KR100773027B1 - Radiator for transformer - Google Patents

Abstract

A radiator for a transformer is provided to reduce management cost for maintenance and repair by replacing a damaged radiating member by the piece without replacing the whole radiator. A radiator for a transformer(101) includes a header pipe(103), a plurality of radiating members, a sealing cap(109), and a coupling device. The header pipe is coupled at the upper and lower parts of a transformer body(102), and circulates an insulating oil. The radiating member has radiating flanges at both ends, and radiating plates(107) separately welded at upper and lower connection pipes having through holes to connect the path of the radiating plate on which the insulating oil flows with the through holes of the upper and lower connection pipes. The sealing cap is bolt-coupled at the radiating flange of the last radiating plate among the radiating plates connected to the header pipe, and closes the through hole. The coupling device couples the radiating plates to the header pipe.

Description

Radiator for transformers

1 is a perspective view showing the appearance of a radiator for a transformer according to the present invention.

2 is a view showing a heat radiating member of the radiator according to the present invention.

Figure 3 is a view showing a state in which a plurality of heat dissipation members are installed adjacent to the present invention.

Figure 4 is a view showing the structure of a radiator for a conventional transformer.

<Description of the symbols for the main parts of the drawings>

101: transformer 102: main body

103: header pipe 104: heat dissipation flange

105: through hole 106: connector

107: heat sink 108: heat dissipation member

109: closing cap 110: the first coupling hole

111: connection flange 112: second coupling hole

113: fixing bolt 114: fixing nut

115: drain valve 116: connecting member

The present invention relates to a radiator for a transformer comprising a header pipe coupled to one side, the bottom of the main body of the transformer to communicate the insulating oil, in particular, due to the inherent vibration generated in the transformer and overheating and aging of the insulating oil If any one of the heat sink is damaged, by replacing only the heat dissipation member including the damaged heat sink is related to a radiator for a transformer to reduce the maintenance cost consumed in the heat sink of the transformer, eliminating the trouble of replacement work.

In general, the inside of the transformer generates heat by the action of electric current, and due to this heat, the pressure inside the transformer gradually rises with the temperature rise of the insulating oil. Therefore, if the state of overheating and pressure increase continues, the explosion accident and the deterioration of the insulating oil will eventually occur. This causes insulation damage and breakdown.

In order to prevent this phenomenon, a heat radiator is attached to one side of the main body of the transformer so that heat generated inside the transformer is transferred to the radiator by the insulating oil, and the radiator prevents the transformer from being overheated by allowing the insulating oil to be cooled by the fan or the outside air. It was.

Transformers installed to increase or decrease the voltage of transmission and distribution lines are important components of the power system and play a very important role for stable supply of power.

The inside of the transformer is filled with insulating oil to prevent the insulation power from deteriorating due to moisture or dust in the winding of the transformer, and is configured to radiate heat generated from the winding by convection or radiation of the oil.

Therefore, the heat dissipation effect of the radiator leads to an improvement in the performance of the transformer, so that the stable operation of the transformer is maintained only when the heat dissipation efficiency of the heat radiation is high.

In general, the radiator used is a heat sink 1 formed of a pair of panels overlapped to form an insulating flow path as shown in FIG. 4, and the heat sink 1 is provided on one side of the main body 3 of the transformer 2. It consists of a pair of header pipes 4 installed in parallel with each other, and a plurality of heat sinks 5 installed in communication between the header pipes 4.

However, the conventional radiator as described above has a coupling structure in which the heat dissipation plate 1 is heat-exchanged with the outside air and is integrally welded to the header pipe 4, so that a welded area to which a pair of panels are joined is deteriorated over time. Due to the inherent vibration generated by the transformer 2 itself, it is often ruptured or opened, causing a problem of leakage of insulating oil.

Accordingly, since the entire heat sink including the plurality of heat sinks 2 is replaced in the transformer 2 by the damaged or damaged heat sink 1, a problem arises in that the maintenance cost increases.

The present invention devised to solve the above problems is to provide a radiator for a transformer to reduce the replacement cost by only replacing the damaged heat sink even if the welded portion of the heat sink is broken or broken.

The above object is, in the radiator for a transformer 101 including a header pipe 103 coupled to the lower portion of the main body 102, one side of the transformer 101 to communicate the insulating oil, the heat radiation flange 104 at both ends ) Is formed, and a plurality of heat sinks 107 are welded to the upper and lower connection pipes 106a and 106b having the through hole 105 spaced apart from each other, and the flow path of the heat sink 107 through which the insulating oil flows, and the upper and lower connection pipes. A heat dissipation member 108 for allowing the through holes 105 of the 106a and 106b to communicate with each other; A closing cap 109 which is bolted to the heat dissipation flange 104 of the last heat dissipation member 108 of the heat dissipation member 108 connected from the header pipe 103 to close the through hole 105; The radiating member 108 is achieved by a radiator for a transformer 101, characterized in that it comprises a coupling means of the radiating member to be coupled to the header pipe 103 in a structure that is adjacently coupled to each other.

Herein, the coupling means of the heat dissipation member includes: a plurality of first coupling holes 110 formed in the heat dissipation flange 104; A second coupling hole 112 formed at a connection flange 111 formed at an end of the header pipe 103; A fixing bolt 113 penetrating through the first coupling hole 110 and the second coupling hole 112; And a fixing nut 114 fastened to the fixing bolt 113 penetrating through the first coupling hole 110 or the second coupling hole 112.

In addition, it is preferable to further include a drain valve 115 formed in the lower connection pipe 106b of the heat dissipation member 108 to discharge the insulating oil.

Hereinafter, the configuration and operation of the present invention will be described with reference to FIGS. 1 and 2.

As shown in FIG. 1, the radiator for the transformer 101 according to the present invention is for preventing overheating of the insulating oil filled in the transformer 101, so that the insulating oil in the main body 102 can be circulated. On one side of the 102, it is installed in the header pipe 103 coupled to the bottom.

First, referring to the structure of the heat dissipation member 108 and the structure of the heat dissipation plate 107 to allow the insulating oil to exchange heat with the outside, a flow path for allowing the insulating oil to flow to the upper and lower sides as shown in FIGS. (Not shown) is formed therein, and this flow path can be manufactured by forming a groove inside a pair of panels and welding the pair of panels together, and the structure of the heat sink 107 is known. Because of the configuration, the detailed description and drawings will be omitted.

In addition, looking at the coupling structure of the connection pipe 106 and the heat dissipation plate 107 of the heat dissipation member 108, the cutting oil discharged through the upper header pipe 103 on the upper and lower ends of the heat dissipation plate 107 The upper and lower connecting pipes 106a and 106b in which the through holes 105 are formed in a direction (orthogonal to the flow path) corresponding to the diameter direction of the header pipe 103 so as to be guided to the flow path of the 107 are formed. Each is welded.

That is, a plurality of heat sinks 107 are welded to the outer diameter of the lower connection pipe 106b so that flow paths formed in the respective heat sinks 107 communicate with the through holes 105 of the connection pipe 106. The heat radiation member 108 is configured by connecting the upper connection pipe 106a to the upper end of the heat sink 107.

The coupling means of the heat dissipation member for coupling the plurality of heat dissipation members 108 having the structure as described above to the header pipe 103 is connected to the first heat dissipation member 108a as shown in FIGS. 1 and 2. The heat dissipating flange 104 of the tube 106 abuts the connection flange 111 of the header pipe 103, and then the heat dissipating flange 104 of the connection pipe 106 of the second heat dissipating member 108b is disposed on the first heat dissipating member. A plurality of heat dissipation members 108 are adjacent to each other by abutting the connection tube 106 heat dissipation flange 104 of 108.

In the connection flange 111 of the heat dissipating flange 104 and the header pipe 103, a plurality of first coupling holes 110 and second coupling holes 112 are formed at positions corresponding to each other, and thus, fixing bolts 113 After passing through the first coupling hole 110 and the second coupling hole 112, a plurality of heat dissipation members 108 are adjacent to each other by fastening the fixing nut 114 to the fixed fixing bolt 113. Can be installed.

Here, the upper and lower heat dissipation flange 104 of the last heat dissipation member (108c) of the heat dissipation member (108), respectively, the closing cap 109 bolting coupling so as to close the through hole 105 of the connection pipe 106 As a result, it is preferable that the finishing cap 109 is bolted by the fixing bolt 113 penetrating the first coupling hole 110 and the second coupling hole 112.

In addition, when the drain valve 115 is to be coupled to the lower connection pipe 106b of at least one of the heat dissipation members 108 to replace the heat dissipation member 108, the drain valve ( It is preferable to open the 115 so that the cutting oil filled in the heat sink 107 flow path can be discharged in advance.

On the other hand, the plurality of heat dissipation member 108, as shown in Figure 3 (not shown in the fixing bolt 113 and the fixing nut 114 in Figure 3) finishing cap 109 and a plurality of heat dissipation Another embodiment is also employed in which the connecting member 116 is bolted to the connecting flange 111 of the header pipe 103 after being bolted to the connecting member 106 and the connecting member 116. Although it may be, these means and other embodiments can be easily devised by the present invention, and the present invention is not limited thereto because it does not correspond to the gist of the present invention.

In addition, the sealing member (O-ring) may be interposed between any one heat radiation flange 104 and another heat radiation flange 104 according to the manufacturer's intention, so as to ensure airtightness between the heat radiation members 108. desirable.

According to the present invention having the above-described configuration, the insulating oil discharged to the upper header pipe 103 while the insulating oil of the main body 102 of the transformer 101 is heated is provided with a plurality of connection pipes 106, a through hole 105, and a heat sink 107. The circulation cycle flowing into the main body 102 through the lower header pipe 103 is repeated.

Therefore, when any one of the welded portion in the heat sink 107 is ruptured or damaged during use and needs replacement, the closing valve (not shown) installed in the upper and lower header pipes 103 may be closed in some cases. After the insulating oil inside the main body 102 is blocked from flowing into the heat dissipation member 108, the drain valve 115 coupled to the lower connection pipe 106 b is opened to discharge all the insulating oil from the heat dissipating plate 107.

Then, the fixing nut 114 is dismantled from the fixing bolt 113 so that each heat dissipation member 108 is separated from each other, and after replacing only the heat dissipation member 108 to be replaced, all the heat sinks 107 are described above. Recombination to the header pipe 103 by the coupling means of the heat radiation member.

As described above, after the replacement operation is completed, the drain valve 115 is closed, the opening and closing valve of the header pipe 103 is opened, and the body 102 is filled with insulating oil to dissipate the heat sink 107 or the heat dissipation member ( 108 will be able to complete the replacement or repair work.

As described above, the present invention removes only the broken or damaged heat dissipation member 108 and additionally combines the new heat dissipation member 108, thereby minimizing waste of the heat dissipation plate 107.

On the other hand, the horizontal bar and the connecting bar shown in Figures 2 and 3 are to suppress the vibration of the radiator by the vibration of the transformer 101 as much as possible, which is a known configuration, because it does not correspond to the subject matter of the present invention Detailed description will be omitted.

As described above, when the heat sink is broken, the present invention can replace the heat sink including the broken heat sink individually without replacing the entire heat sink, thereby reducing the management cost of maintenance of the heat sink. Has

Claims (3)

In the radiator for a transformer comprising a header pipe coupled to the lower portion of the main body of the transformer to communicate the insulating oil, Heat dissipation flanges are formed at both ends, and the heat dissipation member is welded so that a plurality of heat dissipation members are spaced apart from each other in the upper and lower connection pipes through which the through-holes are formed so that the through-holes of the heat dissipation plate through which the insulating oil flows are communicated with each other; A closing cap bolted to the heat dissipation flange of the last heat dissipation member of the heat dissipation member connected to the header pipe to close the through hole; And a coupling means of the heat dissipation member to be coupled to the header pipe in a structure in which the heat dissipation members are adjacent to each other. The method of claim 1, Coupling means of the heat dissipation member, A plurality of first coupling holes formed in the heat dissipating flange; A second coupling hole formed in a connection flange formed at an end of the header pipe; A fixing bolt penetrating the first coupling hole and the second coupling hole; And a fixing nut fastened to the fixing bolt penetrated by the first coupling hole or the second coupling hole. The method of claim 1, And a drain valve formed in the lower connection pipe of the heat dissipation member to discharge the insulating oil.

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