KR20180073180A - A radiator for transformer - Google Patents

Abstract

The present invention relates to a radiator for a transformer which heat-exchanges insulating oil stored in a transformer body to cool the transformer. The radiator for a transformer includes a first inlet pipe, a second inlet pipe, a heat sink, and an outlet pipe. The first inlet pipe includes a horizontal pipe having an outer end connected to the transformer body and receiving the insulating oil from the transformer body, and a vertical pipe having an upper end extended downward from an inner end of the horizontal pipe and having a closed lower end. A plurality of second inlet pipes are formed such that an inner end is radially connected around the circumference of the vertical pipe to receive the insulating oil from the first inlet pipe, and an outer end is closed. A plurality of heat sinks are respectively connected to the lower sides of the second inlet pipes to be radially disposed, and receive the insulating oil from the second inlet pipes to perform heat exchange. The discharge pipe is connected to lower sides of the heat sinks, receives the heat-exchanged insulating oil from each of the heat sinks, and supplies the heat-exchanged insulating oil to the transformer body. Thus, heat dissipation efficiency is able to be improved.

Description

{A RADIATOR FOR TRANSFORMER}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a radiator for a transformer for cooling by heat exchange of insulating oil stored in a transformer main body.

Transformers installed to increase or decrease the voltage of the transmission and distribution line are important components of the power system and play a large role in stabilizing the power supply.

The inside of the transformer is filled with insulating oil so as to prevent the dielectric strength of the winding in the transformer from being lowered due to moisture or dust and to dissipate the heat generated by the winding by convection or radiation of the oil.

However, if the insulating oil is overheated due to overheating due to leakage current or insufficient insulation, high temperature caused by abnormality such as arc or partial discharge, and the temperature of the insulating oil increases, the pressure inside the transformer gradually rises. In this way, when the overheat and pressure increase state in the transformer continues, the explosion accident and the deterioration of the insulating oil cause the insulation damage and the insulation breakdown phenomenon.

To prevent such a phenomenon, a radiator is attached to one side of the transformer main body so that the heat generated in the transformer is transferred to the radiator by the insulating oil. Then, the radiator prevents the transformer from being overheated by allowing the insulating oil to cool by the fan or outside air.

1 is a perspective view illustrating a conventional radiator for a transformer. 2 is a view showing an example in which the radiator shown in FIG. 1 is installed in the transformer main body.

1 and 2, a radiator 1 for a transformer includes an inflow pipe 11 supplied with the insulating oil in the transformer main body 10, a heat exchanger 11 connected to a lower side of the inflow pipe 11, And a discharge pipe 13 connected to the lower side of the heat radiating plate 12 and discharging the heat-exchanged insulating oil to the transformer main body 10.

The conventional heat radiator 1 for a transformer is configured such that the inflow pipe 11 is horizontally connected from one side of the transformer main body 10 and the heat sinks 12 are disposed apart from the lower side of the inflow pipe 11 .

Accordingly, the plurality of heat sinks 12 are disposed side by side from the transformer main body 10, and the flow rate of the dielectric oil decreases as the distance from the transformer main body 10 increases. As the flow rate of the insulating oil decreases, the insulating oil is prevented from flowing evenly to the heat sink 12 away from the transformer main body 10, thereby lowering heat radiation efficiency.

An object of the present invention is to provide a radiator for a transformer with improved heat dissipation efficiency by improving the structure so that the amount of insulating oil supplied from the transformer main body to the heat sink becomes constant.

According to an aspect of the present invention, there is provided a heat spreader for a transformer, the heat radiator including a first inlet pipe, a second inlet pipe, a heat sink, and a discharge pipe for heat exchange with the insulating oil stored in the transformer main body. The first inlet pipe has a horizontal pipe whose outer end is connected to the transformer main body and supplied with the insulating oil from the transformer main body, and a vertical pipe whose upper end extends downward from the inner end of the horizontal pipe and whose lower end is closed. The second inflow pipe is provided in plural, and the inner end is radially connected along the circumference of the vertical pipe to receive the insulating oil from the first inflow pipe, and the outer end is formed to be closed. The plurality of heat radiating plates are connected to the lower side of the second inflow pipe and disposed radially, and the second inflow pipe receives the heat insulating oil and performs heat exchange. The discharge pipe is connected to the lower side of the heat sink, and receives the heat-exchanged insulating oil from each heat sink and supplies it to the transformer main body.

According to the present invention, as the plurality of heat sinks are radially connected to the first inlet pipe, the flow rate of the dielectric oil supplied from the first inlet pipe to each heat sink becomes constant. Accordingly, since the insulating oil can be uniformly supplied to each of the heat sinks, the area of contact with the insulating oil is wider than that of the conventional heat sink, and the heat radiation efficiency is improved.

1 is a perspective view showing a heat radiator for a transformer according to the prior art;
Fig. 2 is a view showing an example in which the radiator shown in Fig. 1 is installed in a transformer main body.
3 is a perspective view illustrating a radiator for a transformer according to an embodiment of the present invention;
Fig. 4 is a side view of the radiator shown in Fig. 3; Fig.
Fig. 5 is a view showing an example in which the radiator shown in Fig. 3 is installed in the transformer main body.
6 to 7 are side views showing a radiator for a transformer according to another embodiment of the present invention;

Hereinafter, a radiator for a transformer according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. Here, the same reference numerals are used for the same components, and repeated descriptions and known functions and configurations that may obscure the gist of the present invention will not be described in detail. Embodiments of the invention are provided to more fully describe the present invention to those skilled in the art. Accordingly, the shapes and sizes of the elements in the drawings and the like can be exaggerated for clarity.

FIG. 3 is a perspective view illustrating a radiator for a transformer according to an embodiment of the present invention, and FIG. 4 is a side view of the radiator shown in FIG. 4 is a view showing an example in which the radiator shown in Fig. 3 is installed in the transformer main body.

3 to 5, the radiator 100 for a transformer includes a first inflow pipe 110, a second inflow pipe 120, a heat sink 130, and a discharge pipe 140 . Here, the heat radiator 100 for a transformer is a device for cooling by heat-exchanging the insulating oil stored in the transformer main body 10.

The first inlet pipe 110 is horizontally disposed from the bottom surface and has an outer end connected to the transformer main body 10 and having a horizontal pipe 111 for supplying the insulating oil from the transformer main body 10.

The first inlet pipe 110 may further include a vertical pipe 112 for stable installation of the second inlet pipe 120, which will be described later. The vertical pipe 112 may have a shape in which the upper end extends downward from the inner end of the horizontal pipe 111 and the lower end is closed.

Specifically, the vertical pipe 112 may be bent downward from the inner end of the horizontal pipe 111, and a plurality of discharge holes 112a may be formed around the lower end of the horizontal pipe 111. Here, the number of the discharge holes 112a is not limited, but is preferably equal to the number of the heat sinks 130 to be described later.

A plurality of second inflow pipes 120 are provided, and the inner ends thereof are radially connected along the circumference of the vertical pipe 112 to receive the insulating oil from the first inflow pipe 110.

The second inlet pipe 120 may be formed so that the outer end thereof is closed. Since the plurality of discharge holes 112a are formed on the lower side of the vertical pipe 112, if the second inlet pipe 120 is connected to the discharge hole 112a, the second inlet pipe 120 is radially .

The plurality of heat sinks 130 may be connected to the lower side of the second inflow pipe 120, and the second inflow pipe 120 may receive the heat oil and receive heat. At this time, the heat sink 130 may be disposed radially as the second inlet pipe 120.

A flow passage (not shown) may be formed in the heat dissipation plate 130 in a vertical direction so that the insulating oil can flow. The flow path can be manufactured by forming a groove in the inside of a pair of panels and welding a pair of panels together. Since the structure of such a heat dissipating plate 130 is a well-known structure, detailed description and drawings are omitted .

As the insulating oil having passed through the first inlet pipe 110 and the second inlet pipe 120 is supplied to the inside of the heat sink 130, the heat oil is heat-exchanged with the external air contacting the external surface of the heat sink 130, .

Particularly, since the second inflow pipe 120 is radially connected to the first inflow pipe 110, the insulating oil can be uniformly supplied to the heat sink 130 disposed below the second inflow pipe 120 . 1 and 2, the flow rate of the insulating oil supplied to the heat radiating plate 12 is set to be lower than that of the first inlet pipe 11 arranged in the horizontal direction, And decreases as the distance from the inflow side increases, which causes a decrease in the heat radiation efficiency.

However, when the second inflow pipe 120 is radially connected to the first inflow pipe 110 as in the present invention, the positions of the second inflow pipes 120 from the first inflow pipe 110 are the same It will be canceled.

Accordingly, the flow rate of the insulating oil supplied to the second inlet pipes 120 becomes the same, so that the insulating oil can be uniformly supplied to the respective heat sinks 130 connected to the lower side of the second inlet pipe 120. When the insulating oil is uniformly supplied to each of the heat sinks 130, the contact area between the insulating oil and the heat sink 130 is widened, thereby improving heat dissipation efficiency.

The discharge pipe 140 is connected to the lower side of the heat sink 130 and supplies the heat-exchanged insulating oil from the respective heat sinks 130 to the transformer main body 10. The discharge pipe 140 includes a first discharge pipe 141 and a second discharge pipe 142. The first discharge pipe 141 and the second discharge pipe 142 are connected to the transformer main body 10, can do.

The first discharge pipe 141 is connected to each lower side of the heat radiating plate 130, and is radially disposed to receive the heat-exchanged insulating oil from the heat radiating plate 130. And, the first discharge pipe 141 may be formed such that the inner end thereof is opened and the outer end thereof is closed.

The second discharge pipe 142 is connected to the inner end of the first discharge pipe 141 on the upper side and is connected to the second discharge pipe 141 through the second discharge pipe 141. The second discharge pipe 142 receives the heat- And a vertical pipe 142a.

Specifically, a plurality of inlet holes 143a may be formed on the upper side of the second vertical pipe 142a. Since the first discharge pipes 141 are connected to the plurality of the inlet holes 143a, the first discharge pipes 141 can be arranged radially. Here, the number of the inlet holes 143a is not limited, but is preferably the same as the number of the heat sinks 130. [

The second discharge pipe 142 may further include a horizontal pipe 142b for stably supplying the insulating oil discharged from the second vertical pipe 142a. The horizontal pipe 142b may extend in the horizontal direction from the lower end of the second vertical pipe 142a at an inner end and may be connected to the transformer body 10 at an outer end.

Accordingly, the horizontal pipe 142b can receive the insulating oil discharged from the second vertical pipe 142a and discharge it to the transformer main body 10.

As described above, the heat radiator 100 for a transformer radially connects the plurality of heat sinks 130 to the first inlet pipe 110, so that the insulating oil supplied from the first inlet pipe 110 to each heat sink 130 The flow rate of the gas is constant. Accordingly, since the insulating oil can be uniformly supplied to each of the heat sinks 130, the area of contact with the insulating oil is wider than that of the conventional heat sink 1, and heat radiation efficiency is improved.

6 is a side view showing a radiator for a transformer according to another embodiment of the present invention. In the present embodiment, the differences from the above-described embodiment will be mainly described.

As shown in FIG. 6, the radiator 200 for a transformer may be formed such that the second inflow pipe 120 is horizontally disposed and downwardly inclined from the inner end toward the outer end.

As the second inflow pipe 120 is formed to be inclined downward from the inner end portion toward the outer end portion, the flow rate of the insulating oil flowing from the first inflow pipe 110 to the second inflow pipe 120 increases. In this case, since the insulating oil flowing into each of the heat sinks 130 in the second inlet pipe 120 can be supplied more quickly and uniformly, heat radiation efficiency can be improved.

7 is a side view showing a heat spreader for a transformer according to another embodiment of the present invention. In the present embodiment, the differences from the above-described embodiment will be mainly described.

7, the transformer radiator 300 may further include a connection member 150 at a connection portion between the first inflow pipe 110 and the second inflow pipe 120.

The connecting member 150 may be in the form of a cone formed to be smaller in cross section in the direction of discharge of the insulating oil. The connecting member 150 having a conical shape is installed at the connecting portion between the first inlet pipe 110 and the second inlet pipe 120 so that the pressure between the first inlet pipe 110 and the second inlet pipe 120 And a flow rate of the insulating oil can be increased.

That is, the connecting member 150 serves as a pump, and the flow rate of the insulating oil passing through the connecting member 150 increases due to a pressure difference between the inlet and the outlet. Since the supply of the insulating oil flowing into the respective heat sinks 130 from the second inlet pipe 120 can be performed more quickly and uniformly, the heat dissipation efficiency can be improved.

Although not shown, the connecting member 150 may be a Venturi tube designed to increase the velocity of fluid as it passes through the tube.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation and that those skilled in the art will recognize that various modifications and equivalent arrangements may be made therein. It will be possible. Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

110. First inlet pipe
111 .. Horizontal pipe
112 .. vertical pipe
120. Second inlet pipe
130 .. heat sink
140 .. discharge pipe
141. First discharge pipe
142 .. Second exhaust pipe
142a .. Second vertical pipe
142b .. Second horizontal pipe
150.

Claims (9)

A heat spreader for a transformer for cooling insulating oil stored in a transformer main body,
A first inlet pipe having an outer end connected to the transformer main body and having a horizontal pipe for supplying the insulating oil from the transformer main body;
A plurality of second inflow pipes whose inner ends are radially connected along the periphery of the first inflow pipe and are supplied with the insulating oil from the first inflow pipe and whose outer ends are closed;
A plurality of heat sinks connected to the lower side of the second inflow pipe and arranged radially, the heat sinks receiving heat oil from the second inflow pipe and performing heat exchange; And
A discharge pipe connected to a lower side of the heat sink and supplied with heat-exchanged oil from each of the heat sinks and supplying the same to the transformer main body;
And a radiator for a transformer.
The method according to claim 1,
Wherein the first inflow pipe further comprises a vertical pipe having an upper end extending downwardly from an inner end of the horizontal pipe and a lower end closed.
3. The method of claim 2,
Wherein the vertical pipe is formed with a plurality of discharge holes around its lower side and the discharge pipes are respectively connected to the discharge holes.
The method according to claim 1,
Wherein the second inflow pipe is disposed in a horizontal direction and is inclined downward from an inner end toward an outer end.
The method according to claim 1,
And a connecting member in the form of a cone formed in a connecting portion between the first inlet pipe and the second inlet pipe so as to have a smaller cross section in the discharge direction of the insulating oil.
The method according to claim 1,
Further comprising a connection member formed of a venturi tube at a connection portion between the first inflow pipe and the second inflow pipe.
The method according to claim 1,
The discharge pipe
A plurality of first discharge pipes connected to respective lower sides of the heat radiating plate, radially arranged to receive the heat-exchanged insulating oil from the heat radiating plate, having an inner end opened and an outer end closed;
And a second exhaust pipe having a second vertical pipe connected to the inner end of the first exhaust pipe at an upper side thereof and supplied with the insulating oil heat-exchanged from the first exhaust pipe to the transformer main body, Radiator.
8. The method of claim 7,
Wherein the second discharge pipe further comprises a second horizontal pipe having an inner end extending horizontally from a lower end of the second vertical pipe and an outer end connected to the transformer main body.
8. The method of claim 7,
Wherein the second vertical pipe is formed with a plurality of inflow holes around the upper side thereof, and the first discharge pipes are connected to the inflow holes, respectively.

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