KR102053754B1 - Transformer - Google Patents

Abstract

The present invention provides a transformer having large resistance against external force by earthquake or external impact by improving a structure for supporting a radiator to enable a radiator to be supported by a structure for supporting both ends installed for heat dissipation of insulating oil and reducing the overall weight by reducing a weight of a structure for supporting a radiator since the strength of a structure for supporting a radiator is increased.

Description

Transformer {TRANSFORMER}

The present invention relates to a transformer that improves the support structure of the radiator to dissipate heat generated during the transformation of power.

In general, a transformer is a power device for raising or lowering a voltage, and a power device for transforming is disposed inside the enclosure, and the power device is insulated by insulating oil filled in the enclosure.

In the transformer, heat is generated in the process of transforming the voltage, and the heat generated in the transformer increases the temperature of the insulating oil filled in the transformer, and when the temperature of the insulating oil increases, the internal pressure of the transformer also increases. Therefore, the possibility of an explosion of a transformer may increase due to overheating and a pressure increase, and insulation damage may occur as the insulating oil degrades.

Therefore, the conventional transformer is provided with a radiator for radiating the insulating oil.

The radiator is connected to the transformer enclosure and the insulating oil circulates and radiates. That is, the insulating oil filled in the enclosure of the transformer is supplied to the radiator, circulated, and cooled while releasing heat while passing through the radiator.

1 is a perspective view of a transformer according to the prior art, FIG. 2 is a side view of the transformer according to the prior art, and FIG. 3 is a plan view of the transformer according to the prior art.

1 to 3, the transformer 1 includes an enclosure 10 forming an appearance, and inside the enclosure 10, a power device for converting a voltage by winding a coil around a core is disposed, and the enclosure (10) is filled with insulating oil and provided to insulate the power equipment.

The radiator 20 is installed on the side of the enclosure 10 of the transformer 1, and the upper and lower parts are connected and supported by the upper header pipe 12 and the lower header pipe 14 extending from the enclosure 10. Insulating oil is circulated. The radiator 20 has a cooling flow path through which the insulating oil passes, and a plurality of heat sinks 22 for heat dissipation are extended and installed around the cooling flow path.

However, the conventional transformer 1 is provided in a structure in which the radiator 20 is supported by the upper header pipe 12 and the lower header pipe 14 in the form of cantilever beams extending from the enclosure 10. When an external force is transmitted by an external shock or the like, a large force is applied to the connection portion of the upper header pipe 12 or the lower header pipe 14 so that the connection is broken or the upper header pipe 12 or the lower header pipe 14 is damaged. There is a risk of deformation.

The present invention improves the structure of supporting the radiator so that the radiator installed for heat dissipation of the insulating oil is supported by both ends of the support structure to have a large resistance to external force by earthquake or external impact, and the strength of the structure supporting the radiator It is an object of the present invention to provide a transformer capable of reducing the weight of the structure supporting the radiator as it increases, thereby reducing the overall weight.

The objects of the present invention are not limited to the above-mentioned objects, and other objects and advantages of the present invention, which are not mentioned above, can be understood by the following description, and more clearly by the embodiments of the present invention. Also, it will be readily appreciated that the objects and advantages of the present invention may be realized by the means and combinations thereof indicated in the claims.

A transformer according to an embodiment of the present invention for achieving the above object is an enclosure containing an internal power device, the insulating oil for the insulation of the internal power device; A plurality of radiators installed on at least one side of the enclosure to cool the insulating oil heated and discharged from the enclosure; A plurality of upper header pipes respectively installed on upper sides of the radiators to supply the insulating oil discharged from the enclosure to the radiators; A lower header pipe installed at a lower side of the radiator to collect the insulating oil cooled through the radiator; A plurality of upper supports installed at an upper side of the enclosure and coupled to the upper header pipe to support both ends of the upper header pipe; And a plurality of lower support parts installed at a lower side of the enclosure and coupled to the lower header pipe to support both ends of the lower header pipe.

The heat radiator includes a plurality of heat sinks spaced apart from each other, and the upper header pipe and the lower header pipe are disposed to have the same length direction as that of the heat sink.

The upper support portion is characterized in that one end is connected to the upper side of the enclosure, each other end is extended to the outside of the enclosure, and is coupled vertically to both ends of the upper header pipe.

The lower support portion is characterized in that one end is connected to the lower side of the enclosure, the other end is extended to the outside of the enclosure and coupled vertically to both ends of the lower header pipe.

The upper support may be supplied with the heated insulating oil discharged from the enclosure through at least a portion to the upper header pipe.

The lower support part may be supplied to the enclosure with the insulating oil collected in the lower header pipe through at least a portion.

In addition, the heat dissipation plate may be disposed to be displaced from the heat dissipation plate of another adjacent heat dissipator.

In addition, the transformer may further include at least one blower fan provided on one side of the enclosure to blow air to the heat sink.

According to the present invention as described above, the present invention improves the structure for supporting the radiator so that the radiator installed for the heat dissipation of the insulating oil is supported by both ends of the support structure to have a large resistance to external forces by earthquakes or external shocks, etc. As the strength of the structure supporting the radiator increases, the structure supporting the radiator can be reduced in weight, thereby reducing the overall weight.

1 is a perspective view of a transformer according to the prior art.
2 is a side view of a transformer according to the prior art.
3 is a plan view of a transformer according to the prior art.
4 is a perspective view of a transformer according to an embodiment of the present invention.
5 is a side view of a transformer according to an embodiment of the present invention.
6 is a plan view of a transformer according to an embodiment of the present invention.
7 is a bottom view of a transformer according to an embodiment of the present invention.

The above objects, features, and advantages will be described in detail with reference to the accompanying drawings, whereby those skilled in the art may easily implement the technical idea of the present invention. In describing the present invention, when it is determined that the detailed description of the known technology related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description will be omitted. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to indicate the same or similar components.

4 is a perspective view of a transformer according to an embodiment of the present invention, FIG. 5 is a side view of a transformer according to an embodiment of the present invention, and FIG. 6 is a plan view of the transformer according to an embodiment of the present invention. 7 is a bottom view of a transformer according to an embodiment of the present invention.

4 to 7, the transformer 100 of the present embodiment may include an enclosure 110 having an approximately hexahedral shape and forming an appearance. In the enclosure 110, a power device including a core and a coil wound around the core for transformation may be accommodated, and insulating oil for thermal insulation of the power device may be accommodated.

The transformer 100 may increase the temperature of the insulating oil by heat generated in the process of transforming the voltage of the power device, and when the insulating oil rises, insulation damage may occur due to explosion or evaporation or deterioration of the insulating oil.

The transformer 100 may include a radiator 120 for circulating and dissipating the insulating oil in order to prevent the temperature rise of the insulating oil.

The insulating oil heated by the heat of the transformer 100 is discharged to the upper portion of the enclosure 110 of the transformer 100. The discharged insulating oil is cooled through the radiator 120 and then flows back into the lower portion of the enclosure 110. The radiator 120 may be provided in plurality. The enclosure 110 and the radiator 120 are connected by separate connectors, and the insulating oil moves through the connectors. This connector structure may be provided at the upper and lower portions of the enclosure 110, respectively.

Hereinafter, the connector structure described above will be described in detail.

The upper one side of the enclosure 110 is provided with a plurality of upper support parts 112, 114, 116 to move the insulating oil discharged from the enclosure 110 to the radiator 120. The lower one side of the enclosure 110 is provided with a plurality of lower support portions 113, 115, and 117 to move the insulating oil radiated from the radiator 120 back into the enclosure 110. A header pipe 124 connected to the radiator 120 is provided between the plurality of upper supports 112, 114, and 116 to move the insulating oil moved through the upper supports 112, 114, and 116 to the radiator 120. .

The other side of the enclosure 110 is provided with the same upper and lower supports, radiators and header pipes as described above. Since this is the same configuration, the description thereof will be omitted for convenience.

Here, one side and the other side of the enclosure 110 refers to two surfaces having a relatively wide area of the hexahedral shape, and faces that face each other. The same heat dissipation and support structure as the above-described configuration may be provided on a surface having a relatively narrow area among the hexahedral shapes of the enclosure 110. However, considering the installation area, the number of radiators and the number of supporting structures may be reduced.

In detail, the transformer 100 may be provided by extending the first upper support part 112 through which insulating oil flows on an upper side of the enclosure 110. In addition, the transformer 100 may be provided with the second upper support part 114, which is spaced apart from the first upper support part 112, by a predetermined distance from the upper other side of the enclosure 110.

The first upper support part 112 and the second upper support part 114 may be formed to extend to a predetermined length from the enclosure 110, and the insulating oil accommodated in the enclosure 110 may be provided to be connected to the enclosure 110. Can be supplied. One end of the first upper support part 112 and the second upper support part 114 is connected to the enclosure 110, and the other end extends to the outside of the enclosure 110. In this case, the first upper support part 112 and the second upper support part 114 extend perpendicular to one side surface of the enclosure 110.

In addition, the transformer 100 may be provided by extending the first lower support portion 113 through which the insulating oil flows on the lower side of the enclosure 110. In addition, the transformer 100 may be provided with the second lower support part 115 which is spaced apart from the first lower support part 113 by a predetermined distance to the other side of the lower part of the enclosure 110.

The first lower support part 113 and the second lower support part 115 may be provided to correspond to the first upper support part 112 and the second upper support part 114, respectively.

In addition, the first lower support part 113 and the second lower support part 115 may be formed to extend from the enclosure 110 to a predetermined length. Preferably, the first lower support part 113 and the second lower support part 115 may be supplied after the insulating oil introduced into the first upper support part 112 and the second upper support part 114 circulates through the radiator 120. In addition, the circulating and supplied insulating oil may be provided to return to the inside of the enclosure 110.

In the present embodiment, the transformer 100 is not limited to two upper support parts 112 and 114 and lower support parts 113 and 115 provided in the enclosure 110, and may be provided in a plurality of rows spaced apart from each other by a predetermined distance. It is possible to provide three pieces as an example.

That is, in the present embodiment, the upper support parts 112, 114, and 116 may further include a first upper support part 112, a second upper support part 114, and a third upper support part 116. The second upper support part 114 and the third upper support part 116 may be described as having a structure equivalent to that of the first upper support part 112 and the second upper support part 114, and this structure may be described as the lower support part 113. The same applies to (115, 117).

In addition, the radiators 120 may be arranged in a row at predetermined intervals between the upper supports 112, 114, and 116 and the lower supports 113, 115, and 117. These radiators 120 are in contact with the air passing through the periphery and may radiate heat transferred from the insulating oil.

Meanwhile, an upper header pipe 124 may be installed between the first upper support part 112 and the second upper support part 114.

The upper header pipe 124 is installed to have the same direction in the longitudinal direction along the heat dissipation plate 122 arrangement direction of the radiator 120. That is, the upper header pipe 124 is installed in a direction parallel to one side of the enclosure 110.

The upper header pipe 124 may be connected to the first upper support part 112 or the second upper support part 114 to supply insulating oil. The upper header pipe 124 serves to supply insulating oil to the radiator 120. The insulating oil flows along the longitudinal direction of the upper header pipe 124 and moves to the heat sink 122 of the heat sink 120.

In addition, a lower header pipe 126 may be installed between the first lower support part 113 and the second lower support part 115.

The lower header pipe 126 is installed to have the same direction in the longitudinal direction along the heat sink 122 arrangement direction. That is, the lower header pipe 126 is installed in a direction parallel to one side of the enclosure 110.

The lower header pipe 126 is a portion where the insulating oil cooled by passing through the radiator 120 is collected, and the cooled insulating oil moves along the longitudinal direction of the lower header pipe 126.

In addition, a radiator 120 may be installed between the upper head pipe 124 and the lower header pipe 126. The radiator 120 may be provided in communication with the upper head pipe 124 and the lower header pipe 126, and the insulating oil may be circulated and cooled.

The radiator 120 may be provided with a plurality of circumferential heat sink 122 to improve the heat radiation efficiency. Here, the heat sink 122 is provided in a thin plate-like structure, it can increase the contact area with the air. In the present embodiment, the heat sink 120 is disclosed as having a heat sink 122 having a plate-like structure, but in addition, it can be disclosed in various forms to increase the contact area with air, such as a fin structure.

In the present embodiment, the heat sink 120 may be a weight structure with increased self weight as a plurality of heat sinks 122 are provided. The radiator 120 is connected to the upper header pipe 124 and the lower header pipe 126, the upper header pipe 124 and the lower header pipe 126, respectively, the first and second upper support parts 112 and 114, respectively. And the first and second lower support portions 113 and 115 are connected in the form of both ends of the support beam. That is, the first and second upper support parts 112 and 114, the upper header pipe 124, and the first and second lower support parts 113 and 115 and the lower header pipe 126 are vertically connected to each other. This ensures sufficient durability against external forces such as earthquakes, external shocks, and vibrations.

As described above, the insulating oil may move to the radiator 120 through the first upper support part 112. The insulating oil may be supplied to the radiator 120 only through the first upper support part 112, or may also be supplied to the radiator 120 through the second upper support part 114 or the third upper support part 116.

Alternatively, the insulating oil may move to the radiator 120 positioned on the right side through the first upper support part 112, and the insulating oil may move to the radiator 120 positioned on the left side through the second upper support part 114. have.

In this case, the insulating oil in the right radiator 120 may be cooled while flowing toward the second upper support part 114 in the direction of the first upper support part 112. The insulating oil in the left radiator 120 may be cooled while flowing toward the third upper support part 116 in the direction of the second upper support part 114. The insulating oil cooled in the right radiator 120 may be supplied back into the enclosure 110 through the second lower support part 115. The insulating oil cooled in the left radiator 120 may be supplied back into the enclosure 110 through the third lower support part 117. In this case, since the insulating oil does not move directly through the first lower support part 113 and the third upper support part 116, they only serve to support the radiator 120.

However, when the flow direction of the insulating oil is changed, the insulating oil flows through some of each of the upper support and the lower support, and the rest may only serve to support the radiator.

Meanwhile, in the present embodiment, the radiator 120 is described as being arranged in a row with other radiators 120 adjacent thereto. In addition, the radiator 120 provided to the radiator 120 has another radiator 120 adjacent thereto. The heat sink 122 may be disposed to be offset from each other.

Preferably, the heat sink 122 provided on the heat sink 120 may be disposed to be located between the heat sink 122 of the other heat sink 120 adjacent to.

As such, the heat sinks 120 collide with each other in the process of passing the air between the heat sinks 122 through the spaces between the heat sinks 122 as the heat sinks 122 are alternately arranged between the other heat sinks 122. Turbulence can be formed, whereby a more uniform heat dissipation effect can be obtained.

As described above, in the present embodiment, the radiator 120 may be in contact with and radiated with moving air by natural convection, and the heat sink 122 may be disposed at one side of the enclosure 110 of the transformer 100 to improve cooling efficiency. At least one blowing fan for blowing air to the air may be further provided.

Blowing fan may be provided to forcibly blow the air between the heat sink 122 of the radiator 120. In this embodiment, the blowing fan is described as being installed on one side of the enclosure 110, but the installation position of the blowing fan is not limited, and may be changed to various positions to improve the fluidity of the air. For example, the blower fan may be installed at one side of the radiator 120, and may be disposed to blow air in a direction orthogonal to the heat sink 122.

Referring to the operation of the transformer 100 configured as described above are as follows.

The transformer 100 transforms and transmits the voltage of the supplied electric power. The power supplied to the transformer 100 is transformed by the power device including the core and the coil and is sent out. In this process, a large amount of heat is generated. The heat generated by the power device is cooled by the insulating oil contained in the enclosure 110 of the transformer 100, and thus the temperature of the insulating oil is increased.

Insulating oil is supplied to an upper support part connected to the enclosure 110, that is, the first upper support part 112 and the second upper support part 114. In addition, the insulating oil supplied to the first upper support part 112 and the second upper support part 114 is supplied to the upper header pipe 124 and then supplied to the radiator 120 to radiate heat by contact with air.

In addition, the insulating oil is cooled while heat is radiated in the process of passing through the radiator 120, and then is discharged to the lower header pipe 126 connected to the lower portion. At this time, the radiator 120 absorbs the heat of the insulating oil and discharges it to the outside in the process of contacting the heat sink 122 with the air around the heat sink 122.

On the other hand, the radiator 120 is the upper header pipe 124 and the lower header pipe 126, both ends between the first and second upper support parts 112 and 114, and the first and second lower support parts 113 and 115, respectively. It is connected to the supporting structure, thereby ensuring durability even when external forces such as earthquakes, external shocks and vibrations are transmitted, thereby maintaining a stable coupling state.

The present invention described above is capable of various substitutions, modifications, and changes without departing from the spirit of the present invention for those skilled in the art to which the present invention pertains. It is not limited by.

100: transformer 110: enclosure
112: first upper support 114: second upper support
113: first lower support 115: second lower support
120: heat sink 122: heat sink
124: upper header pipe 126: lower header pipe

Claims (8)

An enclosure accommodating an internal power device and accommodating insulating oil for insulation of the internal power device;
A plurality of radiators installed on at least one side of the enclosure to cool the insulating oil which is heated and discharged from the enclosure;
A plurality of upper header pipes respectively installed on upper sides of the radiators to supply the insulating oil discharged from the enclosure to the radiators;
A lower header pipe installed at a lower side of the radiator to collect the insulating oil cooled through the radiator;
A plurality of upper support parts installed at an upper side of the enclosure and coupled to both ends of the upper header pipe to support both ends of the upper header pipe; And
It is installed on the lower side of the enclosure, a plurality of lower support portions coupled to both ends of the lower header pipe for supporting both ends of the lower header pipe;
The heat radiator may include a plurality of heat sinks spaced apart from each other, and the upper header pipe and the lower header pipe may be disposed to have the same length direction as that of the heat sink.
The insulating oil is discharged to one upper support part of the plurality of upper support parts by one radiator unit of the plurality of radiators, and is transferred to the radiator through the upper header pipe, and the insulating oil passing through the radiator is the plurality of lower headers. It flows into one lower header pipe of the pipe and returns to the enclosure through one lower support part far from the one upper support part of the plurality of lower support parts.
And a transformer in which the insulating oil is not transferred to the other upper support part of the plurality of upper support parts and the other upper support part of the plurality of lower support parts.
delete The method of claim 1,
The upper support is
Each end is connected to the upper side of the enclosure, each other end is extended to the outside of the enclosure, the vertical coupling with both ends of the upper header pipe
Transformers.
The method of claim 3,
The lower support is
One end of each of which is connected to the lower side of the enclosure, and the other end of which extends outward of the enclosure to vertically engage both ends of the lower header pipe.
Transformers.
delete delete The method of claim 1,
The heat sink is
Transformers that are offset from the heat sinks of other adjacent radiators.
The method of claim 1,
The transformer further comprises at least one blower fan provided on one side of the enclosure for blowing air to the heat sink.

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