KR102516786B1 - Cooling Dehumidifier with Thermoelement and Heat transfer media - Google Patents

Abstract

The present invention is a cooling dehumidifier using a thermoelectric element and a heat transfer medium installed in an enclosed space, a water tank for storing a heat transfer liquid, a winter pump for circulating the heat transfer liquid in the water tank to the outside by pressure, and one end and a heat transfer liquid supply unit including a heat transfer liquid pipe having the other end connected to the water tank and through which the heat transfer liquid moves; Internal air is sucked in through the dehumidifying fan, and the sucked internal air is cooled by a thermoelectric element and a heat transfer liquid that absorbs heat from the thermoelectric element to generate condensed water and humidity-removed air. A dehumidifying unit discharging to the inside; External air is sucked in through the heat dissipation fan, and the condensed water of the dehumidifier is converted into water vapor through the dry diffuser having a plurality of flow channels formed therein, and discharged to the outside through the heat dissipation fan. a heat dissipation unit that dissipates heat through heat exchange with external air; and a cold sink configured to include a thermoelectric element closely attached to the progress pipe through which the air introduced from the first suction part proceeds, and a water jacket installed in close contact with the thermoelectric element and through which the heat transfer fluid passes through, The dehumidifying unit includes the first suction part including a suction port for sucking in air inside the switchboard and a condensed water diffuser for discharging the condensed water to the heat radiation part, and the cold sink is connected to the first suction part for the air of the progress pipe. It relates to a cooling dehumidifier using a thermoelectric element and a heat transfer medium including a vortex plate installed on an inlet surface and forming a vortex to increase air suction power.

Description

Cooling Dehumidifier with Thermoelement and Heat Transfer Media}

The present invention relates to a cooling dehumidifier using a thermoelectric element and a heat transfer medium.

A dehumidifier is an air conditioning equipment used to lower humidity by cooling indoor temperature. These dehumidifiers are mainly used in enclosed spaces where equipment vulnerable to humidity is installed.

In general, when humidity increases and becomes damp in a switchboard or distribution board that controls electricity and electronics in industrial equipment or facilities such as machinery, the surface of the distribution circuit or accumulated dust becomes wet, resulting in a short circuit or short circuit, resulting in a fire or fire. will cause a breakdown

Conventionally, in order to solve the problem in an enclosed space such as a switchboard, a device or system that functions as a dehumidifier using a thermoelectric element is installed in a switchboard. Representatively, Korean Patent Registration No. 10-1670255 (Title: water/switchboard system with dehumidification function using thermoelectric element and its control method) is disclosed.

Patent No. 1670255 blows air to the cooling surface on the cooling side of the thermoelectric element so that the water condensed on the cooling surface collects in the water tray, and when the water level in the water tray exceeds a certain level, it is discharged to the outside through the discharge pipe.

However, Patent No. 1670255 has a problem in that the configuration of the basic device is large, so it is difficult to install it in a small-sized switchboard, and when external vibration or shock occurs because the water support is installed inside the switchboard, There is a problem that acts as a risk factor.

1. Korea Patent Registration No. 10-1670255 ("Water/switchboard system with dehumidification function using thermoelectric element and its control method", registration date: 2016.10.24.)

An object to be solved by the present invention is to provide a cooling dehumidifier using a thermoelectric element and a heat transfer medium that is installed in an enclosed space to remove internal moisture and maintain safe humidity.

The technical problem to be achieved by the present embodiment is not limited to the technical problem as described above, and other technical problems can be inferred from the following embodiments.

According to an embodiment of the present invention for solving the above problems, in a cooling dehumidifier using a thermoelectric element and a heat transfer medium installed in an enclosed space, a water tank for storing a heat transfer liquid and a heat transfer liquid in the water tank are compressed by pressure. a heat transfer liquid supply unit including a winter pump for circulating to the outside and a heat transfer liquid pipe having one end and the other end connected to the water tank and through which the heat transfer liquid moves; Internal air is sucked in through the dehumidifying fan, and the sucked internal air is cooled by a thermoelectric element and a heat transfer liquid that absorbs heat from the thermoelectric element to generate condensed water and humidity-removed air. A dehumidifying unit discharging to the inside; External air is sucked in through the heat dissipation fan, and the condensed water of the dehumidifier is converted into water vapor through the dry diffuser having a plurality of flow channels formed therein, and discharged to the outside through the heat dissipation fan. a heat dissipation unit that dissipates heat through heat exchange with external air; and a cold sink configured to include a thermoelectric element closely attached to the progress pipe through which the air introduced from the first suction part proceeds, and a water jacket installed in close contact with the thermoelectric element and through which the heat transfer fluid passes through, The dehumidifying unit includes the first suction part including a suction port for sucking in air inside the switchboard and a condensed water diffuser for discharging the condensed water to the heat radiation part, and the cold sink is connected to the first suction part for the air of the progress pipe. Provided is a cooling dehumidifier using a thermoelectric element and a heat transfer medium including a vortex plate installed on an inlet surface and forming a vortex to increase air suction power.

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According to an embodiment of the present invention, the present invention removes moisture inside an enclosed space through a dehumidifying function to maintain the internal humidity at a low humidity, and dissipates and evaporates condensed water generated in the dehumidifying unit through a heat radiation unit to discharge it to the outside. By doing so, the conventional problems are solved.

1 is a schematic configuration diagram of a cooling dehumidifier for a switchboard according to an embodiment of the present invention.
2 is a view showing a state in which suction/discharge ports of a dehumidifying unit and a heat dissipating unit are installed in a cooling dehumidifier for a switchboard according to an embodiment of the present invention.
3 is a view showing a state in which a cooling dehumidifier for a switchboard according to a first embodiment of the present invention is installed in a switchboard.
4 is a view showing a state in which a cooling dehumidifier for a switchboard according to a second embodiment of the present invention is installed in a switchboard.
5 is a perspective view of a dehumidifier in a cooling dehumidifier for a switchboard according to an embodiment of the present invention.
6 is a perspective view of a heat dissipation unit and a heat transfer liquid supply unit in a cooling dehumidifier for a switchboard according to an embodiment of the present invention.
7 is a rear perspective view of a cooling dehumidifier for a switchboard according to an embodiment of the present invention.
8 is a rear perspective view of a cooling dehumidifier for a switchboard according to an embodiment of the present invention.
9 is a view showing the main configuration of a cold sink according to an embodiment of the present invention.

In the following, several embodiments will be described clearly and in detail with reference to the accompanying drawings so that those skilled in the art (hereinafter, those skilled in the art) can easily practice the present invention. will be. Also, the term "unit" used in the specification may mean a hardware component or circuit.

Hereinafter, an IoT device operating as a VPN server and a security method thereof according to an embodiment of the present invention will be described with reference to the accompanying drawings.

1 is a schematic configuration diagram of a cooling dehumidifier for a switchboard according to an embodiment of the present invention. Referring to FIG. 1 , a cooling dehumidifier 100 for a switchboard according to an embodiment of the present invention includes a dehumidifier 110 , a heat dissipation unit 120 and a heat transfer liquid supply unit 130 .

The dehumidifying unit 110 sucks air inside the switchboard and uses the heat transfer liquid supplied from the heat transfer liquid supply unit 130 to convert the water vapor contained in the air into water droplets, that is, condensed water. The humid air is discharged into the switchboard. At this time, the dehumidifier 110 cools the water vapor using a thermoelectric element to make water vapor in the air into condensed water, and the heat transfer liquid absorbs and heats the heat deprived for internal cooling.

The heat transfer fluid functions as a cooling water.

The heat dissipation unit 120 introduces the cooling water that has absorbed heat and the condensation water generated by the dehumidifying unit 110, dissipates the cooling water that has absorbed heat to make it normal temperature cooling water, and evaporates the introduced condensation water to the outside. emit with

The heat transfer liquid supply unit 130 supplies the stored heat transfer liquid at a certain temperature to the dehumidifying unit 110 through a pumping operation, passes through the dehumidifying unit 110, and collects and stores the heat transfer liquid dissipated from the heat dissipating unit 120. .

Hereinafter, referring to FIG. 2 , the installation state of intake/outlet ports in the cooling dehumidifier for switchboard according to an embodiment of the present invention will be described.

2 is a view showing a state in which suction/discharge ports of a dehumidifying unit and a heat dissipating unit are installed in a cooling dehumidifier for a switchboard according to an embodiment of the present invention.

Referring to (a) of FIG. 2 , in the cooling dehumidifier 100 for a switchboard according to an embodiment of the present invention, the first suction part 111 of the dehumidifying part 110 is formed on the box-shaped rear surface of the hexahedron (opposite side of the front surface). ) is installed to be partially exposed to the outside, and the first discharge unit 112 of the dehumidifying unit 110 is installed to be partially exposed to the outside. That is, the inlet of the first inlet 111 and the outlet of the first outlet 112 are installed to be exposed to the outside. Accordingly, the air sucked in from the first suction part 111 proceeds through the internal air passage and is discharged to the first discharge part 112 .

And referring to FIG. 2 (b), the cooling dehumidifier 100 for a switchboard according to an embodiment of the present invention is configured in the shape of a hexahedron box, and the second suction part of the heat dissipation part 120 on the front surface of the box shape ( 121) is installed to be partially exposed to the outside, and the second discharge part 122 of the heat dissipation unit 120 is installed to be partially exposed to the outside. That is, the inlet of the second inlet 121 and the outlet of the second outlet 122 are installed to be exposed to the outside. Accordingly, the air sucked from the second suction part 121 proceeds through the internal air passage and is discharged to the second discharge part 122 .

The second suction part 121 is formed in the cabinet 10 (see FIG. 3).

Hereinafter, a state in which the cooling dehumidifier for a switchboard according to the first and second embodiments of the present invention is installed in the switchboard will be described with reference to FIGS. 3 and 4 .

3 is a view showing a state in which a cooling dehumidifier for a switchboard according to a first embodiment of the present invention is installed in a switchboard. Referring to FIG. 3 , the cooling dehumidifier 100 for a switchboard may be installed so that one side of the cabinet 10 of the switchboard is attached to one side where the inlet and outlet of the dehumidifying unit 110 are installed so as to protrude to the outside.

Accordingly, in the dehumidifying unit 110 of the cooling dehumidifier 100 for a switchboard, as shown in (a) of FIG. (10) Head inside. And, as shown in (b) of FIG. 3, the heat dissipation part 120 of the cooling dehumidifier 100 for the switchboard has a suction inlet of the second intake part 121 and an outlet of the second discharge part 122 in the cabinet 10 ) to the outside.

In the description with reference to FIG. 3 , the dehumidifier 100 has been illustrated and described as being installed on the door of the cabinet, but may be installed on the side or upper side of the cabinet.

4 is a view showing a state in which a cooling dehumidifier for a switchboard according to a second embodiment of the present invention is installed in a switchboard. Referring to FIG. 4 , the cooling dehumidifier 100 for the switchboard may be installed so that one side of the cabinet 10 of the switchboard is attached to one side of the cabinet 10 where the inlet and outlet of the heat dissipation unit 120 are installed so as to protrude into the cabinet 10. .

Accordingly, as shown in (a) and (b) of FIG. 4 , the dehumidifying part 110 of the cooling dehumidifier 100 for the switchboard is composed of the suction port of the first suction part 111 and the first discharge part 112. The discharge port faces the inside of the cabinet 10, and the heat dissipation part 120 of the cooling dehumidifier 100 for a switchboard faces the outside of the cabinet 10 through the intake hole of the second suction part 121 and the discharge hole of the second discharge part 122. Headed.

In the description with reference to FIG. 4, the dehumidifier 100 has been illustrated and described as being installed on the door of the cabinet, but may be installed on the side or upper side of the cabinet.

On the other hand, according to another embodiment of the present invention, in the cooling dehumidifier 100 for switchboard, one surface on which the inlet and outlet of the dehumidifier 110 are installed protrudes into the inside of the cabinet 10, and the inlet of the heat radiation unit 120 protrudes. And the other surface on which the discharge unit is installed may protrude out of the cabinet 10 .

Hereinafter, the cooling dehumidifier 100 for a switchboard according to an embodiment of the present invention will be described in detail with reference to FIGS. 5 to 9 .

5 is a perspective view of a dehumidifier in a cooling dehumidifier for a switchboard according to an embodiment of the present invention. Referring to FIG. 5 , the dehumidification unit 110 of the cooling dehumidifier 100 for a switchboard according to an embodiment of the present invention includes a first suction unit 111 with a suction port, a first discharge unit 112 with an outlet, and 1 includes a cold sink 113 connected between the suction part 111 and the first discharge part 112.

The first suction part 111 is connected to one end of the cold sink 113, the first discharge part 112 is connected to the other end of the cold sink 113, and the first suction part 111 and the cold sink 113 ) and the first discharge unit 112 are formed with air passages penetrating each other. Accordingly, the air sucked in through the first suction part 111 passes through the cold sink 113 and is discharged through the first discharge part 112 .

The first inlet 111 has a suction port and has an inlet pipe 111a through which the introduced air moves, and the condensation water generated in the swirl plate 113b and the progress pipe 113a installed below the inlet pipe 111a It includes a condensed water diffuser 111b that moves the lower part. The condensed water diffuser 111b is installed below the swirl plate 113b and is inclined downward so that the condensed water falls.

The first discharge unit 112 includes a discharge pipe 112a having a discharge port and moving the discharged air, and a dehumidifying fan 112b installed in the discharge port to discharge the air of the discharge pipe 112a to the outside.

Further, the cold sink 113 includes a progress pipe 113a, a vortex plate 113b, a plurality of thermoelectric elements 113c, and a plurality of water jackets 113d.

The progress pipe 113a has one end connected to the inlet pipe 111a and the other end connected to the discharge pipe 112a, so that the air introduced from the inlet pipe 111a moves to the discharge pipe 112a. It is preferable that the progress pipe 113a is made of a heat insulating material in order to maintain a constant internal temperature.

The vortex plate 113b is installed on the air inlet surface of the progress pipe 113a connected to the inlet pipe 111a, has a grid pattern, that is, a form in which a plurality of slits are formed, and forms a vortex to increase air suction power. .

A plurality of thermoelectric elements 113c are installed so as to come into contact with one side and the other side of the progress tube 113a. Also, each of the plurality of water jackets 113d is installed to come into contact with one thermoelectric element 113c.

Here, with reference to FIG. 9 , a state in which the main components of the cold sink 113 are mounted between the progress pipe 113a, the thermoelectric element 113c, and the water jacket 113d will be described. 9 is a view showing the main configuration of a cold sink according to an embodiment of the present invention.

The cold sink 113 is installed so that at least one thermoelectric element 113c is in contact with one surface of the progress pipe 113a, and one water jacket 113d is in contact with the surface of one thermoelectric element 113c. . In addition, the cold sink 113 is installed so that at least one thermoelectric element 113c is in contact with the other surface of the progress pipe 113a, and one water jacket 113d is in contact with the surface of one thermoelectric element 113c. do.

Here, the water jacket 113d may be fastened with the thermoelectric element 113c by bolting or screwing, but since the thermoelectric element 113c may be damaged when bolts or screws are fastened, the water jacket 113d is fastened as if wrapping the thermoelectric element 113c. do. In addition, the water jacket fixing plate 113f presses and fixes the water jacket 113d from the top so that the thermoelectric element 113c can be stably fastened to the progress pipe 113a.

In addition, the heat transfer fluid supplied from the heat transfer fluid supply unit 130 flows through the inside of the water jacket 113d, and the heat transfer fluid flowing through the water jacket 113d has a lower temperature than the air flowing through the progress pipe 113a. . Accordingly, the water jacket 113d serves as a cooling body for the advancing pipe 113a.

Referring to the heat transfer operation of the cold sink 113 configured as described above, the thermoelectric element 113c in contact with the progress tube 113a absorbs heat from the progress tube 113a to cool the progress tube 113a. The heat absorbed from 113a is transferred to the water jacket 113d.

When the water jacket 113d receives heat from the thermoelectric element 113c, it is heated by absorbing heat from the heat transfer liquid flowing through the water jacket 113d, and the heated heat transfer liquid is provided to the heat dissipation unit 120.

Meanwhile, according to an embodiment of the present invention, as shown in (b) of FIG. 9 , the cold sink 113 to which the heat transfer plate 113e is added may be configured. Here, since the heat transfer plate 113e can easily damage or shorten its lifespan when the thermoelectric element 113c directly contacts and attaches to the surface of the progress tube 113a, the progress tube ( 113a) allows the heat to diffuse and transfer evenly.

Looking at the configuration of the cold sink 113 according to this, in the cold sink 113, a heat transfer plate 113e is installed in close contact with one surface of the progress pipe 113a, and at least one thermoelectric element is installed on the surface of the heat transfer plate 113e. (113c) is installed to contact, and one water jacket (113d) is installed to contact the surface of one thermoelectric element (113c). In addition, in the cold sink 113, a heat transfer plate 113e is installed in close contact with the other surface of the progress pipe 113a, and at least one thermoelectric element 113c is installed in contact with the surface of the heat transfer plate 113e. One water jacket 113d is installed to contact the surface of the thermoelectric element 113c.

Meanwhile, in the description with reference to FIG. 9, it has been described that the thermoelectric element 113c is installed on two surfaces of the progress tube 113a, but the thermoelectric element 112c is installed on one or two or more surfaces of the progress tube 113a. can be installed.

Hereinafter, an operation of the dehumidifying unit 110 will be briefly described.

While the dehumidifying part fan 112b is operating, the air in the switchboard is introduced into the suction port of the first suction part 111 . The air sucked into the inlet passes through the vortex plate 113b and proceeds to the progress pipe 113a.

Since the vortex plate 113b and the progress pipe 113a are cooled by the thermoelectric element 113c and the water jacket 113d, the moisture (moisture) of the air sucked into the intake is condensed on the vortex plate 113b, It is condensed inside the progress pipe 113a and becomes condensed water.

The condensed water thus generated falls to the condensed water diffuser 111b, and the condensed water diffuser 111b supplies the condensed water to the heat dissipation unit 120 through an inclined plate.

On the other hand, the air from which moisture has been removed is discharged to the outside, that is, to the inside of the switchboard, through the dehumidifier fan 112b after going to the discharge pipe 112a through the progress pipe 113a.

Hereinafter, the heat dissipation unit 120 in the cooling dehumidifier for a switchboard according to an embodiment of the present invention will be described with reference to FIG. 6 . 6 is a perspective view of a heat dissipation unit and a heat transfer liquid supply unit in a cooling dehumidifier for a switchboard according to an embodiment of the present invention.

Referring to FIG. 6 , the heat dissipation unit 120 of the cooling dehumidifier 100 for a switchboard according to an embodiment of the present invention includes a second discharge unit 122, a diffuse connection tube 123, and a dry diffuse fuse. (124) and a radiator (125).

The second discharge unit 122 is composed of a heat dissipation fan 122a with a radiator 125 installed on the front side, and the heat dissipation fan 122a supplies air outside the switchboard to the radiator 125 and the air around the heat dissipation unit 120. discharge to the outside.

The diffuse connection container 123 is located at the lower end of the condensed water diffuser 111b and is connected to the condensed water diffuser 111b, and temporarily stores the condensed water supplied through the condensed water diffuser 111b.

The dry diffuser 124 has a plurality of passages through which condensed water can move therein to increase heat dissipation efficiency. The dry diffuse 124 is connected to the diffuse connection tube 123 and allows the condensed water stored in the diffuse connection tube 123 to flow through a plurality of internal channels, and the condensed water flowing through the plurality of channels is evaporated by the outside air. and make it into steam. The water vapor generated by the dry diffuse 124 is discharged to the outside of the switchboard by the heat dissipation fan 122a of the second discharge unit 122.

The radiator 125 dissipates heat by exposing the heat transfer liquid to external air so that the heat transfer liquid exchanges heat with the external air.

Next, the heat transfer liquid supply unit 130 includes a water tank 131 , a water pump 132 and a heat transfer liquid pipe 133 .

The water tank 131 is a container for storing the heat transfer liquid, and the water pump 132 is a device for circulating the heat transfer liquid stored in the water tank 131 to the outside by pressure. The heat transfer fluid pipe 133 is a pipe through which the heat transfer fluid moves, and one end and the other end are connected to the water tank 131 and are installed to pass through the water jacket 113d and the radiator 125 .

Referring to the operation of the heat dissipation unit 120 configured as described above, the condensation water generated in the dehumidification unit 110 is collected in the diffuse connection tube 123 of the heat dissipation unit 120 through the condensed water diffuser 111b, and the diffuse The condensed water in the connecting tube 123 flows into the internal flow path of the dry diffuse 124. At this time, the condensed water flowing through the internal passage is dried by the external air supplied by the heat dissipating fan 122a and turned into water vapor, and the water vapor is discharged to the outside through the heat dissipating fan 122a.

Therefore, unlike the prior art, the dew condensation water generated in the dehumidifying unit 110 of the present invention is not stored inside the switchboard, but is immediately converted into water vapor and discharged to the outside.

7 and 8 are perspective views of a cooling dehumidifier for a switchboard according to an embodiment of the present invention, in which the dehumidifying unit 110 shown in FIG. 5, the heat dissipation unit 120 and the heat transfer fluid supply unit 130 shown in FIG. It is a perspective view shown in a combined state.

Overall operations of the cooling dehumidifier for a switchboard according to an embodiment of the present invention will be described with reference to FIGS. 7 and 8 . When power is supplied, the water pump 132, the dehumidifier fan 112b, and the heat dissipation fan 122a operate.

By the operation of the water pump 132, the heat transfer liquid stored in the water tank 131 is supplied to the water jacket 113d of the dehumidifier 110. The heat transfer fluid supplied to the water jacket 113d is heated by absorbing the heat of the thermoelectric element 113c, and the heated heat transfer fluid is supplied to the radiator 125 of the heat dissipation unit 120 and then the outside air of the radiator 125. It is cooled to a normal temperature through heat exchange with the water tank 131 again.

In addition, by the operation of the dehumidifying fan 112b, the air in the switchboard is introduced into the first suction part 111 of the dehumidifying part 110, and the introduced air meets the low-temperature swirl plate 113b and contains moisture This is primarily generated as condensed water, and is secondarily generated as condensed water in the advancing pipe 113a cooled by the thermoelectric element 113c.

The condensed water generated by the swirl plate 113b and the advancing pipe 113a falls by gravity and is collected in the condensed water diffuser 111b, and the condensed water of the condensed water diffuser 111b proceeds along an inclined direction to dissipate heat. It is provided in the diffuse connection tube 123 of the unit 120.

The condensed water supplied to the diffuse connection pipe 123 proceeds to a plurality of passages formed inside the dry diffuse 124, and is vaporized and changed into water vapor during the process. Then, the water vapor is discharged to the outside of the switchboard by the heat dissipation fan 122a.

The above descriptions are intended to provide exemplary configurations and acts for implementing the present invention. The technical idea of the present invention will include not only the above-described embodiments, but also implementations that can be obtained by simply changing or modifying the above embodiments. In addition, the technical idea of the present invention will also include implementations that can be achieved by easily changing or modifying the embodiments described above in the future.

110: dehumidifying unit 111: first suction unit
111a: inlet pipe 111b: condensation water diffuser
112: first discharge unit 112a: discharge pipe
112b: dehumidifying fan 113: cold sink
113a: Progress pipe 113b: Vortex plate
113c: thermoelectric element 113d: water jacket
113e: heat transfer plate 113f: water jacket fixing plate
120: heat dissipation unit 121: second intake unit
122: second discharge unit 123: diffuse connection tube
124: dry diffuse 125: radiator
122a: heat dissipation fan 130: heat transfer liquid supply unit
131: water tank 132: water pump
133: heat transfer liquid pipe

Claims (6)

In a cooling dehumidifier using a thermoelectric element and a heat transfer medium installed in an enclosed space,
A water tank 131 that stores the heat transfer fluid, a winter pump 132 that circulates the heat transfer fluid in the water tank 131 to the outside by pressure, and one end and the other end are connected to the water tank 131 and a heat transfer liquid supply unit 130 including a heat transfer liquid pipe 133 through which the heat transfer liquid moves;
The internal air is sucked in through the dehumidifying fan 112b, and the sucked internal air is cooled by the thermoelectric element 113c and the heat transfer fluid that absorbs heat from the thermoelectric element 113c. a dehumidifying unit 110 generating humidity-removed air and discharging the humidity-removed air to the inside;
External air is sucked in through the heat-dissipating fan 122a, and the condensed water of the dehumidifying unit 110 is converted into water vapor through the dry diffuse 124 having a plurality of flow paths formed therein, and is discharged to the outside through the heat-dissipating fan 122a. a heat dissipation unit 120 that discharges and dissipates heat by exchanging heat with external air through a radiator 125 from the heat transfer liquid that has absorbed the heat; and
A thermoelectric element 113c closely attached to the propagation tube 113a through which the air introduced from the first suction part 111 proceeds and a water jacket installed in close contact with the thermoelectric element 113c and through which the heat transfer liquid penetrates the inside It includes a cold sink 113 configured to include (113d),
The dehumidifying part 110 includes the first suction part 111 including a suction port for sucking air inside the switchboard and a condensed water diffuser 111b for discharging the condensed water to the heat dissipating part 120,
The cold sink 113 is installed on the air inlet surface of the progress pipe 113a connected to the first suction part 111 and includes a thermoelectric element including a vortex plate 113b to increase air suction power by forming a vortex, Cooling dehumidifier using heat transfer medium. According to claim 1,
The dehumidifying unit 110,
A cooling dehumidifier using a thermoelectric element and a heat transfer medium including a first discharge part 112 in which the dehumidifying fan 112b is installed inside the discharge port to discharge the dehumidified air. According to claim 1,
The cold sink 113 is installed so that at least one thermoelectric element 113c is in contact with one surface of the progress pipe 113a, and one water jacket 113d is in contact with the surface of one thermoelectric element 113c. At least one thermoelectric element 113c is installed to contact the other surface of the progress tube 113a, and one water jacket 113d is installed to contact the surface of the thermoelectric element 113c. and a cooling dehumidifier using a heat transfer medium. delete According to claim 3,
The heat dissipation part 120,
a second discharge unit 122 including a heat dissipation fan 122a;
A diffuse connection container 123 for temporarily storing the condensed water supplied through the condensed water diffuser 111b;
It has a plurality of passages through which condensed water can move inside, and the condensed water flowing in through the diffuse connection pipe 123 is moved through a plurality of passages formed inside, and the condensed water is evaporated by external air to make water vapor, thereby dissipating the heat. a dry diffuser 124 that is discharged to the outside through a fan 122a; and
Heat transfer with a thermoelectric element including a radiator 125 exchanging heat with the external air supplied by the heat dissipation fan 122a and supplying the heat exchanged heat transfer liquid to the heat transfer liquid supply unit. Cooling dehumidifier using medium. According to claim 3,
The cold sink 113 is a thermoelectric element that further includes a heat transfer plate 113e positioned between the progress tube 113a and the thermoelectric element 113c to evenly diffuse and transfer the heat of the progress tube 113a. and a cooling dehumidifier using a heat transfer medium.

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