CN219349935U - Radiator structure - Google Patents

Abstract

The utility model relates to the technical field of heat dissipation equipment, in particular to a radiator structure, which comprises two brackets and a heat dissipation assembly, wherein each bracket is provided with a plurality of mounting holes, the heat dissipation assembly comprises a heat dissipation pipeline, a pump body, a liquid inlet pipe, a liquid outlet pipe, a first box body, a second box body, a connecting pipe and a heat absorption unit, the first box body and the second box body are sequentially arranged on the brackets, two ends of the liquid outlet pipe are respectively communicated with one side of the second box body and the heat dissipation pipeline, the heat absorption unit is arranged in the first box body and the second box body, the radiator structure is arranged on one side of a transformer through the mounting holes of the brackets, the heat dissipation pipeline is enabled to be in contact with the transformer to absorb heat, cooling liquid enters the second box body from the liquid outlet pipe to dissipate heat, then enters the first box body through the connecting pipe to dissipate heat for the second time, finally the cooling liquid is pumped into the liquid outlet pipe under the driving of the pump body to return to the heat dissipation pipeline, and the temperature of the transformer is repeatedly circulated, so that the transformer is effectively cooled.

Description

Radiator structure

Technical Field

The utility model relates to the technical field of heat dissipation equipment, in particular to a radiator structure.

Background

In the working process of the transformer, a large amount of heat can be generated, the performance of the transformer is very affected, if the heat is not dissipated in time, the transformer is damaged, and the service life is shortened.

Prior art patent CN206907611U discloses a transformer radiator, installs the transformer into the machine case, and the top of machine case is equipped with the supporting seat, and the supporting seat articulates there is the rocker, and the top of rocker is equipped with the air-plate, and the air-plate drives the connecting rod, and the connecting rod transmits the action to the extension board, and the extension board can be driven and produce the swing, drives the air around, makes the flow velocity of nearby air accelerate for the heat that produces in the machine case is taken away by the air, realizes the cooling heat dissipation of transformer from this.

However, in the prior art, only the wind power generated by swinging is relied on, so that the heat dissipation effect is poor, the transformer cannot be effectively cooled, and the temperature of the transformer cannot be effectively controlled within a reasonable range.

Disclosure of Invention

The utility model aims to provide a radiator structure, which solves the problems that in the prior art, the radiating effect is poor, the transformer cannot be cooled effectively and the temperature of the transformer cannot be controlled within a reasonable range only by wind power generated by swinging.

In order to achieve the above object, the present utility model provides a radiator structure including two brackets and a radiating member, each of the brackets having a plurality of mounting holes;

the heat dissipation assembly comprises a heat dissipation pipeline, a liquid inlet pipe, a liquid outlet pipe, a first box body, a second box body, a connecting pipe and a heat absorption unit, wherein the first box body and the second box body are sequentially arranged on the support, the first box body is communicated with the second box body through the connecting pipe, two ends of the liquid inlet pipe are respectively communicated with the liquid outlet end of the pump body and the heat dissipation pipeline, the liquid inlet end of the pump body is communicated with one side of the first box body, two ends of the liquid outlet pipe are respectively communicated with one side of the second box body and the heat dissipation pipeline, and the heat absorption unit is arranged in the first box body and the second box body.

The heat dissipation assembly further comprises two connecting blocks, one ends of the two connecting blocks are fixedly connected with the heat dissipation pipeline, and the other ends of the two connecting blocks are respectively fixedly connected with the corresponding support and positioned on one side of the support.

The heat absorption unit comprises a plurality of heat absorption copper columns and a plurality of heat absorption copper plates, wherein the two ends of each heat absorption copper column are fixedly connected with the first box body, and are sequentially distributed in the first box body, and the heat absorption copper plates are fixedly connected with the second box body and are staggered in the second box body.

The radiator structure further comprises two reinforcing components, and the two reinforcing components are sequentially arranged on one side of the first box body and one side of the second box body.

The reinforcing component comprises a shell and two cooling fans, wherein the shell is fixedly connected with the first box body and is positioned on one side of the first box body away from the cooling pipeline, and the two cooling fans are fixedly connected with the shell and are sequentially positioned on one side of the shell.

According to the radiator structure disclosed by the utility model, the radiating pipeline is in contact with the transformer and absorbs heat, cooling liquid enters the second box body from the liquid outlet pipe after circulating for a circle in the radiating pipeline, the heat of the cooling liquid is absorbed by the absorption unit, the temperature of the cooling liquid is reduced, then the cooling liquid enters the first box body through the connecting pipe to be cooled for the second time, finally the cooling liquid is pumped into the liquid outlet pipe under the driving of the pump body and returns to the radiating pipeline again, and the cooling liquid is repeatedly circulated to continuously absorb the temperature of the transformer through the arrangement of the structure, so that the transformer is effectively cooled, the radiating effect is good, and the temperature of the transformer can be effectively controlled.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below.

Fig. 1 is a schematic overall structure of a first embodiment of the present utility model.

Fig. 2 is an overall cross-sectional view of a first embodiment of the present utility model.

Fig. 3 is a cross-sectional view taken along line A-A of fig. 2 in accordance with the present utility model.

Fig. 4 is a schematic overall structure of a second embodiment of the present utility model.

Fig. 5 is an overall cross-sectional view of a second embodiment of the present utility model.

101-support, 102-mounting hole, 103-heat dissipation pipeline, 104-pump body, 105-feed liquor pipe, 106-drain pipe, 107-first box, 108-second box, 109-connecting pipe, 110-connecting block, 111-heat absorption copper post, 112-heat absorption copper plate, 201-casing, 202-radiator fan.

Detailed Description

The following detailed description of embodiments of the utility model, examples of which are illustrated in the accompanying drawings and, by way of example, are intended to be illustrative, and not to be construed as limiting, of the utility model.

First embodiment:

referring to fig. 1 to 3, fig. 1 is a schematic overall structure of a first embodiment of the present utility model, fig. 2 is a sectional overall view of the first embodiment of the present utility model, and fig. 3 is a sectional view of fig. 2 along line A-A of the present utility model.

The utility model provides a radiator structure, which comprises two brackets 101 and a radiating component, wherein each bracket 101 is provided with a plurality of mounting holes 102, the radiating component comprises a radiating pipeline 103, a pump body 104, a liquid inlet pipe 105, a liquid outlet pipe 106, a first box 107, a second box 108, a connecting pipe 109, a heat absorbing unit and two connecting blocks 110, the heat absorbing unit comprises a plurality of heat absorbing copper columns 111 and a plurality of heat absorbing copper plates 112, the problems are solved through the scheme, and the scheme can be used for a transformer heat radiating and cooling scene and also can be used for solving the heat radiating and cooling problems of a motor.

For the present embodiment, each of the brackets 101 has a plurality of mounting holes 102, and the radiator structure is mounted on one side of the transformer through the mounting holes 102 of the brackets 101.

The first box 107 and the second box 108 are sequentially arranged on the support 101, the first box 107 and the second box 108 are communicated through the connecting pipe 109, two ends of the liquid inlet pipe 105 are respectively communicated with a liquid outlet end of the pump body 104 and the heat dissipation pipeline 103, a liquid inlet end of the pump body 104 is communicated with one side of the first box 107, two ends of the liquid outlet pipe 106 are respectively communicated with one side of the second box 108 and the heat dissipation pipeline 103, and the heat absorption unit is arranged in the first box 107 and the second box 108. The heat dissipation pipeline 103 contacts with the transformer and absorbs heat, after the cooling liquid circulates in the heat dissipation pipeline 103 for a week, the cooling liquid enters the second box 108 from the liquid outlet pipe 106, the heat of the cooling liquid is absorbed by the absorption unit, the temperature of the cooling liquid is reduced, then the cooling liquid enters the first box 107 through the connecting pipe 109 for second cooling, finally the cooling liquid is pumped into the liquid outlet pipe 106 under the driving of the pump body 104, and returns to the heat dissipation pipeline 103 again, and the cooling liquid repeatedly circulates to continuously absorb the temperature of the transformer, so that the transformer is cooled effectively.

Secondly, one ends of the two connection blocks 110 are fixedly connected with the heat dissipation pipeline 103, and the other ends of the two connection blocks 110 are respectively fixedly connected with the corresponding support 101 and are positioned on one side of the support 101. The connection block 110 mounts the heat dissipation pipe 103 on the bracket 101, so as to improve the stability of the heat dissipation pipe 103.

Meanwhile, two ends of the heat absorbing copper columns 111 are fixedly connected with the first box 107 and sequentially distributed inside the first box 107, and the heat absorbing copper plates 112 are fixedly connected with the second box 108 and are staggered inside the second box 108. The heat absorbing copper plates 112 can absorb heat, meanwhile, the time that the cooling liquid flows in the second box 108 can be prolonged through staggered distribution, meanwhile, after the heat absorbing copper columns 111 are distributed in sequence, the cooling liquid flows among the heat absorbing copper columns 111 and is fully contacted with the heat absorbing copper columns 111, and the heat absorbing copper columns 111 can effectively absorb the heat of the cooling liquid, so that the cooling effect is achieved.

When the heat dissipation device is used for dissipating heat of a transformer, firstly, the radiator structure is arranged on one side of the transformer through the mounting hole 102 of the bracket 101, then the radiating pipeline 103 is in contact with the transformer and absorbs heat, after the cooling liquid circulates in the radiating pipeline 103 for a circle, the cooling liquid enters the second box 108 from the liquid outlet pipe 106, the heat can be absorbed through the heat absorption copper plates 112, meanwhile, the time of flowing the cooling liquid in the second box 108 can be prolonged, the temperature of the cooling liquid is reduced through staggered distribution, then the cooling liquid enters the first box 107 through the connecting pipe 109 for second cooling, the cooling liquid flows among the plurality of heat absorption copper columns 111 and is fully contacted with the cooling liquid, the cooling liquid effectively absorbs the heat of the cooling liquid, finally, the cooling liquid is pumped into the liquid outlet pipe 106 under the driving of the pump body 104 and returns to the radiating pipeline 103, and the cooling liquid is repeatedly circulated through the structure, the temperature of the transformer is continuously absorbed, and therefore the transformer is effectively cooled.

Second embodiment:

on the basis of the first embodiment, please refer to fig. 4 and 5, wherein fig. 4 is a schematic overall structure of the second embodiment of the present utility model, and fig. 5 is a sectional overall view of the second embodiment of the present utility model.

The utility model provides a radiator structure, which also comprises two reinforcing components, wherein the reinforcing components comprise a shell 201 and two radiating fans 202.

For the present embodiment, two reinforcement assemblies are sequentially disposed on one side of the first case 107 and the second case 108. The reinforcing component can cool down the cooling liquid, and the cooling speed is improved.

The casing 201 is fixedly connected with the first casing 107, and is located at a side of the first casing 107 away from the heat dissipation pipeline 103, and the two heat dissipation fans 202 are fixedly connected with the casing 201, and are sequentially located at one side of the casing 201. The housing 201 has water therein to absorb the temperature of the coolant, and the cooling fan 202 continuously blows air to the housing 201 to reduce the temperature of the water.

When the transformer is used for radiating heat, the shell 201 is internally provided with water, so that the temperature of cooling liquid can be absorbed, meanwhile, the cooling fan 202 continuously blows air to the shell 201, the temperature of the water is reduced, and meanwhile, the water can continuously absorb the temperature of the cooling liquid in the first box 107 and the second box 108, so that the cooling effect is improved.

The foregoing disclosure is only illustrative of one or more preferred embodiments of the present application and is not intended to limit the scope of the claims hereof, as it is to be understood by those skilled in the art that all or part of the process of implementing the described embodiment may be practiced otherwise than as specifically described and illustrated by the appended claims.

Claims (5)

1. A radiator structure comprises two brackets, each bracket is provided with a plurality of mounting holes, and is characterized in that,

the heat dissipation assembly is also included;

the heat dissipation assembly comprises a heat dissipation pipeline, a pump body, a liquid inlet pipe, a liquid outlet pipe, a first box body, a second box body, a connecting pipe and a heat absorption unit, wherein the first box body and the second box body are sequentially arranged on the support, the first box body is communicated with the second box body through the connecting pipe, two ends of the liquid inlet pipe are respectively communicated with the liquid outlet end of the pump body and the heat dissipation pipeline, the liquid inlet end of the pump body is communicated with one side of the first box body, two ends of the liquid outlet pipe are respectively communicated with one side of the second box body and the heat dissipation pipeline, and the heat absorption unit is arranged inside the first box body and the second box body.

2. The heat sink structure of claim 1, wherein,

the heat dissipation assembly further comprises two connecting blocks, one ends of the two connecting blocks are fixedly connected with the heat dissipation pipeline, and the other ends of the two connecting blocks are respectively fixedly connected with the corresponding support and positioned on one side of the support.

3. The heat sink structure of claim 2, wherein,

the heat absorption unit comprises a plurality of heat absorption copper columns and a plurality of heat absorption copper plates, wherein two ends of each heat absorption copper column are fixedly connected with the first box body, and are sequentially distributed in the first box body, and the heat absorption copper plates are fixedly connected with the second box body and are staggered in the second box body.

4. The heat sink structure of claim 3, wherein,

the radiator structure further comprises two reinforcing components, and the two reinforcing components are sequentially arranged on one side of the first box body and one side of the second box body.

5. The heat sink structure of claim 4, wherein,

the reinforcing component comprises a shell and two cooling fans, wherein the shell is fixedly connected with the first box body and is positioned on one side of the first box body away from the cooling pipeline, and the two cooling fans are fixedly connected with the shell and are sequentially positioned on one side of the shell.

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