KR101233786B1 - Apparatus for overheating and freezing of facilities - Google Patents

Abstract

An apparatus for preventing overheating and freezing of a facility is disclosed. It is installed in the facility, and it is formed into a heat exchanger and a tubular type that exchanges the facility with the outside, and a working fluid is injected, and one side is disposed adjacent to the heat exchanger to enable heat transfer with the facility, and the other side uses a tubular heat pipe buried in the ground. Including, the tubular heat pipe is a facility overheating and freezing prevention device, characterized in that to transfer the heat of the facility to the ground and stored when the facility is heated than the ground and to transfer the heat of the ground to the facility when the facility is cooled than the ground, By using only a tubular heat pipe without the need for an additional actuating device, the facility can not be overheated and frozen, reducing unnecessary energy consumption and making maintenance easier.

Description

Apparatus for overheating and freezing of facilities}

The present invention relates to a facility overheating and freezing prevention device.

In general, the facility must be maintained at an appropriate temperature range to function properly. Some installations may even lose their function if they are placed in conditions beyond the proper temperature range.

In particular, electronic equipment, such as a communication base station, generates a lot of heat in itself, which is likely to overheat, and may even be overheated by external influences in the cold season. There is also a fear of freezing during cold weather.

In order to prevent damage to electronic equipment due to such overheating or freezing, a method of installing a separate air conditioner or heating device in a facility has been proposed as shown in Korean Patent Publication No. 10-2008-0105628, but it consumes extra energy. There is a problem that the cooling device and the heating device itself are also difficult to maintain due to the risk of failure.

In addition, the conventional apparatus is only for the purpose of overheating or freezing, there is also a problem that requires two separate devices to prevent overheating and freezing together.

The present invention is to provide a facility for preventing overheating and freezing of facilities without consuming extra energy and simple maintenance.

According to an aspect of the present invention, the installation is installed in the facility, the heat exchanger and the tubular shape to heat exchange the facility with the outside is formed in the working fluid is injected, one side is disposed adjacent to the heat exchanger is the facility and heat transfer And the other side includes a capillary heat pipe embedded in the ground, wherein the capillary heat pipe transfers and stores the heat of the facility to the ground when the facility is heated above the ground, and the facility is lower than the ground. When cooled, facility overheating and freezing prevention apparatus is provided, which transfers underground heat to the facility.

The tubular heat pipe may be formed to alternately reciprocate the heat exchange part and the ground.

The heat exchanger may include a radiator coupled to the facility.

The radiator may have a heat transfer structure including a weak heat pipe.

The heat exchange part may include a case or a housing of the facility.

The facility may include electronic equipment.

The electronic equipment may be any one of a communication base station, a transformer and a lamp.

According to the embodiment of the present invention, by using only the tubular heat pipe without additional operating device to prevent overheating and freezing of the facility, unnecessary energy consumption can be reduced and maintenance can be facilitated.

In addition, overheating and freezing can be prevented together with a simple configuration that does not require separate control.

1 is a view showing a facility overheating and freezing prevention apparatus according to an embodiment of the present invention.
Figure 2 is a view showing a facility overheating and freezing prevention apparatus according to another embodiment of the present invention.
3 is a view showing a facility overheating and freezing prevention apparatus according to another embodiment of the present invention.

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

1 is a view showing a facility overheating and freezing prevention apparatus according to an embodiment of the present invention.

Facility overheating and freezing prevention apparatus 100 according to an embodiment of the present invention includes a heat exchange unit 120 and the tubular heat pipe 130, according to the state of the facility 110 without a separate control device of the ground Heat generated in the facility 110 is characterized in that the ground (地 中, 1), that is, radiate into the ground or transfer the thermal energy of the ground (1) to the facility (110).

The heat exchanger 120 is installed in the facility 110, the heat exchanger to the outside of the facility 110, the heat exchanger 120 of the present embodiment through the heat exchange with the tubular heat pipe 130 to be described later facility Heat transfer between the 110 and the tubular heat pipe 130 is enabled.

As shown in FIG. 1, the facility 110 of the present embodiment is a communication base station which is a kind of electronic equipment, and the heat exchanger 120 is a radiator having heat dissipation fins coupled to the communication base station. At this time, in order to further improve the performance of the radiator, the radiator may have a heat transfer structure using a weak heat pipe.

The tubular heat pipe 130 is a part that transfers and radiates heat energy transferred to the heat exchanger 120 to the ground 1 or transfers heat energy stored in the ground 1 back to the heat exchanger 120. To this end, one side of the tubular heat pipe 130 of the present embodiment is disposed adjacent to the heat exchanger 120 to enable heat transfer with the heat exchanger 120, the other side is embedded to extend to the ground (1). .

In addition, the tubular heat pipe 130 of the present embodiment consists of a heat pipe injected with the working fluid 133 to rapidly transfer a large amount of thermal energy while minimizing heat loss. Representatively, the vibrating tubular heat pipe 130 may be used.

As shown in FIG. 1, the vibrating tubular heat pipe 130 has a structure in which the inside of the tubule 132 is sealed from the outside after the working fluid 133 and the bubble 134 are injected into the tubule 132 at a predetermined ratio. Has Accordingly, the vibrating tubular heat pipe 130 has a heat transfer cycle for transporting a large amount of heat in latent heat form by volume expansion and condensation of the bubble 134 and the working fluid 133.

Looking at the heat transfer mechanism, the heat absorbing portion is nuclear boiling (1Nucleate Boiling) by the amount of heat absorbed as the bubbles 134 are located in the heat absorbing portion is the volume expansion. At this time, since the tubule 132 maintains a constant internal volume, the bubbles 134 located in the heat dissipating part which dissipate heat as much as the bubbles 134 located in the heat absorbing part have a volume expansion are contracted. Accordingly, as the pressure equilibrium state in the tubule 132 collapses, the flow including the vibration of the working fluid 133 and the bubbles 134 in the tubule 132 is accompanied, and thus the temperature due to the volume change of the foam 134 is accompanied. The heat dissipation is carried out by the latent heat transportation by lifting and lowering.

Here, the vibrating capillary heat pipe 130 may include a capillary tube made of a metal material such as copper and aluminum having high thermal conductivity. Accordingly, while conducting heat at a high speed, the volume change of the bubble 134 injected therein may be rapidly induced.

In addition, the heat pipe formed of the tubule 132 may have a large heat transfer area to volume, and thus may rapidly absorb or release a large amount of heat. In addition, since there is no restriction on the direction of heat transfer, heat transfer is excellent in any direction, and there is an advantage in that the arrangement is free.

On the other hand, the communication structure of the vibrating tubular heat pipe 130 can be both an open loop (close loop) and (close loop). In addition, when the vibrating tubular heat pipe 130 is plural, all or part of the vibrating tubular heat pipe 130 may be in communication with a neighboring vibrating tubular heat pipe 130. Accordingly, the plurality of vibrating capillary heat pipes 130 may have an open or closed loop shape as a design necessity.

As shown in FIG. 1, in the present embodiment, a plurality of capillary heat pipes 130 having a closed loop structure are continuously arranged. In addition, each capillary heat pipe 130 may be formed to alternately reciprocating the heat exchange unit 120 and the ground (1). Specifically, in this embodiment, part 130a of the tubular heat pipe 130 is coupled to the radiator, and the other part 130b is embedded in the ground.

Accordingly, when high heat is generated in the communication base station that is the facility 110 or when high heat is transferred from the outside to the communication base station (that is, when the facility 110 is heated than the ground 1), the tubular heat pipe 130 is used. The portion 130a coupled to the radiator is a heat absorbing portion, and the portion 130b buried in the ground 1 becomes a heat radiating portion so that heat of the communication base station can be quickly and radiated to the ground 1.

In particular, since the ground maintains a constant temperature even when the temperature changes outside (especially seasonal temperature change), the ground temperature is not only generated when the communication base station itself generates heat but also when the outside temperature rises and heats up. By using a lower characteristic than this, it is possible to effectively prevent overheating of the communication base station.

In addition, in winter (that is, when the facility 110 is cooler than the ground 1), the capillary heat pipe 130 may release the thermal energy of the ground 1 to the communication base station to prevent freezing. At this time, the portion 130a of the tubular heat pipe 130 coupled to the radiator becomes the heat radiating portion, and the portion 130b embedded in the ground 1 becomes the heat absorbing portion. Here, the tubular heat pipe 130 has a high heat transfer efficiency due to the rapid heat transfer as described above, thereby minimizing heat lost to the surroundings in the heat transfer process to increase the energy efficiency of geothermal heat delivered to the facility 110. have. In addition, the tubular heat pipe 130 has a high degree of freedom of installation because the performance is maintained regardless of the orientation.

In summary, the facility overheating and freezing prevention apparatus 100 of the present embodiment uses the thermal energy (heat and cold heat) of the ground (1) when necessary by using the tubular heat pipe 130 having excellent heat transfer performance in both directions. It is possible to prevent overheating and freezing of the 110). In particular, since the transfer of thermal energy uses the thermal equilibrium property, which is a natural law, it does not require an additional operating device such as a pump. This eliminates the need for separate control and facilitates installation and maintenance of the device.

Meanwhile, in the present embodiment, the communication base station has been described as an embodiment, but the facility overheating and freezing prevention apparatus according to the present invention can be applied to various electronic equipments requiring proper temperature conditions. For example, it can be applied to transformers and lightings.

2 is a view showing a facility overheating and freezing prevention apparatus according to another embodiment of the present invention.

The facility overheating and freezing prevention apparatus 200 according to the present embodiment is different from the above-described embodiment in that the facility 210 is an illumination tower and the case or housing of the facility is a heat exchanger. Therefore, since the basic structure and function of the tubular heat pipe 230 is almost similar, a detailed description thereof will be omitted.

As shown in FIG. 2, in the present embodiment, the facility is a light tower having a plurality of lights 212, and heat generated from the lights is transmitted to the outside through the pillars 214 of the light tower. That is, the pillar that is the housing of the light tower serves as a heat exchanger.

Accordingly, the portion 230a of the tubular heat pipe is coupled to the column 214, which is a heat exchanger, and the other portion 230b has a structure embedded in the ground. Therefore, it is possible to prevent overheating and freezing of the lighting tower which is a facility through the heat transfer function described above.

On the other hand, Figure 3 is a view showing a facility overheating and freezing prevention apparatus according to another embodiment of the present invention.

The facility overheating and freezing prevention apparatus 300 according to the present embodiment is different from the above-described embodiment in that a separate heat exchanger is installed in the facility 310 and the heat exchanger becomes the heat exchanger 320. Therefore, since the basic structure and function of the lighting 312, the pillar 314 and the tubular heat pipe 320 is almost similar, detailed description thereof will be omitted.

Conventional facility 310 may have its own air-cooled or water-cooled heat exchanger. Facility overheating and freezing prevention apparatus 300 of the present embodiment has the advantage that it is easy to install the facility overheating and freezing prevention apparatus 300 in a conventional facility by utilizing a heat exchanger installed in the existing facilities.

As shown in Figure 3, the lighting tower in this embodiment is provided with a separate water-cooled heat exchanger. Accordingly, the tubular heat pipe 330 of the present embodiment is configured to enable heat transfer with the water-cooled heat exchanger that is the heat exchanger 320. Specifically, a water pipe 325 connected to the water-cooled heat exchanger is disposed adjacent to a portion 330a of the tubular heat pipe 330 to perform heat exchange. The other portion 330b of the tubular heat pipe 330 is buried in the ground to perform heat exchange with the ground.

On the other hand, the above-described embodiments according to the present invention described the overheating and freezing prevention apparatus for the facility, such as electronic equipment, but the facility is not limited to the electronic equipment. Various buildings and structures that require an appropriate temperature range to perform a function also fall within the scope of the facility of the present invention.

Although the above has been described with reference to embodiments of the present invention, those skilled in the art may variously modify the present invention without departing from the spirit and scope of the present invention as set forth in the claims below. And can be changed.

Many embodiments other than the above-described embodiments are within the scope of the claims of the present invention.

1: underground
100, 200, 300: facility overheating and freezing prevention device
110, 210, 310: Facility
120, 320: heat exchange unit
130, 230, 330: tubular heat pipe

Claims (7)

A heat exchanger installed at the facility and including a radiator coupled to the facility to heat-exchange the facility with the outside; And
It is formed in a tubular shape and a working fluid is injected, one side is disposed adjacent to the heat exchanger to enable heat transfer with the facility and the other side includes a tubular heat pipe embedded in the ground,
The tubular heat pipe is characterized in that when the facility is heated than the ground, the heat of the facility is transferred to the ground and stored, and when the facility is cooled than the ground, the ground heat is transferred to the facility. Facility overheating and freezing protection.
The method of claim 1,
The tubular heat pipe is a facility overheating and freezing prevention device, characterized in that formed in the form of reciprocating the heat exchanger and the ground alternately.
delete The method of claim 1,
The radiator has a heat transfer structure comprising a weak heat pipe, facility overheating and freezing prevention device.
The method of claim 1,
The heat exchange unit, the facility overheating and freezing prevention device, characterized in that it comprises a case or housing of the facility.
The method of claim 1,
The facility is overheating and freezing prevention device, characterized in that it comprises electronic equipment.
The method according to claim 6,
The electronic equipment,
Facility overheating and freezing prevention device, characterized in that any one of a communication base station, transformer and lighting.

Images