet 220 to cool the cooling target 1. And a valve housing 10 in which the inlet 12 is formed,
The cooling device,
A thermoelectric module part including at least one thermoelectric module 300 and a first heat exchange part 310 and a second heat exchange part 320 respectively coupled to the heat dissipation part and the heat absorbing part of the thermoelectric module 300;
A first heat exchange space is formed for heat exchange with the first heat exchange unit 310, and the air is sucked from the outside to flow into the first heat exchange unit 310 to discharge the first air flow path P1 discharged to the outside. A first housing 100 in which one or more openings 110 are formed to form;
The air inlet 210 and the air outlet are formed to form a second heat exchange space for heat exchange with the second heat exchange part 320, and form a second air flow path P2 passing through the second heat exchange part 320. And a second housing 200 in which 220 is formed,
The first heat exchange unit 310,
A first heat exchange plate 311 fixed to the first housing 100 and having one surface thereof in surface contact with the heat dissipation portion of the thermoelectric module 300; A plurality of heat exchange members 312 coupled to the other surface of the first heat exchange plate 311 to perform heat exchange by air flow along the first air flow path P1,
The plurality of heat exchange members 312 are stacked in a direction parallel to the other surface of the first heat exchange plate 311,
The heat exchange member 312,
The main plate 312b and the upper end 312a protruding in one direction to the upper and lower ends of the main plate 312b so that the cross section in the normal direction of the other surface of the first heat exchange plate 311 forms a 'c' shape. And a lower portion 312c,
The upper portion 312a and the lower portion 312c are formed with a coupling portion 313 for coupling with the adjacent heat exchange member 312,
The coupling part 313 has an electric valve further protruding from the upper end portion 312a and the lower end portion 312c so as to be engaged with the protrusion 314 formed on the adjacent heat exchange member 312. . A cooling device;
One or more cooling targets 1 for driving and controlling the electric valve are installed therein and correspond to the air inlet 210 and the air outlet 220 to cool the cooling target 1. And a valve housing 10 in which the inlet 12 is formed,
The cooling device,
A thermoelectric module part including at least one thermoelectric module 300 and a first heat exchange part 310 and a second heat exchange part 320 respectively coupled to the heat dissipation part and the heat absorbing part of the thermoelectric module 300;
A first heat exchange space is formed for heat exchange with the first heat exchange unit 310, and the air is sucked from the outside to flow into the first heat exchange unit 310 to discharge the first air flow path P1 discharged to the outside. A first housing 100 in which one or more openings 110 are formed to form;
An air inlet 210 and an air outlet 220 are formed to form a second heat exchange space for heat exchange with the second heat exchange part 320, and form a second air flow path P2 passing through the second heat exchange part 320. ) Is formed a second housing 200,
The first heat exchange unit 310,
At least one first heat exchange plate 311 whose surface is in surface contact with the heat dissipation portion of the thermoelectric module 300;
A plurality of heat pipes 612 having one end coupled to the first heat exchange plate 311 and disposed in parallel to each other;
The plurality of heat dissipation fin members 613 are sequentially inserted into the plurality of heat pipes 612 to perform heat exchange by air flow along the first air passage P1 together with the plurality of heat pipes 612. Include,
The first heat exchange plate 311 includes a plurality of inserts in which each of the plurality of heat pipes 612 is inserted into one surface of the upper and lower surfaces of the first heat exchange plate 311 that is in close contact with the thermoelectric module 300. Grooves 611a are formed,
The insertion groove 611a is formed on one surface of the upper and lower surfaces of the first heat exchange plate 311 to be in close contact with the thermoelectric module 300 so that each of the plurality of heat pipes 612 is inserted therein.
The heat pipe 612 is,
An electric valve having a rod shape having a length and having a flat portion (612a) formed to form one surface together with one surface of the first heat exchange plate (311) in a state of being inserted into the insertion groove (611a). The method according to any one of claims 15 and 16,
It is coupled between the air inlet 210 and the outlet 11, between the air outlet 220 and the inlet 12, respectively, and the inside of the valve housing 10 together with the second air passage (P2). An electric valve comprising a pair of connecting members (21, 22) to form an air circulation passage for connecting. The method according to claim 17,
Electric valve characterized in that the cooling device is fixed to the valve housing (10) by at least one coupling belt (500) installed to surround the valve housing (10) and the cooling device. The method according to claim 18,
The coupling belt 500 is fitted to the ring portion 140 protruding outward from at least one of the first housing 100 and the second housing to fix the cooling device to the valve housing 10. Electric valve. The method according to any one of claims 15 and 16,
The second housing 200,
At least one flow path forming housing 330 for forming the second air flow path P2 such that the air sucked through the air inlet 210 flows through the second heat exchange part 320 to the air outlet 220. Electric valve, characterized in that it further comprises. delete delete delete delete The method according to claim 16,
The at least one first heat exchange plate (311), the electric valve, characterized in that one surface is in surface contact with the heat radiating portion of the thermoelectric module (300). delete delete delete

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