KR101185261B1 - Hybrid distributing board and motor control board having heat pipe connection structure for reducing temperature - Google Patents

Abstract

PURPOSE: A hybrid distribution board including a heat pipe connection structure is provided to increase a lifetime of an internal device by decreasing heat generated from an internal device. CONSTITUTION: A transformation device(100) is formed in a transformation device enclosure and supplies high voltage power to an external device. A heat pipe is contacted with the transformation device and absorbs heat from the transformation device. One side of the heat pipe is connected to a boiler inlet or a water and sewage pipe(410).

Description

HYBRID DISTRIBUTING BOARD AND MOTOR CONTROL BOARD HAVING HEAT PIPE CONNECTION STRUCTURE FOR REDUCING TEMPERATURE}

The present invention relates to a hybrid switchgear having a heat pipe connection structure for reducing the temperature, more specifically, it is possible to extend the life of the device inside the switchgear and motor control panel by lowering the heat of the high temperature generated from the device inside the switchboard itself. The present invention relates to a hybrid switchgear having a heat pipe connection structure for reducing temperature for saving energy.

Until now, the switchgear has a door open to dissipate internal heat, and heat is released by convection, or it is forced to circulate through an exhaust pen to release heat.In the case of severe heat generation, the switchboard is operated with a large fan. It also lowers the internal temperature.

In this case, inflow of foreign matters such as dust and rats, pests, etc. due to the open operation of the switchboard may cause accidents.

In order to solve this problem, there is a prior art for controlling the temperature and humidity by the air circulation method, but this technique is only an effect of only one switchgear, and the function of increasing the room temperature of the substation room or switchboard room is rather expensive to maintain and operate. There is a lifting issue.

Accordingly, in the relevant technical field, there is a demand for a technology development for maintaining a high temperature of the room so as not to lower the high temperature heat generated from the internal device of the switchboard itself.

[Related Technical Literature]

1. A control device of temperature and humidity for distributing board (Patent Application No. 10-2007-0099729)

2. Equipped with humidity control indoor outdoor switchgear (patent application No. 10-2011-0071433)

3. Distribution board mounted with air-cooling passage (Patent Application No. 10-2010-0049308)

The present invention is to solve the above problems, it is possible to extend the life of the internal device of the switchgear and the motor control panel by lowering the heat of the high temperature generated from the internal device of the switchgear, a hybrid switchgear for saving energy And a heat pipe connection structure for the motor control panel.

However, the objects of the present invention are not limited to the above-mentioned objects, and other objects not mentioned can be clearly understood by those skilled in the art from the following description.

Hybrid switchgear having a heat pipe connection structure for reducing the temperature according to an embodiment of the present invention to achieve the above object, the switchgear main body including a housing formed between the upper panel and the lower panel; A transformer unit formed inside the transformer unit enclosure to supply high voltage power to an external device; And a heat pipe contacting the transformer and absorbing heat generated from the transformer by filling a heat transfer nanomaterial therein. One side of the heat pipe is connected to any one of the boiler inlet pipe and water and sewage pipe; In the hybrid switchgear having a heat pipe connection structure for reducing the temperature comprising: The heat pipe, the contact pipe in contact with the transformer; A cooling tube surrounding a lower portion of the contact tube, the one end of which has a structure in contact with an inner surface of the main switchboard body; And a central insertion tube inserted into the transformer unit housing by branching the contact tube. And a control unit.

In a hybrid switchgear having a heat pipe connection structure for reducing temperature according to another embodiment of the present invention, the upper panel is formed in a plate shape having a length and a thickness longer than that of the housing, and thus, the heat exchanger may exchange heat with external air. It is formed of a heat dissipation plate for dissipating the air inside the main body of the switchgear, the lower panel is formed in a rectangular plate shape having a length and thickness longer than the housing, the air inside the main switchgear through heat exchange with the lower surface Characterized in that the heat dissipation plate to be radiated.

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The hybrid switchgear having a heat pipe connection structure for reducing the temperature according to another embodiment of the present invention is a gas sensor which is formed inside the housing and detects that the internal equipment is burned by a short circuit and a short circuit to generate gas, and Gas / including a temperature sensor formed inside the housing to measure the internal temperature to generate the measurement data, and a wireless transmission and reception unit for transmitting the measurement data for the warning data or temperature according to the gas generation to the smartphone through wireless transmission and reception Temperature measuring unit; Heat pipe connection structure for a hybrid switchgear characterized in that it further comprises.

In the hybrid switchgear having a heat pipe connection structure for reducing the temperature according to another embodiment of the present invention, the heat pipe, when the contact pipe is formed to extend to the point where the upper panel is the top end of the contact pipe An upper insertion tube which is formed by folding and being inserted into the upper panel; Further comprising:

In the hybrid switchgear having a heat pipe connection structure for reducing the temperature according to another embodiment of the present invention, the heat pipe is extended from the lower end of the contact tube in the inside of the cold pipe is bent to the lower end inserted into the lower panel Lower insertion tube formed of a structure; Further comprising:

In a hybrid switchgear having a heat pipe connection structure for reducing temperature according to another embodiment of the present invention, the cold pipe diameter (B) and the diameter (A) of the contact tube are formed at a ratio of 1.3 to 1.5: 1. It is characterized by.

Hybrid switchgear having a heat pipe connection structure for reducing the temperature according to another embodiment of the present invention, the contact tube, the central insertion tube, the upper insertion tube, the lower insertion tube is formed of a copper tube, the cold pipe Silver, characterized in that formed of a PE pipe or PVC pipe.

Heat pipe connection structure for a hybrid switchgear according to an embodiment of the present invention, it is possible to extend the life of the switchgear internal devices by reducing the heat of the high temperature generated from the device inside the switchgear itself, it is possible to save energy to provide.

In addition, the heat pipe connection structure for the hybrid switchgear according to another embodiment of the present invention, as well as the effect of increasing the temperature of the boiler inlet water installed in the vicinity or indirectly prevent the freezing of the water pipe or sewage pipe in winter, the equipment life of the switchgear It is possible to extend the power supply and provide a triple effect that also saves the energy required for cooling due to the rise of the equipment heat.

1 is a view showing a hybrid switchgear having a heat pipe connection structure for temperature reduction according to a first embodiment of the present invention.
FIG. 2 is a diagram for describing a heat pipe connection structure of FIG. 1.
3 is a view showing a hybrid switchgear having a heat pipe connection structure for temperature reduction according to a second embodiment of the present invention.
4 is a view for explaining the heat pipe connection structure of FIG.
5 is a view showing a hybrid switchgear having a heat pipe connection structure for temperature reduction according to a third embodiment of the present invention.
FIG. 6 is a diagram for describing a heat pipe connection structure of FIG. 5.
7 is a flow chart for radiating heat through the boiler inlet pipe and the water and sewage pipe.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a detailed description of preferred embodiments of the present invention will be given with reference to the accompanying drawings. In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

In the present specification, when any one element 'transmits' data or signals to another element, the element can transmit the data or signal directly to the other element, and through at least one other element Data or signal can be transmitted to another component.

 1 is a view showing a hybrid switchgear having a heat pipe connection structure for temperature reduction according to a first embodiment of the present invention. FIG. 2 is a diagram for describing a heat pipe connection structure of FIG. 1. 1 and 2, a hybrid switchgear having a heat pipe connection structure for reducing temperature according to the first embodiment includes a switchgear main body 10, a transformer unit 100, a heat pipe 200, and a gas / temperature measuring unit. 300.

The switchboard main body 10 has a rectangular housing 12 formed between the upper panel 11 and the lower panel 13.

The upper panel 11 is formed of a heat dissipation plate that is formed in a rectangular plate shape having a length and a thickness longer than that of the housing 12 for heat dissipation so that the air inside the switchboard main body 10 is dissipated through heat exchange with external air. do.

Like the upper panel 11, the lower panel 13 is also formed in a rectangular plate shape having a length and a thickness longer than that of the housing 12 for heat dissipation, so that the air inside the switchboard main body 10 through heat exchange with the lower surface. It is formed of a heat dissipation plate to allow the heat dissipation.

The transformer unit 100 is installed in the hybrid switchgear to supply high voltage power to an external device. The transformer 100 is directly contacted on the vertical surface of the heat pipe 200, as shown in Figure 1, the upper end of the heat pipe 200 is formed in a structure inserted into the transformer facility enclosure 110.

The heat pipe 200 includes a cold tube 210, a contact tube 220, and a central insertion tube 230. The cooling tube 210 surrounds the lower portion of the contact tube 220, and has one structure in which one end thereof contacts the inner surface of the main body of the switchgear 10.

On the other hand, the contact tube 220 and the central insertion tube 230 is made of a copper tube made of a high heat transfer material, the insulated tube 210 is inserted into the lower portion of the contact tube 220 does not leak heat or cold to the outside. It is made of low heat transfer PE pipe or PVC pipe.

Since the heat transfer nanomaterial is filled in the contact tube 220 and the central insertion tube 230, the temperature of one side rapidly moves to the other side.

The cooling tube 210 surrounds the outer circumference of the contact tube 220, and a coolant may be inserted between the contact tube 220 and the cold tube 210. The coolant is provided to prevent heat or cold inside the contact tube 220 from flowing out.

The contact tube 220 and the transformer unit 100 is in contact with each other to absorb the heat of the transformer unit 100 to lower the temperature, the central insertion tube 230 in the transformer unit 110 inside the transformer unit at the insertion portion By absorbing the heat, serves to lower the temperature inside the transformer installation (100). Meanwhile, a heat dissipation fan 500 may be additionally formed between the cooling tube 210 and the housing 12, thereby dissipating heat absorbed from the partially exposed contact tube 220 to the outside.

In Figure 2 is formed between the diameter (B) of the cooling tube 210 and the diameter (A) of the contact tube 220 in a ratio of 1.3 to 1.5: 1.

The gas / temperature measuring unit 300 includes a gas sensor 310, a temperature sensor 320, and a wireless transmitter / receiver 330. The gas sensor 310 is formed inside the hybrid switchgear to detect that the internal equipment is burned by a short circuit and a short circuit to generate gas.

The temperature sensor 320 is formed inside the hybrid switchgear to measure the temperature therein to generate measurement data.

The wireless transmitter / receiver 330 transmits the warning data or the measurement data for the temperature according to the gas generation to the smartphone through wireless transmission and reception such as Zigbee, Bluetooth, WLAN. On the other hand, the smart phone is a terminal possessed by the operator who manages the hybrid switchgear, it is formed for prompt measures for accidents by receiving real-time warning data and measurement data for temperature.

3 is a view showing a hybrid switchgear having a heat pipe connection structure for temperature reduction according to a second embodiment of the present invention. 4 is a view for explaining the heat pipe connection structure of FIG. 3 and 4, the hybrid switchgear having a heat pipe connection structure for temperature reduction according to the second embodiment includes a switchgear main body 10, a transformer unit 100, a heat pipe 200, and a gas / temperature measuring unit. 300.

The upper panel 11 is formed of a heat dissipation plate that is formed in a rectangular plate shape having a length and a thickness longer than that of the housing 12 for heat dissipation so that the air inside the switchboard main body 10 is dissipated through heat exchange with external air. The upper insertion tube 240 in the heat pipe 200 is formed to be inserted.

Like the upper panel 11, the lower panel 13 is also formed in a rectangular plate shape having a length and a thickness longer than that of the housing 12 for heat dissipation, so that the air inside the switchboard main body 10 through heat exchange with the lower surface. It is formed of a heat dissipation plate to allow the heat dissipation.

The transformer unit 100 is installed in the hybrid switchgear to supply high voltage power to an external device. The transformer 100 is directly in contact with the vertical surface of the heat pipe 200, as shown in Figure 3, the upper end of the heat pipe 200 is formed in a structure inserted into the transformer facility enclosure 110.

The heat pipe 200 includes a cooling tube 210, a contact tube 220, a central insertion tube 230, and an upper insertion tube 240. The cooling tube 210 surrounds the lower portion of the contact tube 220, and has one structure in which one end thereof contacts the inner surface of the main body of the switchgear 10.

On the other hand, the contact tube 220, the central insertion tube 230, and the upper insertion tube 240 is made of a copper tube made of a high heat transfer material, etc., the cooling tube 210 is inserted into the lower portion of the contact tube 220 It consists of a low heat transfer PE pipe or PVC pipe to prevent heat or cold air from leaking to the outside.

The heat transfer nanomaterial is filled in the contact tube 220, the central insertion tube 230, and the upper insertion tube 240, thereby quickly moving the temperature of one side to the other side.

The cooling tube 210 surrounds the outer circumference of the contact tube 220, and a coolant may be inserted between the contact tube 220 and the cold tube 210. The coolant is provided to prevent heat or cold inside the contact tube 220 from flowing out.

The contact tube 220 and the transformer unit 100 is in contact with the heat absorbing heat of the transformer unit 100 so that the heat dissipation, the central insertion tube 230 is the insertion unit for the transformer unit 110 to the inside By absorbing heat, serves to lower the temperature inside the transformer installation (100). Meanwhile, a heat dissipation fan 500 may be additionally formed between the cooling tube 210 and the housing 12, thereby dissipating heat absorbed from the partially exposed contact tube 220 to the outside.

In Figure 2 is formed between the diameter (B) of the cooling tube 210 and the diameter (A) of the contact tube 220 in a ratio of 1.3 to 1.5: 1.

When the upper insertion tube 240 extends from the contact tube 220 to the point where the upper panel 11 is located, the upper end of the contact tube 220 is bent to be inserted into the upper panel 11.

The upper insertion tube 240 absorbs heat to the inside of the upper panel 11 at the insertion portion into the upper panel 11, thereby lowering the temperature of the transformer installation 100.

Since the gas / temperature measuring unit 300 is configured and functions in the same manner as in FIG. 1, description thereof will be omitted.

 5 is a view showing a hybrid switchgear having a heat pipe connection structure for temperature reduction according to a third embodiment of the present invention. FIG. 6 is a diagram for describing a heat pipe connection structure of FIG. 5. 5 and 6, a hybrid switchgear having a heat pipe connection structure for reducing temperature according to a third embodiment includes a switchgear main body 10, a transformer facility 100, a heat pipe 200, and a gas / temperature measuring unit. 300.

The upper panel 11 is formed of a heat dissipation plate that is formed in a rectangular plate shape having a length and a thickness longer than that of the housing 12 for heat dissipation so that the air inside the switchboard main body 10 is dissipated through heat exchange with external air. The upper insertion tube 240 in the heat pipe 200 is formed to be inserted.

The lower panel 13 is also formed in a rectangular plate shape having a length and a thickness longer than that of the housing 12 in the same manner as the upper panel 11 for heat dissipation, so that the air inside the switchboard main body 10 through heat exchange with the lower surface. Is formed as a heat dissipation plate to dissipate heat, and the lower insertion tube 250 is formed in the heat pipe 200 is inserted.

The transformer unit 100 is installed in the hybrid switchgear to supply high voltage power to an external device. The transformer 100 is directly in contact with the vertical surface of the heat pipe 200, as shown in Figure 3, the upper end of the heat pipe 200 is formed in a structure inserted into the transformer facility enclosure 110.

The heat pipe 200 includes a cold pipe 210, a contact tube 220, a central insertion tube 230, an upper insertion tube 240, and a lower insertion tube 250. The cooling tube 210 surrounds the lower portion of the contact tube 220 and the upper portion of the lower insertion tube 250, and has one structure in which one end thereof contacts the inner surface of the main body of the switchboard 10.

On the other hand, the contact tube 220, the central insertion tube 230, the upper insertion tube 240, and the lower insertion tube 250 is made of a copper tube made of a high heat transfer material, etc., the cooling tube 210 is a contact tube ( Inserted into the lower portion of the 220) is made of a low heat transfer PE pipe or PVC pipe and the like so that heat or cold air does not flow out.

The contact tube 220, the center insertion tube 230, the upper insertion tube 240, the lower insertion tube 250 is filled with heat transfer nanomaterials to serve to quickly move the temperature of one side to the other side.

The cooling tube 210 surrounds the outer circumference of the contact tube 220, and a coolant may be inserted between the contact tube 220 and the cold tube 210. The coolant is provided to prevent heat or cold inside the contact tube 220 from flowing out.

The contact tube 220 and the transformer unit 100 is in contact with each other to absorb the heat of the transformer unit 100 to lower the internal temperature, the central insertion tube 230 in the transformer unit 110 inside the transformer unit at the insertion portion By absorbing the heat, serves to lower the temperature inside the transformer installation (100). Meanwhile, a heat dissipation fan may be additionally formed between the cooling tube 210 and the housing 12, thereby dissipating heat absorbed from the partially exposed contact tube 220 to the outside.

In Figure 2 is formed between the diameter (B) of the cooling tube 210 and the diameter (A) of the contact tube 220 in a ratio of 1.3 to 1.5: 1.

When the upper insertion tube 240 extends from the contact tube 220 to the point where the upper panel 11 is located, the upper end of the contact tube 220 is bent to be inserted into the upper panel 11.

The upper insertion tube 240 absorbs heat to the inside of the upper panel 11 at the insertion portion into the upper panel 11, thereby lowering the temperature of the transformer facility 100.

The lower insertion tube 250 absorbs heat to the inside of the lower panel 13 at an insertion portion into the lower panel 130, thereby lowering the temperature of the transformer installation 100.

Since the gas / temperature measuring unit 300 is configured and functions in the same manner as in FIG. 1, description thereof will be omitted.

7 shows an embodiment of the circulation method, not the heat dissipation method in FIGS. 1 and 3, and lowers the heat of the distribution panel main body 10 by using water from the boiler inlet pipe and the water and sewage pipe 410 provided outside. It will be described in detail as follows.

The heat dissipation of the circulation method shown in FIG. 7 is installed in the boiler inlet pipe and the water and sewage pipe 410 which are provided outside to install a first connection pipe 420, and the main switchgear main body at one side of the first connection pipe 420. An inlet pipe 430 is provided to be introduced into the 10.

One side of the inflow pipe 430 penetrates into the housing 12 and is installed into the distribution panel main body 10, and a circulation motor 400 having an anti-vibration pad 440 is installed on the surface of the housing 12.

Therefore, the inlet pipe 430 is installed in the inlet of the circulation motor 400 to move the water in the boiler inlet pipe and the water and sewage pipe 410 to the water distribution board main body 10.

In addition, the water moved through the circulation motor 400 is moved to the circulation pipe 432, the water moved to the circulation pipe 432 is made of a means for moving the heat of the switchboard main body 10 to the outside.

One side of the circulation pipe 432 is provided through the housing 12 to the outside, one side of the circulation pipe 432 provided to the outside is connected to the discharge pipe 431, the discharge pipe 431 is a second connection Consists of being connected to the boiler inlet pipe and the water and sewage pipe 410 through the pipe 421.

At this time, the second connection pipe 421 connected to the discharge pipe 431 is formed in the flow direction of the water, it is made so as not to interfere with the flow of water flowing in the boiler inlet pipe and the water and sewage pipe 410.

In addition, the circulation pipe 432 provided inside the switchboard main body 10 is formed to be connected to the transformer facility enclosure 110 at the bottom, and to the top of the circulation pipe 432 to discharge the heat of the upper panel 11 to the outside. The pipe is connected.

The contact tube 220 is inserted into the transformer facility enclosure 110, the cooling tube 210 is wrapped so that the contact tube 220 is not exposed to the outside.

In addition, the contact tube 220 is partially exposed inside the circulation tube 432 to cool the heat of the transformer facility enclosure 110 through the contact tube 220 partially exposed.

In addition, the contact tube 220 is inserted into the upper panel 11 is made of the cooling tube 210 is wrapped so as not to be exposed to the outside, the contact tube 220 is circulated in the same manner as the transformer facility enclosure 110 The heat is cooled by being partially exposed inside the tube 432.

In addition, the anti-vibration pad 440 provided between the circulation motor 400 and the housing 12 prevents the vibration of the circulation motor 400 and is made of a rubber material, and the circulation motor 400 and the housing 12. It is made to insulate the liver.

In addition, the motor control panel 450 is provided on the upper side of the circulation motor 400, the motor control panel 450 is formed to be coupled to the inner surface of the housing to form a dustproof pad 440.

As described above, preferred embodiments of the present invention have been disclosed in the present specification and drawings, and although specific terms have been used, they have been used only in a general sense to easily describe the technical contents of the present invention and to facilitate understanding of the invention , And are not intended to limit the scope of the present invention. It is to be understood by those skilled in the art that other modifications based on the technical idea of the present invention are possible in addition to the embodiments disclosed herein.

10: main body of switchboard 11: top panel
12 housing 13 lower panel
100: transformer unit 110: transformer unit enclosure
200: heat pipe 210: cold pipe
220: contact tube 230: central insertion tube
240: upper insertion tube 250: lower insertion tube
300: gas / temperature measuring unit 310: gas sensor
320: temperature sensor 330: wireless transmitter and receiver
400: circulation motor 410: boiler inlet pipe and water and sewage pipe
420: first connector 421: second connector
430: inlet pipe 431: discharge pipe
432: circulation pipe 440: dustproof pad
450: motor control panel 500: heat dissipation fan

Claims (11)

A switchgear body including a housing formed between the upper panel and the lower panel; A transformer unit formed inside the transformer unit enclosure to supply high voltage power to an external device; And a heat pipe contacting the transformer and absorbing heat generated from the transformer by filling a heat transfer nanomaterial therein. One side of the heat pipe is connected to any one of the boiler inlet pipe and water and sewage pipe; In the hybrid switchgear having a heat pipe connection structure for reducing the temperature, the heat pipe,
A contact tube in contact with the transformer facility;
A cooling tube surrounding a lower portion of the contact tube, the one end of which has a structure in contact with an inner surface of the main switchboard body; And
A central insertion tube inserted into the transformer unit housing by branching the contact tube; Hybrid switchgear having a heat pipe connection structure for reducing the temperature comprising a.
The method according to claim 1, wherein the upper panel,
It is formed in a plate shape having a length and thickness longer than the housing to form a heat dissipation plate to heat the air inside the main body of the switchgear through heat exchange with external air,
The lower panel,
The heat pipe connection structure for reducing the temperature, characterized in that formed in a rectangular plate shape having a length and thickness longer than the housing to heat the air inside the switchboard body through heat exchange with the lower surface Hybrid switchgear having a.
delete The method according to claim 1,
A gas sensor which is formed inside the housing and detects that gas is generated by the internal equipment being burned out by a short circuit and a short circuit, a temperature sensor that is formed inside the housing to measure the temperature of the inside and generates measurement data, and wireless transmission and reception Gas / temperature measuring unit including a wireless transmission and reception unit for transmitting the measurement data for the warning data or temperature according to the gas generation to the smartphone through; Hybrid switchgear having a heat pipe connection structure for reducing the hybrid temperature further comprises.
The method according to claim 4, wherein the heat pipe,
An upper insertion tube formed by extending the contact tube to a point where the upper panel is located and having a structure inserted into the upper panel by bending an uppermost end of the contact tube; Hybrid switchgear having a heat pipe connection structure for reducing the temperature further comprising.
The method according to claim 5, wherein the heat pipe,
A lower insertion tube extending from a lower end of the contact tube inside the cold storage tube and bent into the lower panel to be inserted into the lower panel; Hybrid switchgear having a heat pipe connection structure for reducing the temperature further comprising.
The method of claim 6,
The cold pipe diameter (B) and the diameter (A) of the contact tube is a hybrid water distribution panel having a heat pipe connection structure for temperature reduction, characterized in that formed in a ratio of 1.3 to 1.5: 1.
The method of claim 7,
The contact tube, the center insertion tube, the upper insertion tube, the lower insertion tube,
Formed of copper tubes,
The cold pipe, the hybrid switchgear having a heat pipe connection structure for reducing the temperature, characterized in that formed of a PE pipe or PVC pipe.
According to claim 1, The first inlet pipe connected to the lower side of any one of the boiler inlet pipe and the water supply and sewage pipe; And
A second connection pipe connected to any one of the upper side of the boiler inlet pipe and the water supply and sewage pipe is provided, the inlet pipe is coupled to the first connection pipe, the discharge pipe is coupled to the second connection pipe Hybrid switchgear having a heat pipe connection structure for the.
The method according to claim 9,
One side of the inlet pipe penetrates the housing, is connected to the circulation motor provided in the housing, the circulation motor is coupled to the dustproof pad is provided inside the housing, the motor control panel having a dustproof pad on the inner surface of the housing Is coupled, the circulation pipe is provided with one side of the circulation motor, one side of the circulation tube is a hybrid water distribution panel having a heat pipe connection structure for temperature reduction, characterized in that coupled to the discharge pipe.
12. The method of claim 10,
A contact tube connected to the transformer unit enclosure is exposed to the lower side of the circulation tube, and a contact tube connected to the upper panel is exposed to the upper side of the circulation tube so that heat is cooled by water flowing in the circulation tube. Hybrid switchgear having a heat pipe connection structure for reducing the temperature.

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