KR200460377Y1 - A air cooling device for preventing the transformer from overheating - Google Patents

Abstract

The present invention relates to an air cooling device (200) for preventing overheating of a ground transformer, comprising: a cap (201); a cap support (202) for supporting the cap (201); A metal mesh 203 fastened to the cap support 202; And a lower support table 204 to be fastened to the metal mesh 203. The cap support 202 has fastening means at its lower portion to be coupled with the metal mesh 203, The upper part of the metal mesh 203 is coupled to the cap support 202 and the lower part of the metal mesh 203 is connected to the upper support 204. The ground metal A heat cooler 300 for releasing the metal mesh 203 to the outside is coupled to an inner surface of the metal mesh 203 and an upper portion of the metal mesh 203 is coupled to the metal mesh 203, And the lower portion of the lower support 204 is fastened to the outer housing 101 of the ground-level transformer.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an air cooling device for preventing overheating of a ground transformer,

The present invention relates to an air cooling device for preventing overheating of a ground transformer, and more particularly, to an air cooling device for preventing overheating of a ground transformer, To an air cooling apparatus for preventing overheating of a ground-type transformer for efficiently discharging the air to the atmosphere.

Generally, a ground transformer is a facility installed on the ground to supply electricity to a consumer using electricity. These ground transformers consist of a high-voltage primary coil wound around a steel wire, a secondary coil for low-voltage, insulating oil filled in the high-voltage coil and low-voltage coil gap, a transformer inner housing surrounding the primary coil and insulating oil, And an outer housing. The insulating oil filled inside the transformer functions to maintain the electrical insulation inside the transformer. Conventional ground transformers transmit the heat generated during the transforming process of the high-voltage coil and the low-voltage coil to the inner housing of the transformer by receiving the insulating oil. The heat transferred to the inner housing is then transferred to the outer housing by the convection of the air present in the space between the inner housing and the outer housing to release heat from the outer housing to the atmosphere. However, in the conventional ground transformer, the heat transfer efficiency in which the heat generated in the transforming process due to the overload operation of the ground transformer is discharged to the outside becomes low, and the performance of the transformer itself, which converts the pressure of the current from high pressure to low pressure, , There is a problem that the transformer is overheated and explodes in severe cases.

In addition, as the heat generated in the transforming process exceeds the limit temperature of the transformer due to the overload operation of the transformer, or the performance of the insulating oil decreases over time, the insulating oil, which receives the heat generated in the transforming process, The heat transfer rate for transferring heat to the housing is significantly reduced. As the heat transfer rate of the insulating oil is reduced, there has been a problem that the insulating oil flows out of the inner housing of the transformer to reduce the performance of the transformer itself. Furthermore, as the transformer rises above the limit temperature of the insulating oil due to the heat generated during the transforming process, there is a problem that the insulating oil is vaporized into gas, thereby increasing the risk of explosion of the transformer.

Furthermore, breakdown or explosion of a transformer can lead to electrostatic charge to the electrical consumer, increase the risk of fire if the transformer explodes, and cause problems such as a lot of time, manpower and repair costs to recover normally from a broken or exploded transformer. . Especially, since the ground transformer is installed on the ground, the frequent breakdown of the transformer and the risk of explosion are frequently occurred in the summer due to accumulation of heat and radiant heat generated in the transformation process of the ground transformer itself.

The object of the present invention is to solve the above problems, and it is an object of the present invention to efficiently heat the heat generated from the insulating oil filled in the ground transformer for the insulation of the heat and the ground transformer generated during the transforming process of the ground transformer And to provide an air cooling device for preventing overheating of the ground transformer which can reduce the normal recovery cost and time of the transformer by increasing the efficiency of the transformer.

In order to achieve the object of the present invention, an air cooling apparatus for preventing overheating of a ground transformer according to the present invention comprises a cap; a cap support for supporting the cap; A metal mesh secured to the cap support; And a lower support to be fastened to the metal net, wherein the cap support has a fastening means to be coupled to the metal net at a lower portion thereof, the upper portion of the metal net is coupled to the cap support, And a heat cooler for discharging the heat of the ground-type transformer to the outside is coupled to the inner surface of the metal net, and the upper support is connected to the metal net And the lower portion of the lower support is fastened to the outer housing of the ground-level transformer by fastening means.

Further, in a preferred embodiment of the air cooling device for preventing overheating of the ground transformer according to the present invention, the heat cooler has a cavity heat pipe, and one side of the heat pipe extends beyond the outer housing of the ground transformer The other end of the heat pipe may include a heat radiating plate extending in the longitudinal direction of the metal net to discharge heat.

In another preferred embodiment of the air cooling device for preventing overheating of the ground transformer according to the present invention, the heat pipe is coated with a porous material on the inner wall surface to facilitate heat absorption and heat release, The inside of the pipe can be filled with methanol, acetone, sodium, or mercury.

In another preferred embodiment of the air cooling device for preventing overheating of the ground transformer according to the present invention, the coupling means of the cap supporter and the metal net includes a cap support tightening hole formed in the lower part of the cap supporter, The upper screw hole of the metal mesh can be fastened by the metal mesh upper screw.

In another preferred embodiment of the air cooling device for preventing overheating of the ground transformer according to the present invention, the fastening means of the metal net and the lower supporter includes a metal mesh lower screw hole formed in the lower portion of the metal net, The lower support pin tightening hole formed on the upper part of the support can be fastened by the metal net lower fastening screw.

In another preferred embodiment of the air cooling device for preventing overheating of the ground transformer according to the present invention, the lower support and the fastening means of the outer housing of the ground transformer are provided with a lower support screw hole And the outer housing can be fastened by a lower support screw tightening screw.

The present invention proposes an air cooling device according to the present invention at the top of a ground transformer, discharges the heat generated in the transforming process to the atmosphere outside the outer housing of the transformer by using a natural convection phenomenon caused by a temperature difference, There is an effect of saving power. In addition, by appropriately discharging the heat generated in the transforming process to the outside, the ground transformer is cooled to prevent breakdown or explosion of the transformer due to overheating, thereby saving time, manpower, and cost required to recover the ground transformer There is an effect that can be. Furthermore, by increasing the efficiency of the ground transformer, it is possible to reduce consumption of fossil fuel consumed for producing electric power, and at the same time to reduce the amount of generated carbon dioxide, thereby contributing to environmental protection.

1 is a front view of a ground transformer in a state in which an air cooling device for preventing overheating of the ground transformer according to the present invention is installed.
2 is an exploded perspective view of an air cooling device for preventing overheating of a ground transformer according to the present invention.
FIG. 3 shows a state in which an air cooling device for preventing overheating of the ground transformer according to the present invention is coupled.
4 shows a heat flow diagram between an inner housing and an outer housing of a ground transformer having an air cooling device according to the present invention.
5 schematically shows a heat transfer process of the heat cooler in the air cooling apparatus for preventing overheating of the ground-type transformer according to the present invention.

Preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, like reference numerals are used to refer to like elements throughout.

FIG. 1 is a front view of a ground transformer 100 in a state where an air cooling apparatus 200 for preventing overheating of the ground transformer according to the present invention is installed. FIG. 2 is a top view of the ground transformer 100 according to the present invention. Which is an exploded perspective view of the air cooling apparatus 200 for preventing the air cooling apparatus 200 from being damaged. 3 shows a state in which the air cooling apparatus 200 for preventing overheat of the ground transformer 100 according to the present invention is coupled. The air cooling apparatus 200 for preventing overheating of the ground transformer according to the present invention comprises a cap 201, a cap support 202, a metal mesh 203, and a lower support 204.

The cap 201 is disposed on top of the cap support 202 and is preferably formed integrally with the cap support 202, although not necessarily limited thereto. On the other hand, the cap 201 may be formed separately from the cap support 202. In this case, the cap 201 and the cap support 202 may be fastened by fastening means, for example bolts, adhesives, welding, or the like. The cap 201 is preferably in the shape of a cap and has both ends of the cap extending beyond both ends of the cap support 202 to prevent rainwater from flowing into the ground transformer 100 when it rains do. In addition, foreign matter such as dust can be prevented from flowing into the ground transformer 100 by the cap 201, thereby preventing the failure or efficiency of the ground transformer 100 from being reduced.

The cap support 202 may be formed separately from or integrally with the cap 201 and fastening means for coupling with the metal mesh 203 may be formed on the lower portion of the cap support 202. Such fastening means may be bolted, adhesive, welded, or the like. 3, in the preferred embodiment of the air cooling device 200 for preventing overheating of the ground transformer 100 according to the present invention, the fastening means of the cap support 202 and the metal mesh 203 are arranged in the cap The cap support clamping hole 205 formed in the lower portion of the support base 202 and the metal screw upper hole 206 formed in the upper portion of the metal mesh 203 can be fastened by the metal mesh upper fastening screw 210.

It is preferable that the metal mesh 203 of the air cooling apparatus 200 according to the present invention has a plurality of vent holes on the circumferential surface. An upper portion of the metal mesh 203 is coupled to the cap support 202 by fastening means and a lower portion of the metal mesh 203 is coupled to the lower support 204 by fastening means. A heat cooler 300 for discharging the heat generated in the process of transforming the ground transformer 100 and the heat generated by direct sunlight from the ground transformer outer housing 101 to the atmosphere is attached to the inner surface of the metal net 203 do. The fastening means of the metal net 203 and the lower support 204 can be formed by bolt threading, adhesive, welding or the like. 3, in another preferred embodiment of the air cooling apparatus 200 for preventing overheating of the ground transformer 100 according to the present invention, the fastening means of the metal net 203 and the lower support 204 The metal mesh lower screw hole 207 formed in the lower part of the metal mesh 203 and the lower support metal tightening hole 208 formed in the upper part of the lower support 204 can be fastened by the metal mesh lower fastening screw 211.

The upper portion of the lower support 204 is fastened to the lower portion of the metal mesh 203 by fastening means and the lower end of the lower support 204 is fastened to the outer housing 101 of the ground- The heat generated in the transforming process of the ground transformer 100 is transmitted to the inner housing 102 of the ground transformer through the insulating oil and the heat transferred to the inner housing is transferred to the outer housing 101 of the ground transformer by convection Therefore, in a preferred embodiment of the present invention, the lower support 204 is fastened to the upper end of the ground transformer 100, and the upper end of the ground transformer 100 has a vent corresponding to the length of the metal mesh 203 Respectively. The fastening means of the lower support 204 and the outer housing 101 of the ground transformer may be formed by bolt threading, adhesive, welding, or the like. 3, in the preferred embodiment of the air cooling apparatus 200 for preventing overheating of the ground transformer 100 according to the present invention, the lower support 204 and the outer housing 101 of the ground transformer are fastened The lower support bracket 204 is formed by fastening the lower support bracket screw hole 209 formed at the lower ends of the lower support bracket 204 and the outer housing 101 with the lower support bracket tightening screw 212.

Fig. 4 shows a heat flow diagram between the inner housing 102 and the outer housing 101 of the ground-top transformer provided with the air cooling apparatus 200 according to the present invention. Since the heat generated in the transforming process of the ground transformer heats the air between the inner housing and the outer housing of the ground transformer and the heated air flows upward from the inside of the outer housing of the ground transformer, It is not easy to discharge the heat generated by the transforming process of the ground transformer 100 and the direct sunlight from the outer housing 101 of the ground-top transformer to the atmosphere. Since the air cooling apparatus 200 for preventing overheating of the ground transformer according to the preferred embodiment of the present invention is installed at the upper end of the outer housing 101 of the ground transformer, The heat generated in the process of transforming the secondary coil for low voltage (not shown in the figure) is transferred to the insulating oil filled therebetween, and the heat thus transferred is transferred to the inner housing 102 of the ground-type transformer by the convection, The heat transferred to the inner housing 102 flows to the upper portion of the outer housing 101 of the ground-level transformer by convection through the air filled between the inner housing 102 and the outer housing 101 of the ground- The air flowing to the upper portion of the outer housing of the ground-type transformer is absorbed by the heat absorbing plate 301 of the heat cooler 300 and is moved to the heat sink 302 of the heat cooler through the heat pipe 303 of the heat cooler, 203) It is presented through release to the atmosphere. Therefore, as soon as the heat is released to the atmosphere and the ground transformer 100 is cooled, it is possible to prevent the ground transformer from being overheated or exploding due to overheating, thereby preventing the breakdown of the ground transformer. Furthermore, the smooth cooling of the ground transformer increases the efficiency of the ground transformer, prevents the leakage of the insulating oil according to the overheating, and increases the lifetime of the ground transformer.

5 schematically shows a heat transfer process of the heat cooler 300 in the air cooling apparatus for preventing overheating of the ground-type transformer according to the present invention. The heat cooler 300 in the air cooling apparatus according to the present invention is composed of a heat pipe 303 in a cavity. One side of the heat pipe 303 extends beyond the outer housing 101 of the ground transformer to the space filled with air formed by the outer housing 101 and the inner housing 102 of the ground transformer, (301) for rapidly sucking the heat discharged from the heat exchanger (102). The other side of the heat pipe 303 is formed to extend in the longitudinal direction of the metal net adjacent to the metal net 203 and includes a heat sink 302 for rapidly discharging the heat absorbed by the heat absorbing plate 301 to the atmosphere do. The inside of the heat pipe 303 of the heat cooler 300 in the air cooling apparatus 200 according to another preferred embodiment of the present invention is made porous (porous) on the inner wall surface to facilitate heat absorption and heat dissipation. ) Material, and the inside of the heat pipe 303 is filled with methanol, acetone, sodium, or mercury. The lower part of the heat pipe 303 provided with the heat absorbing plate 301 receives heat by the high temperature air between the outer housing 101 and the inner housing 102 of the ground transformer to form a high temperature state , The liquid heated by the heat is filled in the heat pipe 303, and the heated liquid moves to the upper part of the heat pipe 303 by convection. The liquid transferred by the convection to the upper portion of the heat pipe is rapidly discharged to the atmosphere through heat exchange by convection by the heat dissipating plate 302 formed on the other side of the heat pipe 303. As a result, the heat generated during the transforming process of the ground transformer is discharged to the atmosphere faster than the conventional ground transformer through such a process. Accordingly, the ground transformer having the air cooling device according to the present invention continuously maintains the constant operating temperature do.

The present invention is not limited to the variations shown in the drawings, but may be extended to other embodiments falling within the scope of the appended claims.

100: ground transformer, 101: outer housing,
102: inner housing, 103: side vent,
200: air cooling device, 201: cap,
202: cap support, 203: metal mesh,
204: lower support, 205: upper support fastening hole,
206: screw hole in the upper part of the metal net, 207: screw hole in the lower part of the metal net,
208: lower support pin tightening hole, 209: lower support screw hole,
210: metal mesh upper fastening screw, 211: metal mesh lower fastening screw,
212: lower support pin tightening screw, 300: heat cooler,
301: heat sink, 302: endothermic plate,
303: Heat pipe.

Claims (6)

As an air cooling device (200) to prevent over-heating of the ground transformer,
A cap (201) and a cap support (202) for supporting the cap (201); A metal mesh 203 fastened to the cap support 202; And a lower support table 204 which is fastened to the metal mesh 203,
The cap support 202 has fastening means at its lower portion to be coupled to the metal mesh 203,
The metal mesh 203 has an upper portion of the metal mesh 203 attached to the cap support 202 and a lower portion of the metal mesh 203 for coupling with the lower support 204, A heat cooler 300 for discharging the heat of the surface transformer 100 to the outside is coupled to the inner surface of the metal mesh 203,
Wherein the upper part of the lower support 204 is fastened to the metal mesh 203 and the lower part of the lower support 204 is fastened to the outer housing 101 of the ground transformer by fastening means. Air cooling system to prevent overheating.
The heat exchanger according to claim 1, wherein the heat cooler (300) has a cavity heat pipe (303), one side of the heat pipe (303) extends beyond the outer housing (101) 301,
Wherein the other side of the heat pipe includes a heat dissipating plate (302) extending in a longitudinal direction of the metal mesh (203) for discharging heat.
The heat pipe (303) according to claim 2, wherein the heat pipe (303) is coated with a porous material on the inner wall surface to facilitate heat absorption and heat release, and the inside of the heat pipe (303) is made of methanol, acetone, And an air cooling device for preventing overheating of the ground transformer.
4. The apparatus according to any one of claims 1 to 3, wherein the fastening means of the cap support (202) and the metal net (203) comprises a cap support fastening hole (205) formed in a lower portion of the cap support (202) Wherein an upper screw thread hole (206) formed on an upper portion of the metal mesh (203) is fastened by a metal mesh upper screw (210).
4. The apparatus according to any one of claims 1 to 3, wherein the fastening means for fastening the metal net (203) and the lower support leg (204) comprises a metallic mesh lower threaded hole (207) formed in the lower part of the metal net (203) Wherein a lower support pin tightening hole (208) formed on an upper portion of the lower support (204) is fastened by a metal net lower fastening screw (211).
4. The transformer according to any one of claims 1 to 3, wherein the lower support pedestal (204) and the coupling means of the outer housing (101) of the ground transformer are provided with a lower support screw hole 209) and the outer housing (101) are fastened by a lower support screw tightening screw (212) to prevent overheating of the ground transformer.

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