KR101715052B1 - Distribution box of cooling and dampproof - Google Patents

Abstract

According to the present invention, a cooling and moisture-proof distribution box (90) comprises: a box-shaped main body (100); an upper linear motor (300); a thermoelectric element (400); a cooling fin (501) and a heat radiating fin (503); a cooling fan (505) and a heat radiating fan (507); opening and closing holes (120, 130); and doors (701, 703). When the heat generated in a control unit (200) inside the main body (100) reaches a predetermined temperature or higher, the cooling and moisture-proof distribution box cools the inside of the main body (100), thereby improving efficiency.

Description

Distribution box of cooling and dampproof

More particularly, the present invention relates to a cooling / damping power distribution cabinet, and more particularly, to a cooling / damping cabinet that is capable of rapidly cooling a cabin when a predetermined amount of heat is generated in the cabinet, So that safety is ensured. 2. Description of the Related Art

Hereinafter, the distribution cabinet 1 according to the background art will be described with reference to the accompanying drawings.

Fig. 1 is a cross-sectional view showing a distribution box according to the background art.

Generally, the cabinet 1 is box-shaped and configured to receive a control section 20 for controlling power. The control unit 20 includes a legend leg ratio of a high-voltage transformer and a current transformer for a meter.

When the high temperature occurs, the controller 20 melts the contact portions of the connected cable terminals to cut off the power, and the efficiency of the control portion 20 is lowered and the accuracy of the output voltage is deteriorated There was a problem that a fire occurred.

In order to prevent such a phenomenon, in the background art, the top plate 30 of the cabinet 1 is formed with a through-hole 33 larger than the width of the cabinet 1. And a lid 40 covering the upper plate 30. The lid 40 is in the form of a container with its bottom opened. A space 50 is formed between the lid 40 and the top plate 30.

1, the air outside the cabinet 1 is received in the space 50 through the through-hole 33, then flows into the cabinet 1 again to be heat-exchanged with the control unit 20, And is exhausted to the outside of the cabinet 1 through the space 50, so that the heat inside the cabinet 1 is cooled.

However, according to the background art, when the cabinet 1 is installed outdoors, the cooling effect can not be expected in the summer season. This is because the effect of heat exchange can not be expected largely even if the outside air flows into the main body of the cabinet 1 in a state of approaching 35 ° C or more.

In addition, when the cabin 1 is installed in the outdoors, condensation occurs in the cabin 1 due to the temperature difference between the inside and outside of the cabin 1. The condensation becomes water droplets over time, There is a problem in that a short circuit accident occurs.

Korean Utility Registration No. 20-0411963 (March 14, 2006)

The cooling and moisture-evacuating distribution box according to the present invention is intended to solve the following problems.

First, since the inside of the cabinet is cooled when the heat of the control section generated in the cabinet becomes the predetermined temperature or higher, the efficiency of the control section is improved and the accuracy (accuracy) of the output voltage is improved, The contact portion of the terminal is melted and separated by the heat of the predetermined temperature or more, thereby preventing a short circuit accident.

Second, since condensation occurs inside the power distribution box, the condensation becomes water droplets over time and falls into the control unit, thereby preventing a short-circuit accident from occurring.

The cooling / moisture-evacuating distribution box according to the present invention is configured as follows to solve the above-described problems.

An upper linear motor supported on the inner upper surface of the main body so as to reciprocate toward both sides of the main body; and a thermal motor mounted on the guider, the cooling surface and the heat generating surface facing the reciprocating direction of the guider, A cooling fan and a heat dissipation fan attached to the cooling fin and the heat dissipation fin respectively, and a cooling fan and a heat dissipation fan attached to the cooling fan and the heat dissipation fan, respectively, And a door that opens and closes the opening and closing port.

The guide rails are disposed on opposite sides of the door, and have a cross-sectional shape. A rod fixed to the door is moved up and down. And an attached lower linear motor.

And a control unit for receiving an abnormal signal from the temperature sensor and the humidity sensor to drive the upper linear motor and the lower linear motor and to connect power to the thermoelectric element, do.

In addition,

The temperature sensor senses that the temperature inside the main body is equal to or higher than a specified value and sends an abnormal signal, connects power to the thermoelectric element, the cooling fan, and the heat radiation fan after receiving the abnormal signal, And the upper linear motor is operated to move the guider toward the opening and closing port on one side so that the radiating fan and the radiating fin are exposed through the opening and closing port, Cooling fan and the heat-dissipating fan, and the upper linear motor is operated so that the heat-dissipating fan and the heat-dissipating fin are separated from the opening and closing port, and when the abnormality signal is not transmitted from the temperature sensor, And the door is programmed to close the door,

Wherein the humidity sensor senses that the humidity inside the main body is equal to or higher than a predetermined value and sends an abnormal signal, connects the power source to the thermoelectric element, the cooling fan, and the heat radiation fan after receiving the abnormal signal, And the upper linear motor is operated to move the guider toward the open / close port of the opened counterpart so that the cooling fan and the cooling fin are exposed through the opening / closing port, The cooling fan, and the heat-dissipating fan, and the upper linear motor is operated so that the cooling fan and the cooling fin are separated from the opening and closing port, And the motor is operated so that the door is programmed to close the door.

The cooling and moisture-proof distribution cabinet according to the present invention has the following effects.

First, since the inside of the main body is cooled when the heat generated in the control portion inside the main body becomes the predetermined temperature or more, the efficiency is improved and the accuracy (accuracy) of the output voltage is improved. There is an effect that the occurrence of a short circuit accident can be prevented because the contact portion is melted and separated by heat above a prescribed temperature.

Secondly, since condensation occurs in the interior of the main body, the condensation becomes a droplet as time passes and falls to the control unit, thereby preventing a short-circuit accident from occurring.

1 is a sectional view showing a distribution box according to the background art;
2 is a cross-sectional view showing a cooling and moisture-proof distribution cabinet according to the present invention;
Fig. 3 is a local perspective view showing a state in which a door configured by the door for cooling and moisture-proofing distribution according to the present invention is opened by a door.
4 is a partial sectional view showing a state in which a heat radiating fan is exposed in a state where one of openings of both sides of the cooling and moisture-proof distribution cabinet according to the present invention is open.
Fig. 5 is a partial sectional view showing a state in which a cooling fan is exposed in a state in which the opposite side of the opening / closing ports on both sides of the cooling / damping distribution cabinet according to the present invention is open;

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention.

FIG. 2 is a cross-sectional view showing a cooling and moisture-proof distribution cabinet according to the present invention, FIG. 3 is a local perspective view showing a state in which a door formed in the cooling and moisture- FIG. 5 is a partial sectional view showing a state in which a heat radiating fan is exposed in a state where one of openings of both sides of a moisture-proof power distribution box is opened; FIG. 5 is a cross- Together with a sectional view showing a state in which the cooling fan is exposed.

Generally, the power distribution box is box-shaped and includes a main body 100 having a door (not shown) formed therein for receiving the control unit 200, such as a high-voltage transformer or a current transformer for a meter.

According to the present invention, it is possible to prevent a phenomenon in which efficiency is lowered by supplying cool air when a predetermined temperature or more is detected in the main body 100, and to prevent a short-circuit accident caused by condensation by supplying warm air when humidity above a predetermined level is detected .

To this end, the cooling / dampening distribution cabinet 90 according to the present invention is configured as follows.

The upper linear motor 300 is configured to be supported on the inner upper surface of the main body 100 and to reciprocate the guider 320 to both sides. The upper linear motor 300 has a structure in which a guider 320 is reciprocated in the longitudinal direction of the body 310 at a lower portion of a block shaped body 310 elongated in left and right directions, .

The thermoelectric element 400 is mounted on the guider 320 and has a cooling surface 410 and a heat generating surface 420 facing the reciprocating direction of the guider 320. The thermoelectric element 400 is generally heated to a high temperature on the heat generating surface 420 and a low temperature on the cooling surface 410 due to the supply of electricity.

The cooling fan 501 and the radiating fin 503 are attached to the cooling surface 410 and the heating surface 420 respectively and the cooling fan 505 attached to the cooling fin 501 and the radiating fin 503, And a heat radiating fan 507 are constituted.

The cooling fan 505 and the cooling fan 501 are connected to the cooling fan 505 and the heat dissipation fan 507. The cooling fan 505, the cooling fin 501, the heat dissipation fan 507, 100 and 120, 130, respectively.

In addition, plate-like doors 701 and 703 for opening and closing the open / close ports 120 and 130 are formed, respectively. The doors 701 and 703 are vertically moved upward and downward while being in close contact with the inner side surface 110 of the main body 100 and open and close the opening and closing ports 120 and 130. The doors 701 and 703 are provided on both sides of the doors 701 and 703 S are inserted into the guide rails 600 so as to be able to move up and down and disposed on both sides of the openings 120 and 130 so that the doors 701 and 703 can be elevated without being detached. FIG. 3 shows a door 701 and a guide rail 600 on one side of the door 120 disposed on one side in FIG. 2, and the opening and closing port 130 of the other side is configured similarly.

The rods 803 and 807 fixed to the doors 701 and 703 move up and down to constitute lower linear motors 801 and 805 attached to the inner surface 110 of the main body 100. Therefore, since the rods 803 and 807 are lifted and lowered by electric signals, the doors 120 and 130 can be opened and closed by the doors 701 and 703.

A temperature sensor T and a humidity sensor D attached to the inner surface 110 of the main body 100 are configured to receive an abnormal signal from the temperature sensor T and the humidity sensor D, A controller (not shown) for driving the upper linear motor 300 and the lower linear motors 801 and 805 and connecting power to the thermoelectric elements 400 is formed.

The control unit (not shown) is programmed as follows.

When the temperature sensor T senses that the temperature inside the main body 100 is higher than the specified value and sends an abnormal signal, the thermoelectric element 400, the cooling fan 505, And the fan 507 is connected to the power source. The lower linear motor 801 is operated to open the door 701 on one side corresponding to the heat radiation fan 507 and to operate the upper linear motor 300 to rotate the guider 320 The heat radiating fan 507 and the radiating fin 503 are exposed to the opening and closing port 120 by moving the radiating fan 507 and the radiating fin 503 toward the opening and closing port 120. In this state, when the abnormality signal is not transmitted from the temperature sensor T, the power is turned off to the thermoelectric element 400, the cooling fan 505, and the heat radiation fan 507, and the upper linear motor 300 is operated The heat radiating fan 507 and the radiating fin 503 are separated from the opening and closing port 120 and the lower linear motor 801 is operated so that the door 701 closes the opening and closing port 120.

When the humidity sensor D detects that the humidity inside the main body 100 is higher than the specified value and sends an abnormal signal, the thermoelectric device 400, the cooling fan 505, And the fan 507 is connected to the power source. The lower linear motor 805 is operated to open the door 703 on the opposite side corresponding to the cooling fan 505 to operate the upper linear motor 300 to move the guider 320 to the open side So that the cooling fan 505 and the cooling fin 501 are exposed to the opening and closing port 130. If no abnormality signal is sent from the humidity sensor D in this state, the power is turned off to the thermoelectric element 400, the cooling fan 505 and the heat radiation fan 507, and the upper linear motor 300 is operated The cooling fan 505 and the cooling pin 501 are released from the opening and closing port 130 and the door 703 is programmed to close the opening and closing port 130 by operating the lower linear motor 805 .

The operation sequence of the cooling / damping distribution cabinet 90 according to the above embodiment will be described as follows.

 As shown in FIG. 2, when the doors 701 and 703 are closed on both sides of the doors 120 and 130, a load is applied to the control unit 200 and the inside of the main body 100 If excessive heat is generated above the specified temperature, the temperature sensor T senses this and sends an abnormal signal to the control unit (not shown).

Then, the controller applies electricity to the thermoelectric element 400, the cooling fan 505, and the heat radiation fan 507, and drives the lower linear motor 801 on the side corresponding to the heat radiation fan 507 The load 803 is lowered so that the door 701 opens the door 120 corresponding to the heat radiation fan 507.

Next, the upper linear motor 300 is operated to move the guider 320 toward the open / close opening 120, so that the heat radiation fan 507 is moved to the outside of the main body 100 through the opening / So that the heat dissipation fin 503 is allowed to escape to the outside of the main body 100.

Accordingly, the cooling fin 501 is cooled to a low temperature (0 ° C to 10 ° C) through the cooling surface 410 of the thermoelectric element 400. When the cooling fan 505 is rotated, Is circulated, and is cooled to a low temperature while contacting the cooling fin 501. As a result, the efficiency of the control unit 200 due to overheating deteriorates, the degree of accuracy of the voltage decreases, and the contact portions of the cable terminals connected to the control unit 200 are melted and separated by heat of a predetermined temperature or more, Can be prevented. The heat generated by the heat generating surface 420 of the thermoelectric element 400 is rapidly dissipated to the outside by the heat dissipation fan 507 and the heat dissipation fin 503 while being out of the body 100 So that the cooling efficiency of the cooling surface 410 is improved.

When the temperature of the inside of the main body 100 drops to the predetermined temperature after the air is cooled in this state, the temperature sensor T does not send an abnormal signal. The operation of the thermoelectric element 400, the cooling fan 505 and the heat radiation fan 507 is stopped and the upper linear motor 300 is operated to move the guider 320 in the reverse direction, , So that the radiating fin 503 is released from the opening / closing port 120. Then, the lower linear motor 801 is operated so that the door 701 closes the opening / closing part 120.

As shown in FIG. 2, when the doors 701 and 703 are closed with the door openings 120 and 130 on both sides, if the indoor air contains excessive steam exceeding a predetermined value in the air, (D) sends an abnormal signal to the control unit (not shown).

Then, the controller applies electricity to the thermoelectric element 400, the cooling fan 505, and the heat radiation fan 507, and drives the lower linear motor 805 on the side corresponding to the cooling fan 505 The door 803 is lowered so that the door 703 opens the door 130 corresponding to the cooling fan 505.

Next, the upper linear motor 300 is operated to move the guider 320 toward the open / close port 130, so that the cooling fan 505 and the cooling fin 501 can be guided through the opening / (100).

The heat dissipation fin 503 is heated to a high temperature (50 to 80 deg. C) through the heating surface 420 of the thermoelectric element 400 and the heat dissipation fin 503 is heated by the rotation of the heat dissipation fan 507, The air inside the main body 100 is circulated so that the condensation formed on the inner surface 110 of the main body 100 becomes steam and is exhausted to the outside because the air is heated to a high temperature while the radiating fins 503 are in contact with each other. At this time, it is a matter of course that the exhaust of steam is exhausted through a fan (not shown) installed in the main body 100. As a result, dew condensation occurs in the cabin during the winter season, so that water droplets are dropped over time, and thus the occurrence of a short circuit accident can be prevented.

At this time, the cooling fan 505 and the cooling fin 501 heat exchange the cooling surface 410 of the thermoelectric element 400 with the outside air from the outside of the main body 100, so that the heat efficiency of the heat generating surface 420 So that the degradation phenomenon can be prevented.

When the condensation is heated in this state and the humidity inside the main body 100 falls to a specified value, the humidity sensor D does not send an abnormal signal. Then, the operation of the thermoelectric element 400, the cooling fan 505 and the heat radiation fan 507 is stopped, and the upper linear motor 300 is operated to move the guider 320 to the original position, (505) and the cooling fin (501) are separated from the opening / closing port (130). Then, the lower linear motor 805 is operated so that the door 703 closes the opening / closing part 130.

According to the present invention, since the inside of the main body 100 is cooled when the heat generated in the controller 200 inside the main body 110 reaches a predetermined temperature or more, It is possible to prevent the occurrence of a short circuit accident because the degree of accuracy of voltage is improved and the contact portion of the cable terminal connected to the water distribution equipment is melted and separated by the heat of the predetermined temperature or more. In addition, since condensation is generated in the main body 100, the condensation becomes water droplets over time and falls to the control unit, thereby preventing a short circuit accident.

The embodiments and the accompanying drawings described in the present specification are merely illustrative of some of the technical ideas included in the present invention. Therefore, it is to be understood that the embodiments disclosed herein are not for purposes of limiting the technical idea of the present invention, but are intended to be illustrative, and therefore, the scope of the technical idea of the present invention is not limited by these embodiments. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

90: Cooling and desiccant distribution cabinet 100:
120, 130: access door 200:
300: upper linear motor 320: guider
400: thermoelectric element 410: cooling face
420: heat generating surface 501: cooling pin
503: radiating fin 505: cooling fan
507: heat dissipating fan 600: guide rail
701, 703: door 801, 805: lower linear motor
T: Temperature sensor D: Humidity sensor

Claims (4)

delete A main body 100 configured to receive the control unit 200 in a box shape,
An upper linear motor 300 supported on an inner upper surface of the main body 100 and configured to reciprocate the guider 320 to both sides,
A thermoelectric element 400 mounted on the guider 320 and having a cooling surface 410 and a heat generating surface 420 facing the reciprocating direction of the guider 320,
A cooling fin 501 and a cooling fin 503 attached to the cooling surface 410 and the heating surface 420,
A cooling fan 505 and a heat radiating fan 507 attached to the cooling fin 501 and the radiating fin 503,
Openings 120 and 130 corresponding to the cooling fan 505 and the heat radiating fan 507 and passing through the main body 100 so that the cooling fan 505 and the heat radiating fan 507 can pass therethrough,
And door (701, 703) for opening and closing the door (120, 130)
Guide rails 600 disposed on both sides of the open / close ports 120 and 130 and having a cross-sectional shape, and guide rails 600 disposed on both sides of the open / close ports 120 and 130 to guide the both sides S of the doors 701 and 703,
And the lower linear motors 801 and 805 attached to the inner side surface 110 of the main body 100 as the rods 803 and 807 fixed to the doors 701 and 703 move up and down. Cooling dehumidification power distribution box. 3. The method of claim 2,
A temperature sensor T and a humidity sensor D attached to the inner surface 110 of the main body 100,
The thermoelectric device 400 receives the abnormal signal from the temperature sensor T and the humidity sensor D and drives the upper linear motor 300 and the lower linear motors 801 and 805 to drive the thermoelectric device 400, And a control unit (not shown) for connecting power to the heat-dissipating fan 507. The method of claim 3,
The control unit (not shown)
When the temperature sensor T senses that the temperature inside the main body 100 is higher than the specified value and sends an abnormal signal, the thermoelectric element 400, the cooling fan 505, The power is connected to the fan 507 and the lower linear motor 801 is operated to open the door 701 at one side corresponding to the heat radiating fan 507 to operate the upper linear motor 300, The radiator fan 507 and the radiating fin 503 are exposed to the opening and closing port 120 by moving the guider 320 toward the opening and closing port 120 on one side of the opened one. The cooling fan 505 and the heat dissipation fan 507 are turned off and the upper linear motor 300 is operated so that the heat dissipation fan 507 and the heat dissipation fin 503 are operated, (120), and the lower linear motor (801) is operated The door 701 is programmed to close the door 120,
When the humidity sensor D detects that the humidity inside the main body 100 is higher than the specified value and sends an abnormal signal, the thermoelectric device 400, the cooling fan 505, The upper linear motor 300 is operated by connecting the power source to the fan 507 and operating the lower linear motor 805 to open the door 703 on the opposite side corresponding to the cooling fan 505, The cooling fan 505 and the cooling fin 501 are exposed to the opening and closing port 130 by moving the guider 320 toward the opening and closing port 130 of the opened counterpart. The cooling fan 505 and the heat radiating fan 507 are turned off and the upper linear motor 300 is operated so that the cooling fan 505, 501) is released from the opening / closing port (130), and when the lower linear motor (805) is operated Standing the door 703 to cool moisture-proof cabinet, characterized in that the program to close the aperture 130.

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