KR102172256B1 - Valve Room with Heat Pipe Structure - Google Patents

Abstract

The present invention relates to a valve chamber having a heat pipe structure, which prevents dew condensation. The valve chamber having the heat pipe structure includes: a valve chamber embedded at a predetermined depth from the ground surface and comprising a valve chamber main body having an upper frame; and a heat pipe structure installed to penetrate through the valve chamber main body, wherein the heat pipe structure obtains a heat source from geothermal heat under the ground to heat an inner side of the upper frame.

Description

Valve Room with Heat Pipe Structure {Valve Room with Heat Pipe Structure}

The present invention relates to a valve chamber provided with a heat pipe structure to prevent condensation.

It is common to bury the valve room at the location where facilities such as water control valves are installed for safe and convenient maintenance work while protecting facilities such as water drainage valves that are connected in the middle of paths such as water and sewage pipes buried underground. .

A manhole is installed on the upper side of the valve room to allow the operator to enter from the ground, and such a manhole is usually composed of a manhole cover for opening and closing the manhole, and a manhole frame provided on the upper side of the valve room so that the manhole cover can be seated. .

The manhole cover provided on the upper side of the valve chamber becomes high temperature by sunlight, especially in summer, and this high temperature may be transmitted to the inside of the valve chamber to increase the high temperature.

The hot air inside the valve chamber is concentrated on the upper frame and becomes high temperature, and the outer surface of the upper frame is buried underground at a predetermined depth, so the outer surface of the upper frame is low temperature and the inner surface is high temperature, causing condensation due to temperature difference. do.

When such condensation falls, it may damage various electronic circuit components installed inside the valve chamber.

Korean Patent Registration No. 10-1766413 (Registration Date: August 02, 2017)

The present invention is to provide a valve chamber having a heat pipe structure that prevents condensation from occurring in the valve chamber body by reducing a temperature difference between the inside and the outside of the valve chamber body.

The solution means of the present invention comprises a valve chamber made of a valve chamber body buried at a predetermined depth from the ground surface and having an upper frame; Including a heat pipe structure installed to pass through the valve chamber body,

The heat pipe structure may be provided with a valve chamber for heating the inside of the upper frame by obtaining a heat source from underground geothermal heat.

According to the present invention, condensation generated on the inner surface of the upper frame, which is the inner upper side of the valve chamber body, can be prevented by providing a heat pipe structure penetrating the upper side of the valve chamber to reduce the temperature difference between the inside and the outside of the valve chamber body.

In the present invention, at least one end of the heat conduction pipe constituting the heat pipe structure is exposed through the valve chamber body and is buried underground, obtains a heat source from the underground geothermal heat to heat the heat conduction pipe, and heats the heat conduction pipe by the heated heat conduction pipe. Since the pipe is heated, the upper side inside the valve chamber can be heated, and condensation inside the valve chamber can be prevented accordingly.

The heat pipe structure of the present invention can be provided inclined with a predetermined angle on the upper side of the valve chamber body, whereby the heat source of the geothermal heat of the high part of the heat pipe structure can move to the low part to realize an even heating state. Accordingly, condensation can be prevented by heating the inner surface of the upper frame of the valve chamber body more quickly.

In addition, in the present invention, since the passage part is formed inside the heat conduction pipe, and both ends of the heat conduction pipe are open, air can be circulated, and the heat conduction pipe obtained as a heat source by circulation of air can heat air. Thus, the heat conduction pipe can be quickly and evenly heated by the circulation movement of air.

In addition, the present invention is a heat consisting of a first pipe, a second pipe provided inside the first pipe, a heat pipe provided between the first pipe and the second pipe and wound along the length direction on the outer peripheral surface of the second pipe. A pipe structure may be provided, and such a heat pipe structure is a structure in which a passage through which air is circulated is formed inside the second pipe, and one or both ends of the second pipe are side frames from the upper side of the valve chamber body. The heat pipe can be quickly heated by gaining geothermal heat by being exposed through and buried underground, and condensation can be prevented by heating the inner side of the upper frame of the valve chamber body.

1 is a front view of the valve chamber of the present invention.
2 is a plan view of the valve chamber of the present invention.
3 is an enlarged cross-sectional view of one end of the heat pipe structure according to an embodiment of the present invention.
4 is a longitudinal sectional view of the heat pipe structure of the present invention.
5 is a cross-sectional view showing a heat pipe structure according to another embodiment of the present invention.
6 is a partially enlarged cross-sectional view of FIG. 5.
7 is a schematic diagram of another example of installation of a heat pipe structure in the valve chamber of the present invention.

Hereinafter, specific details for carrying out the present invention will be described in detail based on the accompanying exemplary drawings.

1 is a front view of the valve chamber of the present invention, and FIG. 2 is a plan view of the valve chamber of the present invention. 1 and 2, the valve chamber 100 is made of a valve chamber body 110, and the valve chamber body 110 includes an upper frame 112, a side frame 114, and a lower frame 116. Can be done.

A manhole frame 140 and a manhole cover 150 may be provided on an upper portion of the valve chamber body 110.

The valve chamber body 110 may be formed in a rectangular cylindrical shape or a cylindrical shape.

The manhole cover 150 is heated together with the ground surface due to hot sunlight, especially in summer, and such heat may be transmitted to the inside of the valve chamber body 110 as it is.

The inside of the valve chamber body 110 may be heated by increasing the temperature due to the transfer of the heated manhole cover 150.

However, since the upper frame 112 and the side frame 114 of the valve chamber main body 110 are buried at a predetermined depth (D) from the ground surface, the heat of the high-temperature ground surface is blocked, so that a relatively low-temperature state is prevented. Can be.

Accordingly, condensation may occur inside the valve chamber body 110 due to a temperature difference with the outside of the ground.

Condensation generated inside the valve chamber body 110 is not a problem because it flows downward when it flows down the side of the valve chamber body 110, but falls from the upper inner surface of the valve chamber body 110. Condensation may fall and damage various electronic circuit components (not shown) provided under it.

In the present invention, in order to reduce the temperature difference between the inside and the outside of the valve chamber body 110, a heat pipe 200 passing through the valve chamber body 110 may be provided.

The heat pipe structure 200 may be formed of a heat pipe 210 forming an exterior and a heat conduction pipe 220 provided inside the heat pipe 210 with reference to FIGS. 3 and 4.

A space part 212 may be formed between the heat pipe 210 and the heat conduction pipe 220. A working fluid 214 capable of generating heat when a heat source is obtained may be provided inside the heat pipe 210.

In addition, the heat conduction pipe 220 has a passage portion 222 through which air is circulated, and both ends 224 of the heat conduction pipe 220 extend in length from both ends of the heat pipe 210 It can protrude, and can be buried in the ground in an open state.

The closing member 230 may be coupled to the end 224 of the heat conduction pipe 220. A plurality of ventilation holes 232 may be formed in the closing member 230.

The heat pipe 210 may obtain a heat source using a powerless method or a power supply method.

The power-free method may be a method of obtaining a heat source from geothermal heat without separate electrical connection to the heat pipe 210, and the power method may be a method of generating heat by receiving power by making an electrical connection to the heat pipe 210.

1 and 3, the heat pipe structure 200 according to an embodiment of the present invention faces the inner surface of the upper frame 112 of the valve chamber body 110 or is spaced apart at a predetermined interval. The heat pipe structure 200 may be penetrated across the state, and both ends of the heat pipe structure 200 may be exposed through the side frame 114 of the valve chamber body 110 and buried underground.

At least one end of the heat pipe structure 200 according to an embodiment of the present invention is exposed through the side frame 114 of the valve chamber body 110 and is buried underground, and the other end is the side frame ( 114) can be installed only up to the side frame 114 without penetrating.

When a specific configuration of the heat pipe structure 200 is described, it is composed of a heat pipe 210 and a heat conduction pipe 220 provided inside the heat pipe 210, and both ends 222 of the heat conduction pipe 220 ) Can be buried underground in an open state.

In addition, the heat pipe structure 200 is buried underground by exposing only one end 222 of the heat conduction pipe 220 through the side frame 114, and the other end 222 of the heat conduction pipe 220 It may be made of an open structure to communicate with the outside air without penetrating the frame 114.

In other words, the other end 222 of the heat conduction pipe 220 is coupled only to the side frame 114 so as to be visible from the outside so that an open opening can be seen.

The depth at which the heat conduction pipe 220 is buried from the ground surface may be 40 cm to 50 cm, and thus, geothermal heat of a predetermined temperature is present, although lower than the ground surface, and such geothermal heat can be obtained.

Both ends of the heat pipe 210 may be sealed on the outer peripheral surface of the heat conduction pipe 220.

Accordingly, both ends 222 of the heat conduction pipe 220 can obtain a heat source from geothermal heat existing underground, and the heat source thus obtained can be transferred to the heat pipe 210.

When the heat conduction pipe 220 obtains a heat source, since the working fluid 212 is formed on the outer circumferential surface of the heat conduction pipe 220, the working fluid 212 obtains a heat source and generates heat, and accordingly, the heat pipe 210 generates heat. As a result, the inside of the valve chamber body 110 can be heated.

In addition, since the passage portion 222 is formed inside the heat conduction pipe 220 and both ends are open, air can be circulated. Therefore, the geothermal heat obtained at the end 224 can heat the air circulated inside the heat conduction pipe 220, and the heated air is circulated along the length direction of the heat conduction pipe 220, so that the heat conduction pipe 220 The temperature can be quickly raised.

Of course, because the end portion 224 of the heat conduction pipe 220 is buried underground, air may not communicate properly, but since the underground is not a completely sealed structure, air is sufficiently communicated. Can be cycled.

Since the heat conduction pipe 220 can be quickly heated up, heat generation of the heat pipe 210 can also be achieved quickly. Moreover, since the heat pipe 210 is a structure provided in the upper part of the valve chamber body 110, when a heat source is obtained, the inner upper side of the valve chamber body 110 can be heated, thereby preventing condensation due to temperature difference. can do.

In addition, both ends 224 of the heat conduction pipe 220 have an open structure for circulation of air, but when buried, soil may flow into the passage part 222 in the heat conduction pipe 220, By combining (230) it is possible to prevent the inflow of soil.

Due to the coupling of the closing member 230, air circulation of the heat conduction pipe 220 may not be properly performed, but since a plurality of ventilation holes 232 are formed in the closing member 230, soil does not enter and only air communicates. Can be.

Meanwhile, as another embodiment, referring to FIG. 5, the heat pipe structure 300 of the present invention includes a first pipe 310, a second pipe 320 provided inside the first pipe 310, and It may be formed of a heat pipe 330 provided between the first pipe 310 and the second pipe 320 and wound on the outer peripheral surface of the second pipe 320 along the longitudinal direction.

A space part 312 in which the heat pipe 330 may be provided is formed in the first pipe 310, and a passage part 322 through which air is circulated may be formed in the second pipe 320. have.

Both ends of the second pipe 320 have an open structure, and separate closing members 230 may be coupled. A plurality of ventilation holes 232 through which air communicates may be formed in the closing member 230.

The heat pipe structure 300 according to another embodiment of the present invention passes through the upper portion of the valve chamber body 110, similarly to the heat pipe structure 200 according to the embodiment, so that one end or both ends thereof is the side frame 114 It may protrude to be exposed through through.

When only one end of the heat pipe structure 300 is exposed through the side frame 114, the other end is provided only up to the side frame 114, and the second end is provided from the outside of the valve chamber body 110 so that air is communicated. The passage portion 322 in which the pipe 320 is an opening may be seen.

In the heat pipe structure 300 according to another embodiment of the present invention, a heat pipe 330 is provided between the first pipe 310 and the second pipe 320, and the end 324 of the second pipe 310 ) Is a structure buried in the basement (1) at a predetermined depth, so a heat source by geothermal heat can be obtained from the basement (1).

When the second pipe 310 is heated by obtaining a heat source by geothermal heat, the heat pipe 330 wound along the longitudinal direction on the outer circumferential surface of the second pipe 310 may be heated. Since the working fluid 332 is provided inside the heat pipe 330, a heat source of the second pipe 310 can be obtained and quickly heated.

Since the first pipe 310 is provided on the outer circumferential surface of the heat pipe 330, the first pipe 310 can also be heated, and accordingly, the inner upper portion of the valve chamber body 110, that is, the upper frame 112. The inner surface can be heated.

The inside of the second pipe 320 has a passage portion 322 through which air is circulated, and both ends are open, so that air can be circulated. Both ends 324 of the second pipe 320 When the geothermal heat is obtained, the air existing in the passage portion 322 of the second pipe 320 may also be heated, and since this air is circulated through the passage portion 322, the heat source moves and the second pipe ( 320) can be heated throughout.

Accordingly, the heat pipe 330 wound around the outer circumferential surface of the second pipe 320 can be quickly heated.

Of course, when the valve chamber 100 is buried underground, since soil may flow into the open end side of the second pipe 320, the closing members 230 at both ends 324 of the second pipe 320 ) Can be combined to prevent soil from entering.

Since a plurality of ventilation holes 232 are formed in the closing member 230, air can communicate while blocking soil. Accordingly, air circulation in the passage portion 322 of the second pipe 320 is not impeded.

7 is a schematic diagram of another example of installation of a heat pipe structure in the valve chamber of the present invention.

Referring to FIG. 7, the heat pipe structures 200 and 300 penetrating inside the upper frame 112 of the valve chamber body 110 may be disposed to be inclined to one side with an angle α.

The heat pipe structures 200 and 300 penetrating from the inner side of the upper frame 112 may be installed to face the inner side of the upper frame 112 or are spaced apart from each other at a distance, as shown in FIG. 7, Heat pipe structures 200 and 300 may be installed inclined in one direction with the entire spaced apart, and when facing, one side of the heat pipe structure 200 and 300 faces the inner side of the upper frame 112 In addition, the heat pipe structure 200 and 300 may be disposed in an inclined manner at intervals toward the other side.

When the heat pipe structures 200 and 300 are arranged inclined to one side with an angle α, the geothermal heat obtained from the high side of the heat pipe structures 200 and 300 may have a relatively higher temperature than the geothermal heat obtained from the lower side, Accordingly, the working fluid in each of the heat pipes 210 and 330 moves from a high temperature to a low temperature, and a circulation operation in which the working fluid in a low position moves to a high position is performed, so that even heat generation can be achieved.

In addition, air circulating in the heat conduction pipe 220 of the heat pipe structure 200 and the passage portions 222 and 322 formed in the second pipe 320 of the heat pipe structure 300 of another embodiment are more smoothly Can be cycled.

Therefore, when the air circulation in each passage part 222, 322 is made more smoothly, a heat source by geothermal heat in the basement can be quickly transferred to the heat conduction pipe 220 and the second pipe 320, Then, since the heat source is more rapidly and evenly transmitted to the heat pipes 110 and 330, the upper side inside the valve chamber body 110 can be effectively heated. By such efficient heating, condensation that may occur inside the valve chamber body 110 may be prevented.

1: underground
100: valve chamber 110: valve chamber body
112: upper frame 114: side frame
116: lower frame 150: manhole cover
200: heat pipe structure 210: heat pipe
212: space part 214: working fluid
220: heat conduction pipe 222: passage portion
224: end 230: finishing member
232: ventilation hole 300: heat pipe structure
310: first pipe 312: space
320: second pipe 322: passage portion
324: end 330: heat pipe
332: working fluid

Claims (10)

A valve chamber made of a valve chamber body buried at a predetermined depth from the ground surface and having an upper frame;
A heat pipe structure installed to pass through the valve chamber body;
Including,
The heat pipe structure heats the inside of the upper frame by obtaining a heat source from underground geothermal heat,
The heat pipe structure,
It consists of a second pipe, a heat pipe wound along the length direction on the outer peripheral surface of the second pipe,
At least one end of the second pipe is exposed to the outside of the valve chamber body to be buried.
The method of claim 1,
The heat pipe structure,
It consists of a heat pipe, a heat conduction pipe provided inside the heat pipe,
At least one end of the heat conduction pipe is exposed to the outside of the valve chamber body and buried,
The heat pipe structure is installed through the inner surface of the upper frame of the valve chamber body facing or spaced apart from each other.
The method of claim 2,
A valve chamber having a structure in which a passage through which air is circulated is formed in the heat conduction pipe, and both ends of the heat conduction pipe are open.
The method of claim 2,
At the end of the heat conduction pipe,
A valve chamber in which a closing member having one or more ventilation holes for communicating air and blocking soil inflow is combined.
delete The method of claim 1,
A valve chamber having a structure in which a passage through which air is circulated is formed in the second pipe, and both ends of the second pipe are open.
The method of claim 1,
A valve chamber provided with a first pipe heated by receiving a heat source from the heat pipe on an outer peripheral surface of the heat pipe.
The method of claim 6,
At both ends of the second pipe,
A valve chamber in which a closing member having at least one ventilation hole through which air is communicated and the inflow of soil is blocked is combined.
The method of claim 1,
The heat pipe structure
A valve chamber which is obliquely penetrated in one direction from the inside of the upper frame of the valve chamber body.
The method of claim 9,
The heat pipe structure is inclinedly coupled while being spaced apart from an inner surface of the upper frame, or in a state in which a portion of the heat pipe structure is faced to each other and is inclinedly coupled to an end.

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