KR100725074B1 - Turbo cooling apparatus of transformer and cooling control method thereof - Google Patents

Abstract

A turbo cooling apparatus of a high voltage transformer is provided to increase efficiency of the high voltage transformer by automatically controlling the turbo cooling apparatus according to an inner temperature condition of the transformer. A turbo cooling apparatus of a high voltage transformer includes a general heat convection type heat dissipater(30), high/low voltage terminals(34,36) for high voltage insertion and low voltage withdrawing, a body(32), radiating pipes(38), a cooling fan(42), and a bracket(40). The radiating pipes(38) are continuously arranged at regular intervals at one side of the body(32). The cooling fan(42) for turbo cooling is installed adjacently to an array of the radiating pipes(38) by using the bracket(40).

Description

Turbo cooling apparatus of high pressure transformer and its operation control method

1 is a diagram illustrating an internal structure of a general high pressure transformer.

2 is an external structural diagram of a conventional transformer having a natural convection radiator.

3 is a perspective view of a first embodiment (heat dissipation pipe) of a turbo cooling device of a high-pressure transformer according to the present invention.

4 is a perspective view of a second embodiment (heat pipe) of the high-pressure transformer turbo cooling device according to the present invention.

5 is a perspective view of a third embodiment (inclined heat pipe) of the high-pressure transformer turbo cooling device according to the present invention.

6 is a plan view of a second embodiment of a high-pressure transformer turbo cooling device according to the present invention.

7 is a plan view of a fourth embodiment of a high pressure transformer turbo cooling device according to the present invention.

8 is a block diagram of a turbo cooling operation control circuit of the high-voltage transformer according to the present invention.

9 is a flowchart illustrating a turbo cooling operation control process of the high pressure transformer according to the present invention.

* Explanation of symbols for main parts of drawings *

30: radiator 32: (high voltage transformer)

34: high voltage terminal 36: low voltage terminal

38: heat dissipation pipe 40, 40-1: bracket

42,42-1: Cooling fan 44,44-1,45: Heat pipe

46: temperature sensor 50: controller

52: reference temperature setting section 54: driver

The present invention relates to a cooling technology for improving the efficiency of a high pressure transformer installed in an integrated switchgear, etc. In particular, an additional turbo cooling device is installed on one side of a high pressure transformer having a conventional radiator, and the turbo cooling device is an internal temperature condition of the high pressure transformer. The present invention relates to a cooling apparatus for a high pressure transformer and a cooling operation control method thereof, by which the automatic operation is performed to improve the efficiency of the high pressure transformer.

The power supply unit (switch distribution panel) that converts the extra high voltage to low pressure and supplies the necessary power to apartments, buildings, schools, factories, ports, etc. is equipped with a large high-voltage transformer with a capacity of about 80 to 700 kW.

The high-pressure transformer blocks the inflow of moisture and foreign substances from the outside, and the casing is closed in its entirety and the inner space is filled with insulating oil in order to keep the internal components operating optimally. In particular, one side of the high-voltage transformer case is provided with a radiator to promote cooling by the insulating oil circulation.

The radiator cools the heat generated during the high and low voltage induction process of the high pressure transformer by bringing it into contact with the outside atmosphere.

If the internal temperature of the high-voltage transformer rises, the transformer efficiency decreases, resulting in a decrease in output, and furthermore, cooling of the high-voltage transformer is very important because an accident such as damage or explosion may occur due to destruction of the insulating layer.

1 shows the internal structure of a typical high pressure transformer. This is a cross-sectional view of the internal structure of the oil transformer installed in the switchgear, the core 18 is installed on the inner side of the bobbin 10 of the oil transformer, and the high pressure coil 14 and the low pressure coil 12 are installed in the outer circumference. I'm showing you.

Through the flow path duct 16 provided between the high pressure coil and the low pressure coil, the insulating oil absorbing heat generated in the transformation process circulates through the heat radiator installed outside the flow path and the high pressure transformer to cool the temperature of the high pressure transformer.

Here, looking at the cooling process by the insulating oil, when the insulating oil is first heated, natural convection occurs to move upward along the flow path duct due to buoyancy. This is one of the circulation operations to remove the heat generated inside the high-voltage transformer, the heat transferred to the insulating oil is cooled in the radiator (radiator) installed on the outside of the transformer. The insulating oil cooled in the radiator is returned back into the high pressure transformer, and the high pressure transformer is cooled by the sealed single phase thermosyphon method.

2 is an external structural diagram of a conventional high-pressure transformer having a natural convection radiator, the radiator 20 having a plurality of heat radiation fins on the outside of the high-voltage transformer main body 22 having the high and low voltage terminals 24 and 26 for power inlet and drawout. ), Which shows that the internal insulating oil absorbing heat generated from the high-pressure transformer moves along the flow path of the radiator 20 installed outside the transformer body to perform heat exchange by convection with the outside air. It dissipates heat generated in the high pressure transformer.

However, since the heat dissipation performance of the conventional inlet transformer having a simple radiator as described above is determined by the size of the heat sink, it is necessary to increase the area of the radiator to increase the heat dissipation efficiency. There is a problem that causes a burden, and increases the maintenance and management burden of the product.

The present invention is to solve the problems of the conventional high pressure transformer cooling technology as described above, an object of the present invention is to install a turbo cooling device on one side of the existing high pressure transformer having a radiator and the turbo cooling device is a high pressure transformer It is to provide a cooling apparatus and a cooling operation control method of the high-pressure transformer to improve the efficiency of the high-voltage transformer by the automatic operation control according to the internal temperature conditions of the.

Another object of the present invention is to install a turbo cooling device on one side of the existing high pressure transformer having a radiator, the cooling device to maximize the operating efficiency of the high pressure transformer by quickly dissipating the heat generated by the high pressure transformer to the outside by using a heat pipe. The present invention provides a cooling device for a high pressure transformer and a cooling operation control method thereof.

Turbo cooling device of the high pressure transformer of the present invention for achieving the above object of the present invention is a series of heat dissipation pipe or heat pipe array on one side of the high pressure transformer is provided with a conventional tropical flow radiator vertically or inclined arrangement and the heat dissipation In close proximity to the pipe or heat pipe array, a cooling fan for turbo cooling is installed.

In addition, the turbo cooling operation control method of the high-voltage transformer of the present invention senses the temperature of the insulating oil in the high-voltage transformer and compares it with a predetermined set temperature value, and then when the temperature of the insulating oil in the high-voltage transformer exceeds the set temperature value, the high-pressure transformer It characterized in that the drive control of the cooling fan for the turbo cooling of the heat radiation pipe or heat pipe array of a series of heat pipes installed on one side of.

Hereinafter, the present invention will be described with reference to the accompanying drawings.

3 is a first embodiment of a turbo cooling device of a high-pressure transformer according to the present invention.

As referred to herein, the high-pressure transformer cooling apparatus of the present invention is one of the high-pressure transformer body 32 is provided with a conventional tropical flow type radiator 30 and the high, low pressure terminals (34, 36) for high pressure inlet and low pressure drawout. Continuously arranging the heat dissipation pipes 38 at regular intervals on the side to form a series of vertical heat dissipation pipe arrays, and approaching the vertical heat dissipation pipe arrays by installing a cooling fan 42 for turbo cooling using the bracket 40. have.

The heat dissipation pipe 38 may form a heat dissipation fin in the longitudinal direction along a circumference of the heat dissipation pipe body for rapid heat exchange.

In addition, the vertical heat dissipation pipe array is advantageously installed in the upper portion or more than the middle portion of the high-pressure transformer body 32 for the rapid cooling of the upper layer oil in the body.

As shown in FIG. 8, the cooling fan 42 is configured to be driven and controlled by the scriber 54 in the controller 50, and the controller 50 is a temperature sensor mounted on the high-voltage transformer main body 32. The temperature extraction value of the oil in the main body from 46 is compared with the reference temperature value, and the cooling fan drive signal is output to the driver 54 when the current oil temperature value exceeds the reference temperature. The reference temperature to be used in the controller allows to register in advance through a separate reference temperature setting unit 52.

Referring to the operation of the first embodiment of the present invention having such a configuration is as follows.

First, when the transformer operation occurs in the high-voltage transformer body, heat is generated by iron loss and the like, and the insulating oil inside the body 32 is heated for a predetermined time. The heated insulating oil is convectively circulated through the ordinary radiator 30 and the cooling operation is performed.

The heat generated by the transformer operation in the high-voltage transformer body 32 depends on the load, and as the load increases, the temperature of the insulating oil rises together, and when this condition progresses further, the temperature of the transformer exceeds the maximum allowable temperature value. Transformer circuit breakage will occur. Therefore, if the heat generated above the limit temperature of the high pressure transformer can be quickly and processed, the transformer efficiency can be increased, and thus more load can be covered according to the increase effect of the limit capacity of the high pressure transformer.

Therefore, the oil temperature of the high pressure transformer detected by the temperature sensor 46 and input to the controller 50 during the heat radiation operation of the radiator 20 installed on one side of the high pressure transformer is set to the set value (reference temperature setting part ( 52), the controller 50 drives the cooling fan 42 through the driver 54.

The driving of the cooling fan 42 is provided on the upper side of one side of the main body 32, so that the air is blown through a series of heat dissipation pipe arrays for convection of heated oil (insulating oil). This will happen. That is, when the internal temperature of the high-voltage transformer body 32 rises rapidly, the turbo cooling operation is performed by an additional heat dissipation pipe array in addition to the existing heat dissipator 30 and a cooling fan installed near the heat dissipation pipe array.

Figure 4 shows a second embodiment of the high pressure transformer turbo cooling device according to the present invention using a heat pipe 44 instead of a heat radiation pipe.

The heat pipe 44 may be manufactured by forming a porous or slot in the longitudinal direction along the inner circumference of the pipe and closing the medium after injecting a medium such as acetone or methyl alcohol. By performing vaporization of the medium and liquefaction of the medium by cooling in the upper portion of the heat pipe (the liquid moves downward through the porous or the slot inside the pipe), a rapid and high efficiency heat exchange operation is performed.

Therefore, when a plurality of heat pipes 44 are arranged side by side in succession to form a series of heat pipe arrays, and the cooling fan 42 is mounted and driven in close proximity to the heat pipe arrays, internal heat generation in the high pressure transformer is prevented. It can be cooled at a remarkably high speed to improve the transformer efficiency of the high pressure transformer.

Figure 5 shows a structure that can maximize the efficiency of the heat pipe as a third embodiment of the high-pressure transformer turbo cooling device according to the present invention.

Here, a plurality of heat pipes 45 are continuously arranged side by side on the upper side of the main body 32 of the high-voltage transformer body 32 to form a series of heat pipe arrays, and these heat pipes 45 have a predetermined angle of inclination with respect to the vertical direction ( are arranged at an angle of θ).

The structure of the third embodiment of the present invention is such that the operation performance of the heat pipe is smoothly maintained, and the vaporization of the medium by heating at the lower part of the heat pipe occurs and the liquefaction of the medium by cooling at the upper part of the heat pipe. When this occurs, the inclined arrangement of the heat pipe allows the liquid liquefied at the top of the heat pipe to naturally move downward through the porous or slots inside the pipe, resulting in a smooth sublimation operation.

Figure 6 is a plan view of a second embodiment of a high pressure transformer turbo cooling device according to the present invention, Figure 7 is a plan view of a fourth embodiment of a high pressure transformer turbo cooling device according to the present invention.

This shows that the turbo cooling by the heat dissipation pipe or the heat pipe array and the cooling fan can be installed on two or more sides of the high pressure transformer main body 32, and the heat dissipation pipe or the heat pipe array and the cooling fan in one high pressure transformer. It is shown that the transformer rating or efficiency can be increased by the expansion of the turbo cooling system.

8 is a configuration diagram of a turbo cooling operation control circuit of the high pressure transformer according to the present invention as described above, and FIG. 9 is a flowchart illustrating a turbo cooling operation control process of the high pressure transformer of the present invention based on the control circuit of FIG. 8. to be.

In the turbo cooling operation control method of the high pressure transformer according to the present invention, a series of heat dissipation pipes or heat pipe arrays are disposed vertically or inclined on one side of the high pressure transformer having a general tropical flow radiator and a temperature sensor for detecting internal temperature. In close proximity to the heat-radiating pipe or heat pipe array, a cooling fan for turbo cooling is installed, the temperature value inside the high-voltage transformer is sensed and compared to a predetermined set temperature value, and then the temperature of the insulating oil in the high-voltage transformer is set as described above. When the temperature value is exceeded, the high-pressure transformer is turbo-cooled by controlling and controlling a series of heat-dissipating pipes or turbo cooling cooling fans of the heat-pipe array installed at one side of the high-voltage transformer.

As described above, the present invention further installs a turbo cooling device on one side of an existing high pressure transformer having a radiator, and the turbo cooling device significantly improves the efficiency of the high pressure transformer by automatically controlling the operation according to the internal temperature condition of the high pressure transformer. You can.

In addition, the present invention is to install a turbo cooling device on one side of the existing high-pressure transformer having a radiator, this cooling device to further improve the operating efficiency of the high-voltage transformer by quickly dissipating the heat generated by the high-pressure transformer to the outside using a heat pipe. To be able.

Claims (5)

A turbo cooling apparatus for a high pressure transformer, characterized in that a series of heat pipe arrays are vertically arranged at one side of a high pressure transformer provided with a conventional tropical flow radiator, and a cooling fan for turbo cooling is provided in proximity to the heat pipe array. The turbocooling apparatus of claim 1, wherein the series of heat pipe arrays are inclined at a predetermined angle with respect to the vertical direction. The turbocooling apparatus of claim 1, wherein the series of heat pipe arrays having the turbo cooling fans are installed at two or more along the circumference of the high pressure transformer. The turbocooling apparatus of claim 1, wherein the series of heat pipe arrays is installed at an upper end portion of one side of the high pressure transformer enclosure. delete

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