KR102008943B1 - Temperature controll apparatus for distributing board - Google Patents

Abstract

The temperature control apparatus for a switchboard according to an embodiment of the present invention is a temperature control apparatus for a switchboard mounted on the enclosure of the switchboard and controls the temperature inside the enclosure, and is a thermoelectric module disposed outside the enclosure. A thermoelectric module including a thermoelectric element provided therein, a heating block including a cooling fin attached to a heat generating surface of the thermoelectric element, and a cooling block including cooling fins attached to a cooling surface of the thermoelectric element; A heat exchange module disposed inside the enclosure, the heat exchange module comprising a blowing fan configured to suck the air inside the enclosure and blow the air into the housing; And an annular circulation pipe which transfers a temperature between the thermoelectric module and the heat exchange module through a heat exchange medium flowing therein, which extends across the heat generating block of the thermoelectric module and the heat exchange module. And a heat generating circulation pipe for transmitting the heat exchange module to the heat exchange module, and a cooling circulation pipe extending over the cooling block of the thermoelectric module and the heat exchange module to transfer the low temperature heat of the thermoelectric module to the heat exchange module. ; At least one perforated portion is formed on the wall surface of the enclosure, the circulation pipe passes through the wall surface of the enclosure through the perforated portion, the perforated portion diameter of the heat generating circulation pipe or the cooling circulation pipe It is formed in a size corresponding to.

Description

TEMPERATURE CONTROLL APPARATUS FOR DISTRIBUTING BOARD

The present invention relates to a temperature control apparatus for a switchboard, and the thermoelectric module is disposed outside the enclosure of the switchboard and the heat exchange module is disposed inside the enclosure, and the thermoelectric module and the heat exchange module are connected by a circulation pipe, so that the structure is simple and easy to install. It is to provide a temperature control device for a switchboard.

The switchgear is a device for lowering and distributing the special high voltage to a voltage suitable for various devices, and has a special high voltage connection part, a transformer, and a low voltage distribution part inside the switchboard. Very high heat is generated inside the switchboard formed of such a structure, and this high heat often causes deterioration and damages to various internal devices. Excessive increase in temperature and humidity inside the cabinet of the switchboard at high temperature and high humidity will reduce the operation efficiency and accuracy of various components and devices, and will cause degradation of the contact point of electronic devices. Partial discharge is generated at the contacts inside the switchboard to generate an abnormal state inside the switchboard. Furthermore, there is a problem that may cause a fire, and cause secondary damage to various electronic devices electrically connected to the switchboard due to a malfunction caused by an abnormal state of the switchboard.

In the related art, a temperature control apparatus including a thermoelectric element is provided on the enclosure wall of the switchboard, and when the temperature and humidity inside the switchboard reach a set value, the cooling fan is immediately operated to forcibly lower the temperature inside the enclosure. However, the conventional temperature control device is mounted on the wall of the enclosure, the perforated surface is processed on the wall of the enclosure so that the temperature control device is mounted to penetrate the wall of the enclosure, one side of the thermoelectric element inside the enclosure, the other side Install to expose outside of enclosure. Accordingly, the perforated surface for installing the temperature control device should be formed in a fairly wide area on the wall of the enclosure, which is difficult to install and apply to the actual switchboard.

The present invention was devised to meet the requirements as described above, and an object of the present invention is to provide a temperature control apparatus for a switchboard that is easy to install in a switchboard.

The object of the present invention is not limited to those mentioned above, and other objects not mentioned will be clearly understood by those skilled in the art from the following description.

A temperature control apparatus for a switchboard according to an embodiment of the present invention for solving the above problems is a temperature control apparatus for a switchboard mounted on the enclosure of the switchboard to control the temperature inside the enclosure, as a thermoelectric module disposed outside the enclosure, And a cooling block including a thermoelectric element having a heating surface and a cooling surface, a heating block including a cooling fin attached to the heating surface of the thermoelectric element, and a cooling fin attached to the cooling surface of the thermoelectric element. Thermoelectric module; A heat exchange module disposed inside the enclosure, the heat exchange module comprising a blowing fan configured to suck the air inside the enclosure and blow the air into the housing; And an annular circulation pipe which transfers a temperature between the thermoelectric module and the heat exchange module through a heat exchange medium flowing therein, which extends across the heat generating block of the thermoelectric module and the heat exchange module. And a heat generating circulation pipe for transmitting the heat exchange module to the heat exchange module, and a cooling circulation pipe extending over the cooling block of the thermoelectric module and the heat exchange module to transfer the low temperature heat of the thermoelectric module to the heat exchange module. ; At least one perforated portion is formed on the wall surface of the enclosure, the circulation pipe passes through the wall surface of the enclosure through the perforated portion, the perforated portion diameter of the heat generating circulation pipe or the cooling circulation pipe It is formed in a size corresponding to.

In addition, the heat generating circulation pipe, a portion of one side is disposed close to the heat generating surface through the heating block of the thermoelectric module, the other portion is disposed on one side of the blower fan through the housing of the heat exchange module, The cooling circulation pipe may be disposed at one side of the blower fan through a portion of one side of the thermoelectric module close to the cooling surface, and a portion of the other side of the cooling circulation pipe through the housing of the heat exchange module.

In addition, one side and the other side of the heat generating circulation pipe, one side and the other side of the cooling circulation pipe may be connected to each other through a connector.

The one side portion of the exothermic circulation pipe is bent a plurality of times and disposed in parallel to the heating surface, and the other side portion of the exothermic circulation pipe is bent several times and disposed in parallel to the blowing fan, and the cooling is performed. The one side portion of the circulation pipe may be bent several times and disposed in parallel to the cooling surface, and the other portion of the cooling circulation pipe may be bent several times and disposed in parallel to the blowing fan.

According to the temperature control apparatus for the switchboard according to the embodiment of the present invention, it is enough to process only the perforated part to a size small enough to penetrate the circulation pipe to the wall of the enclosure, it is not necessary to process the existing wide perforated surface There is an easy advantage.

In addition, the temperature control device can be easily installed by inserting the circulation pipe into the enclosure through the hole and simply connecting the circulation pipe of the heat exchange module disposed in the enclosure to the connector. In addition, since the thermoelectric module and the heat exchange module are easily detachable by the connector, it is possible to easily repair or replace any component.

The effects of the present invention are not limited to those mentioned above, and other effects that are not mentioned will be clearly understood by those skilled in the art from the following description.

1 is a perspective view of a temperature control apparatus for a switchboard according to an embodiment of the present invention.
Figure 2 is a perspective perspective view of a temperature control apparatus for a switchboard according to an embodiment of the present invention.
3 is a perspective view of a temperature control apparatus for a switchboard according to an embodiment of the present invention.
4 is a cross-sectional view of a temperature control apparatus for a switchboard according to an embodiment of the present invention.
5 is a perspective view of a temperature control apparatus for a switchboard according to an embodiment of the present invention.

Objects and effects of the present invention, and technical configurations for achieving them will be apparent with reference to the embodiments described later in detail in conjunction with the accompanying drawings. In describing the present invention, when it is determined that a detailed description of a known function or configuration may unnecessarily flow the gist of the present invention, the detailed description thereof will be omitted. The terms to be described later are terms defined in consideration of structures, roles, functions, and the like in the present invention, which may vary according to intentions or customs of users and operators.

However, the present invention is not limited to the embodiments disclosed below but may be implemented in various forms. The present embodiments are merely provided to complete the disclosure of the present invention, and to fully inform the scope of the invention to those skilled in the art, and the present invention is described only in the claims. It is only defined by the scope of the claims. Therefore, the definition should be made based on the contents throughout the specification.

Throughout the specification, when a part is said to "include" a certain component, it means that it can further include other components, except to exclude other components unless otherwise stated.

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

1 is a perspective view of a temperature control apparatus for a switchboard according to an embodiment of the present invention, Figure 2 is a perspective view of a temperature control apparatus for a switchboard according to an embodiment of the present invention, Figure 3 according to an embodiment of the present invention 4 is a perspective view of a switchboard temperature control device according to an embodiment of the present invention, and FIG. 5 is a perspective view of a switchboard temperature control device according to an embodiment of the present invention.

Referring to these drawings, the switchboard temperature control apparatus 100 according to an embodiment of the present invention is a switchboard temperature control device 100 for controlling the temperature inside the enclosure mounted on the enclosure of the switchboard, the outside of the enclosure It is configured to include a thermoelectric module 110 is disposed, a heat exchange module 130 disposed in the interior of the housing, the annular circulation pipe 150.

The thermoelectric module 110 includes a thermoelectric element 111 having a heat generating surface 111A and a cooling surface 111B. The thermoelectric element is a semiconductor element using endotherm and heat generation by a known Peltier effect, and uses a PN junction made of a semiconductor such as bismuth and a tere compound (Bi2Te3). The thermoelectric element is a well-known element used for a conventional temperature control apparatus, and a detailed description is omitted. Both sides of the thermoelectric element are provided with a cooling surface 111B and a heating surface 111A, respectively, the heating surface 111A of the thermoelectric element 111 is provided with a heating block 113 provided with a plurality of cooling fins (P). The cooling surface 111B of the thermoelectric element 111 is provided with a cooling block 115 having a plurality of cooling fins P installed therein. An insulation panel may be formed between the heating block 113 and the cooling block 115. The thermoelectric module 110 configured as described above is disposed outside the enclosure.

Meanwhile, the heat exchange module 130 includes a housing 131 and a blowing fan 133 that sucks air in the enclosure and blows the air into the housing 131. The housing 131 accommodates a portion of the other side of the heat generating circulation pipe 151 and the other portion of the cooling circulation pipe 153 extending into the enclosure as described below. And, the housing 131 is formed with an air discharge port, when the air inside the housing flows into the housing 131 by the operation of the blower fan 133, the air and the other portion of the heat generating circulation pipe 151 and After passing through the other side portion of the cooling circulation pipe 153, the air is circulated back to the enclosure outside the housing 131 through the air outlet. As described later, a portion of the heat generating circulation pipe 151 and the cooling circulation pipe 153 passes through the housing 131 of the heat exchange module 130, and is disposed at one side of the blower fan 133. Specifically, as shown in FIG. 4, the heat generating circulation pipe 151-the cooling circulation pipe 153-the blowing fan 133 may be arranged in the order, and the cooling circulation pipe 153-the heat generating circulation pipe 151. It may be arranged in the order of the blowing fan (133). The heat exchange module 130 configured as described above is disposed inside the enclosure.

On the other hand, the annular circulation pipe 150 transmits the temperature between the thermoelectric module 110 and the heat exchange module 130 through the heat exchange medium flowing therein. The circulation pipe 150 includes a heat generating circulation pipe 151 extending over the heat generating block 113 and the heat exchanging module 130 of the thermoelectric module 110, a cooling block 115 and a heat exchanging module of the thermoelectric module 110. Consisting of a cooling circulation pipe 153 extending over 130. The heat generating circulation pipe 151 penetrates the wall surface 10 of the enclosure, one side of which extends to the outside of the enclosure and the other side of the enclosure to extend the inside of the enclosure, one part of the heat generation of the thermoelectric module 110 outside the enclosure The block 113 is disposed close to the heating surface 111A, and a portion of the other side passes through the housing 131 of the heat exchange module 130 inside the enclosure and is disposed at one side of the blower fan 133. On the other hand, the cooling circulation pipe 153 penetrates the wall surface 10 of the enclosure, one side of which extends to the outside of the enclosure and the other side of the interior of the enclosure, a portion of one side of the thermoelectric module 110 outside the enclosure Passing through the cooling block 115 is disposed close to the cooling surface (111B), a portion of the other side is disposed on one side of the blowing fan 133 through the housing 131 of the heat exchange module 130 inside the enclosure. In this case, the cooling circulation pipe 153 may be filled with cooling oil or refrigerant gas, and the heat generating circulation pipe 151 may be filled with heat medium oil. Accordingly, it is possible to maximize the heat exchange efficiency compared to the energy consumption.

Meanwhile, according to an embodiment of the present invention, at least one perforation 170 is formed on the wall surface 10 of the enclosure, and these circulation pipes 150 are wall surfaces 10 of the enclosure through the perforation 170. Penetrates. The heat generating circulation pipe 151 and the cooling circulation pipe 153 are arranged to penetrate the enclosure wall 10 through the perforation 170 and one side portion and the other side portion reach the thermoelectric module 110 and the heat transfer module, respectively. . In this case, the perforations 170 may be formed to have a size corresponding to the diameter of the heat generating circulation pipe 151 or the cooling circulation pipe 153. The circulation pipe 150 transfers heat of a high or low temperature of the thermoelectric module 110 to the heat exchange module 130 while the heat exchange medium circulates in the circulation pipe 150, and flows through the circulation pipe 150. It is necessary for the circulation pipe 150 to limit the contact area with air so that the temperature of the heat exchange medium can be maintained while the outer diameter of the circulation pipe 150 is preferably small in size. Accordingly, the perforations 170 may also be perforated small in size corresponding to the outer diameter of the circulation pipe 150. Conventionally, the perforated surface is processed on the wall surface 10 of the enclosure so that the temperature control device is mounted on the enclosure wall surface 10, but one side of the thermoelectric element 111 is installed inside the enclosure and the other side is exposed outside the enclosure. In this case, the housing wall 10 had to be perforated with a large area corresponding to the size of the temperature control device. On the contrary, according to the structure of the temperature control apparatus according to an embodiment of the present invention, which separates the thermoelectric module 110 and the heat exchange module 130 into separate components, and connects the modules through the circulation pipe 150, the enclosure It is enough to process only the perforation 170 to the wall surface 10 in a size small enough to penetrate the circulation pipe 150. Accordingly, there is no need to process the existing wide perforated surface has the advantage of easy installation.

Meanwhile, one side and the other side of the heating circulation pipe 151 and one side and the other side of the cooling circulation pipe 153 are connected to each other through the connector 180, respectively. In detail, a pair of heat generating circulation pipes 151 extend from the heat generating block 113 of the thermoelectric module 110 to the outside and extend through the perforations 170 to the interior of the enclosure wall 10. Is extended. In addition, the heat exchange module 130 also has a pair of exothermic circulation pipes 151 extending to the outside. The heat generating circulation pipe 151 on the thermoelectric module 110 side is connected to the heat generating circulation pipe 151 on the heat exchange module 130 side to form an integral circulation pipe 150 through which the heat exchange medium can be circulated. Connected via 180. Similarly, a pair of cooling circulation pipes 153 extend outward from the cooling block 115 of the thermoelectric module 110 and the extended pipes extend through the perforations 170 and into the enclosure wall 10. In addition, the pair of cooling circulation pipes 153 extend to the outside in the heat exchange module 130. The cooling circulation pipe 153 on the thermoelectric module 110 side is connected to the cooling circulation pipe 153 on the heat exchange module 130 side to form an integral circulation pipe 150 through which the heat exchange medium can be circulated. Connected via 180. According to this configuration, the temperature control of the present invention by simply connecting the circulation pipe of the heat exchange module 130 disposed inside the enclosure to the connector 180 after inserting the circulation pipe through the perforator 170 inside the enclosure. The device 100 can be installed. In addition, since the thermoelectric module 110 and the heat exchange module 130 are easily detachable by the connector 180, any one component can be easily replaced and replaced.

Meanwhile, the circulation pipe 150 may further include a pump P for forced circulation of the heat exchange medium and a valve V for controlling circulation.

On the other hand, the shape of one portion and the other portion of the circulation pipe 150 may adopt a curved structure of a plurality of times in order to maximize the contact area. Specifically, a portion of one side of the heat generating circulation pipe 151 may be curved in a plurality of times and disposed in parallel to the heat generating surface 111A of the thermoelectric element 111. Accordingly, when the heat generating surface 111A generates heat, the temperature of the heat generating surface 111A can be more efficiently transferred to the circulation pipe 150, and the temperature of the heat exchange medium of the circulation pipe 150 can be improved quickly. . In addition, the other side portion of the heat generating circulation pipe 151 may also be bent in a plurality of times and arranged in parallel to the blowing fan 133. Accordingly, since the air introduced into the heat exchange module 130 by the blowing fan 133 may be contacted over a large area of the heat generating circulation pipe 151, the cold air of the inlet air may be quickly generated. Similarly, one side portion of the cooling circulation pipe 153 is bent several times and arranged in parallel to the cooling surface 111B, and the other side portion of the cooling circulation pipe 153 is bent several times and parallel to the blowing fan 133. Can be arranged in parallel. Accordingly, in the cooling block 115 of the thermoelectric module 110, the temperature of the heat exchange medium is rapidly lowered, and in the heat exchange module 130, hot air of the inlet air can be quickly cooled.

On the other hand, the temperature control mechanism according to the temperature control apparatus 100 for the switchboard according to an embodiment of the present invention will be described.

When the inside of the enclosure is higher than the set temperature due to the heat generation of the electronic device, the internal air of the enclosure should be cooled. First, a current is supplied to the thermoelectric device (not shown) so that the cooling surface 111B of the thermoelectric element 111 is cooled. 111). When the cooling surface 111B of the thermoelectric element 111 is cooled, the heat is conducted to the cooling circulation pipe 153 near the cooling surface 111B to cool the heat exchange medium. The control unit operates the pump P installed in the cooling circulation pipe 153 to circulate the heat exchange medium in the interior of the enclosure. The heat exchange medium moves to the heat exchange module 130 through the cooling circulation pipe 153, and in the heat exchange module 130, the blower fan 133 is operated to draw air inside the housing into the housing 131 of the heat exchange module 130. Inflow to The introduced high-temperature air is discharged out of the housing 131 after the temperature decreases while contacting the cooling circulation pipe 153, and thus the internal temperature of the enclosure may decrease. The heat exchange medium that transfers heat to the high temperature air circulates to the cooling block 115 outside the enclosure while the temperature rises, and the cooling fins P installed on the cooling block 115 radiate the elevated temperature of the heat exchange medium to the outside. Let's do it.

On the contrary, when the inside of the enclosure is lower than the set temperature due to the external environment, the internal air of the enclosure must be generated. First, a current is applied to the thermoelectric element 111 so that the heat generating surface 111A of the thermoelectric element 111 is generated by the controller. do. When the heat generating surface 111A of the thermoelectric element 111 generates heat, the heat is conducted to the heat generating circulation pipe 151 near the heat generating surface 111A to generate heat exchange medium. The control unit operates the pump P installed in the heat generating circulation pipe 151 to circulate the heat exchange medium in the interior of the enclosure. The heat exchange medium moves to the heat exchange module 130 through the heat generating circulation pipe 151, and in the heat exchange module 130, the blower fan 133 is operated to draw air inside the enclosure into the housing 131 of the heat exchange module 130. Inflow to The introduced low temperature air is discharged out of the housing 131 after the temperature is raised while contacting the exothermic circulation pipe 151, thereby increasing the internal temperature of the enclosure. The heat exchange medium is circulated to the heating block 113 side outside the enclosure again, the cooling fins (P) installed in the heating block 113 heats the temperature of the heat exchange medium to the outside. In this case, a cooling fan is installed in the heat generating block 113 to forcibly introduce external air to the heat generating block 113 to increase the cooling efficiency of the heat generating block 113.

On the other hand, it will be described a dehumidification mechanism according to the switchboard temperature control apparatus 100 according to an embodiment of the present invention. When the humidity inside the enclosure is higher than the set humidity, both the valve V of the exothermic circulation pipe 151 and the valve V of the cooling circulation pipe 153 are opened and the pump P is operated to operate the thermoelectric module 110. The heated heat exchange medium of the exothermic circulation pipe 151 and the cooled heat exchange medium of the cooling circulation pipe 153 are transferred to the heat exchange module 130 through the respective pipes. Accordingly, the heat-exchanging medium that is heated and cooled is circulated in the exothermic circulation pipe 151 and the cooling circulation pipe 153 passing through the housing 131 of the heat exchange module 130, respectively. At this time, the blower fan 133 is driven to suck air from the outside of the housing into the housing or vice versa to sequentially contact the exothermic circulation pipe 151 and the cooling circulation pipe 153. For example, as shown in FIG. 4, when the heat exchange module 130 is arranged in the order of the exothermic circulation pipe 151, the cooling circulation pipe 153, and the blower fan 133, the blower fan 133 may be driven to Allow air to exit the housing. On the contrary, when the heat exchange module 130 is arranged in the order of the cooling circulation pipe 153-the heat generating circulation pipe 151-the blowing fan 133, the blower fan 133 is driven to allow air to flow into the housing. . In this process, the hot air passing through the exothermic circulation pipe 151 first condenses while passing through the cooling circulation pipe 153, thereby lowering the humidity.

As mentioned above, although embodiment of this invention was described, the person of ordinary skill in the art should add, change, delete, add, etc. the component within the range which does not deviate from the idea of this invention described in the claim. The present invention may be modified and changed in various ways, and it should be understood that the present invention is included in the scope of the present invention.

100: temperature control device for the switchboard 110: thermoelectric module
111: thermoelectric element 113: heat generating block
115: cooling block 130: heat exchange module
131: housing 133: blowing fan
150: circulation pipe 151: heat generating circulation pipe
153: cooling circulation pipe 170: perforation
180: connector

Claims (4)

A temperature control device for a switchboard mounted on the enclosure of the switchboard and controlling the temperature inside the enclosure.
A thermoelectric module disposed outside of the enclosure, the thermoelectric element having a heat generating surface and a cooling surface, a heat generating block including a cooling fin attached to the heat generating surface of the thermoelectric element, and attached to the cooling surface of the thermoelectric element. A thermoelectric module including a cooling block including a cooling fin;
A heat exchange module disposed inside the enclosure, the heat exchange module comprising a blowing fan configured to suck the air inside the enclosure and blow the air into the housing; And
An annular circulation pipe that transfers a temperature between the thermoelectric module and the heat exchange module through a heat exchange medium flowing therein, which extends across the heat generating block of the thermoelectric module and the heat exchange module to heat high temperature heat of the thermoelectric module. A circulation pipe including an exothermic circulation pipe for transferring to the heat exchange module, and a cooling circulation pipe extending over the cooling block of the thermoelectric module and the heat exchange module to transfer low temperature heat of the thermoelectric module to the heat exchange module;
Including,
At least one perforation is formed on the wall of the enclosure, and the circulation pipe passes through the wall of the enclosure through the perforation.
The perforated part is formed in a size corresponding to the diameter of the heat generating circulation pipe or the cooling circulation pipe,
Temperature controller for switchboard. The method of claim 1,
The heat generating circulation pipe, a portion of one side is disposed close to the heating surface by passing through the heating block of the thermoelectric module, a portion of the other side is disposed on one side of the blower fan through the housing of the heat exchange module,
The cooling circulation pipe, a portion of one side is disposed close to the cooling surface by passing through the cooling block of the thermoelectric module, and the other side is disposed on one side of the blower fan through the housing of the heat exchange module. doing,
Temperature controller for switchboard. The method of claim 2,
One side and the other side of the heat generating circulation pipe, one side and the other side of the cooling circulation pipe is characterized in that connected to each other through a connector,
Temperature controller for switchboard. The method of claim 2,
The one side portion of the exothermic circulation pipe is bent a plurality of times arranged in parallel to the heating surface, the other portion of the exothermic circulation pipe is bent several times and arranged in parallel to the blowing fan,
The one side portion of the cooling circulation pipe is bent a plurality of times arranged in parallel to the cooling surface, the other portion of the cooling circulation pipe is bent several times, characterized in that arranged in parallel to the blowing fan,
Temperature controller for switchboard.

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