KR20090045531A - Apparatus for automatic welding of radiator board for transformer - Google Patents

Abstract

The present invention relates to a heat dissipating plate automatic welding device for a transformer that can automatically and easily weld the connecting holes of the heat dissipating plate constituting the radiator.

The present invention is the frame 20 which is disposed perpendicular to the upper sides of the base 10, respectively; A jig lifting platform 30 and a welding lifting platform 40 respectively installed on the front center and the upper part of the frame 20 so as to be liftable; A jig 50 provided at an upper portion of the jig lifting platform 30 to support a connection part 2b of the heat sink 2a; A pressing plate 60 installed rotatably in a vertical line on the frame 20 to closely connect the connecting portions 2b of the heat sink 2a stacked up and down; A pair of heat absorbing rings 70 installed rotatably on a horizontal line on the frame 20 and fitted between the connecting portions 2b of the heat sinks 2a stacked up and down; A pair of welding torches 80 rotatably installed on the welding platform 40 to weld connecting portions of the connecting holes 2c stacked up and down; A motor (M1) (M2) for operating the jig lifting table 30 and the welding torch 80, respectively; It comprises a cylinder (C1) (C2) (C3) for operating the welding platform 40, the pressing plate 60 and the heat absorption ring 70, respectively.

Transformer, Radiator, Heat Sink, Connector, Automatic Welding Device, Welding Torch

Description

Heat sink automatic welding device for transformer {apparatus for automatic welding of radiator board for transformer}

The present invention relates to a heat sink automatic welding device for a transformer, and more particularly, to a heat sink automatic welding device for a transformer that can easily and easily automatically weld the connection hole of the heat sink constituting the radiator.

In general, the transformer generates heat due to the magnetic action of the current, and due to this heat, the internal pressure of the transformer gradually rises with the rise of the temperature of the insulating oil, and eventually an explosion damage and the deterioration of the insulating oil cause insulation damage and dielectric breakdown. Done.

In order to prevent such a phenomenon, a radiator for radiating heat to the outside of the transformer is essentially attached. Therefore, heat generated in the transformer is transferred to the radiator by the insulating oil, and the radiator cools the insulating oil by the outside air, thereby preventing the transformer from overheating.

1 and 2, the transformer radiator 2 attached to the outside of the transformer case 1 is composed of a plurality of heat sinks 2a, and connecting portions are provided at both upper and lower sides of the heat sink 2a. (2b) protrudes, the connection portion (2b) is formed with a connection hole (2c) to serve as an oil passage, the connection hole (2c) of the heat dissipating plate (2a) facing each other is connected by welding.

However, in the prior art, since the connection parts 2b of the heat sinks 2a face each other and the connection parts 2b are fixed to each other by welding, the worker directly welds the connection parts of the connection holes 2c by hand. There was a problem that productivity and workability are greatly reduced.

That is, in the prior art, since the worker welded the connection part of the connection hole 2c by hand by welding the connection parts 2b of the heat sinks 2a to each other, the welding work is very inconvenient and difficult, resulting in overall productivity and workability. There was a problem that mass production is difficult to fall largely, and in particular, because a large amount of time and manpower is required, there is a problem that the manufacturing cost and cost greatly increase economically.

In addition, in the related art, since the connection holes 2c of the heat dissipation plates 2a are manually welded as described above, it is difficult to weld the connection parts constantly and smoothly, thereby lowering the precision of welding. There was a problem of leakage that the insulation oil flows to the outside because it is not bunched and airtight.

An object of the present invention is to invent the conventional drawbacks as described above, by simply and easily automatically welding the connection hole of the heat sink constituting the radiator to greatly improve the productivity and workability at the same time economically manufactured Reduces cost and cost, and improves the precision of welding by uniformly and smoothly welding the joints of the connecting parts, and thereby prevents product defects and maintains airtightness to prevent leakage of insulating oil to the outside. It is to provide an automatic welding device for heat sink for transformer.

In order to achieve the above object, the present invention vertically arranges the frame on both sides of the base, respectively, and installs the jig lifter and the welding lifter on the front center and the upper part of the both frame so as to lift, respectively, on the upper part of the jig lifter. A jig for supporting each side connection part of the heat sink is installed, and a pressing plate for closely contacting the connection parts of the heat sinks stacked up and down on both frames is rotatably installed in a vertical line. A pair of heat absorption rings to be fitted are rotatably installed on a horizontal line, and a pair of welding torches are rotatably installed to weld the connection portions of heat sink connecting holes stacked up and down on the welding platform.

The heat dissipation plate automatic welding device for transformer of the present invention can easily and easily automatically weld the connection holes of the heat dissipation elements constituting the radiator to greatly improve productivity and workability and economically reduce manufacturing cost and cost. We can improve the precision of welding by welding the connection part of the connector uniformly and smoothly. Through this, it prevents the defect of the product and maintains the airtightness, thereby preventing the leakage of insulating oil to the outside. .

Hereinafter, the technical configuration of the present invention according to the accompanying drawings in detail.

Heat dissipating plate automatic welding device for a transformer of the present invention, as shown in Figure 3 to 21, the frame 20 which is disposed vertically on each upper side of the base 10; A jig lifting platform 30 and a welding lifting platform 40 respectively installed on the front center and upper portions of both side frames 20 so as to be liftable; Jig 50 is provided on each of the upper side jig lifting table 30 to support the connecting portion (2b) of the heat sink (2a); Press plates 60 which are rotatably installed on both sides of the frame 20 in a vertical line to closely contact the connecting portions 2b of the heat sinks 2a stacked up and down; A pair of heat absorbing rings 70 installed on both sides of the frame 20 so as to be rotatable on a horizontal line and fitted between the connecting portions 2b of the heat sinks 2a stacked up and down; A pair of welding torches 80 rotatably installed on both side welding platforms 40 to weld connecting portions of the connecting holes 2c stacked up and down; A motor (M1) (M2) for operating the jig lifting table 30 and the welding torch 80, respectively; The welding platform 40, the pressure plate 60 and the heat absorbing ring 70, including the cylinder (C1) (C2) (C3) for operating each of the basic features in its technical configuration.

Here, the base 10 is disposed on the floor to support both sides of the frame 20, as shown in Figures 3 and 7a, the upper and front of the base 10 is provided with a rail 11, and also the base ( The rack 12 is provided at the upper front of the 10). At this time, a support 13 for supporting the motor M1 is installed at the upper portion of the vertical column 13a on the other side of the base 10.

The frame 20 is disposed vertically on both sides of the base 10, respectively, the jig lifting platform 30, the welding lifting platform 40, the jig 50, the pressing plate 60, The heat absorption ring 70 and the welding torch 80 are respectively installed.

The one side (left side in FIG. 3) frame 20 is fixedly installed so as not to move from side to side on the top of the base 10, the other side (right side in FIG. 3) frame 20 is the base ( It is connected to the rail 11 of the 10 to move left and right, the pinion 20a that is engaged to the rack 12 of the base 10 is rotatably installed on the other frame 20, the pinion 20a Is connected to the handle 20b. Therefore, when the handle 20b is turned clockwise or counterclockwise, the other frame 20 moves left and right along the rail 11, and as a result, the other frame (according to the size (length) of the heat sink 2a) By adjusting the left and right positions of the 20) it is possible to freely adjust the distance of both frames (20).

The both sides of the frame 20 is provided with a screw rod 21 for elevating the jig platform 30 and a rail 22 for guiding the elevating of the jig platform 30, respectively, the upper part of the screw rod 21 is helical A gear box 23 having gears 23a and 23b is installed, a screw rod 21 is installed in the helical gear 23a, and a drive shaft connected to the motor M1 in the helical gear 23b. 24 is built up. At this time, the both gear box 23 is provided with a guide (23c) for accurately guiding the stacking position of the upper heat sink (2a) stacked on top of the lower heat sink (2a) supported by the jig (50).

And both sides of the frame 20 is provided with a rail 25 for guiding the lifting of the welding platform 40, respectively, and on both sides of the frame 20 to support the pressing plate 60 and the heat absorption ring 70 ( 26 are provided respectively.

The jig lifting platform 30 is respectively installed to be elevated in the front center portion of the both sides of the frame 20, these two jig lifting platform 30 is connected to the screw rod 21 by screwing as shown in Figure 9b and 9c A female screw 31 is provided.

The welding platform 40 is respectively installed to be elevated on the upper side of the frame 20, both of the welding platform 40 is meshed with the drive gear 41 connected to the motor (M2) welding torch 80 The driven gear 42 for rotating the positive and negative is provided, the cylinder (C1) is connected to the upper portion of the two welding platform 40. Accordingly, when the motor M2 is driven, the welding torch 80 rotates through the driving gear 41 and the driven gear 42 as shown in FIG. 10B, and when the cylinder C1 is operated, the welding platform 40 is operated. And the welding torch 80 is moved up and down.

The jig 50 is provided on both sides of the jig lifting platform 30 to support both connecting portions 2b of the heat dissipation plate 2a. The jig 50 has connection parts 2b of the heat dissipating plate 2a. Grooves are formed. Accordingly, as shown in FIGS. 15A and 15B, the heat sinks 2a are placed on the both sides of the jig 50, and another upper part is mounted on the lower heat sinks 2a mounted on the jig 50 as shown in FIGS. 16A and 16B. When the heat sink 2a is placed, two heat sinks 2a are stacked up and down. At this time, the upper heat dissipation plate 2a stacked on the upper side of the lower heat dissipation plate 2a supported by both jig 50 is accurately stacked in the correct position by the guide 23c as shown in FIGS. 16A and 16B.

The pressing plate 60 is rotatably installed on the frame 20 in a vertical line to closely contact the connecting portions 2b of the heat sink 2a stacked up and down. The pressing plate 60 is attached to the pressing plate 60 in FIGS. 11 and 12a and 12b. As in the horizontal axis 61 is rotatably connected to the bracket 26 of the frame 20 is provided, one end of the lever 62 is connected to the horizontal axis 61, the other end of the lever 62 cylinder ( C2) is connected. Accordingly, when the cylinder C2 is operated, the pressing plate 60 operates as shown in FIGS. 12A and 12B and FIGS. 17A and 17B while pressing down the heat sink 2a stacked on the top thereof, whereby the heat sink stacked vertically. The connecting portions 2b of 2a are in close contact with each other.

The pair of heat absorption rings 70 are rotatably installed on both sides of the frame 20 so as to fit between the connecting portions 2b of the heat sinks 2a stacked up and down as shown in FIGS. 18A and 18B. The pair of heat absorption rings 70 are rotatably connected to each other through a vertical axis 71 connected to the bracket 26 of the frame 10 as shown in FIGS. 11 and 13a and 13b, and a pair of heat absorption rings ( One end of the lever 72 is connected to each other 70, and a cylinder C3 is connected to the other end of the lever 72. Accordingly, when the cylinder C3 is operated, a pair of heat absorption rings 70 are sandwiched between the connecting portions 2b of the heat dissipation plates 2a stacked up and down while operating as shown in FIGS. 13A and 13B and 18A and 18B. , The pair of heat absorbing ring 70 absorbs heat in order to prevent the opening of a hole in the connection portion of the connection hole (2c) during welding. At this time, the pair of heat absorption ring 70 is made of a copper material so as to easily absorb the heat generated during welding.

The pair of welding torches 80 are rotatably installed at both welding platforms 40 to CO2 weld the connecting portions of the connecting holes 2c stacked up and down, and the pair of welding torches 80 are welded. CO2 welding of the connecting portions of the connecting holes 2c stacked up and down while rotating by the starting motor M2, the drive gear 41 and the driven gear 42, and the welding rod is provided to the pair of welding torches 80 during welding. It is supplied automatically. At this time, the pair of welding torch 80 is rotated while drawing a semi-circular trajectory about 180.6 ° by the motor (M2) during welding, CO2 welding the connecting portion of the connecting hole (2c) stacked up and down, a pair of welding When the torch 80 rotates about 180.6 ° half a turn and welding is completed, driving of the motor M2 is automatically stopped.

Meanwhile, according to the present invention, the inner diameter L1 of each of the upper connecting holes 2c provided in the upper and lower connecting portions 2b of the heat sink 2a stacked up and down as shown in FIG. 21 is the inner diameter of the lower connecting hole 2c. It is formed larger than (L2). At this time, the pair of welding torch 80 to weld the "A" portion shown in Figure 21, the "A" portion shown in Figure 21 forms a connection portion of the connecting hole (2c) stacked up and down.

The motor M1 is fixedly installed on the support 13 of the base 10 to move the jig lifting platform 30 up and down, and the driving shaft 24 is connected to the motor M1 as shown in FIGS. 9A and 9B. do. Therefore, when the motor M1 is driven, the drive shaft 24 is driven at the same time. When the drive shaft 24 is driven, the helical gear 23b is driven at the same time. When the helical gear 23b is driven, the helical gear 23a is driven. When the helical gear 23a is driven at the same time and the helical gear 23a is driven, the screw rod 21 is driven. As a result, the jig lifting table 30 having the female screw 31 screwed to the screw rod 21 is female thread 21. It moves up and down by. At this time, when the motor M1 is driven in the forward direction, the jig platform 30 is lowered. When the motor M1 is driven in the reverse direction, the jig platform 30 is reversed.

The motor M2 is fixed to each of the two welding platform 40 to drive the welding torch 80 to 180.6 ° forward and backward, such a motor (M2) drive gear 41 as shown in Figure 10a, 10b Connected. Accordingly, when the motor M2 is driven, the drive gear 41 is driven. When the drive gear 41 is driven, the driven gear 42 is driven at the same time. When the driven gear 42 is driven, the welding torch 80 is driven. As a result, when the motor M2 is driven in the forward and reverse direction, the welding torch 80 rotates through the drive gear 41 and the driven gear 42 in the 180.6 ° forward and reverse direction.

The cylinders C1 are respectively installed on the upper sides of the two side frames 20 as shown in FIGS. 10A and 10B, and the welding platform 40 is connected to the cylinders C1. Accordingly, when the cylinder C1 is operated, the welding platform 40 and the pair of welding torches 80 move up and down.

The cylinders C2 are installed in the brackets 26 of both frames 20 as shown in FIGS. 11 and 12A and 12B, respectively, and a lever 62 is connected to the cylinders C2. Therefore, when the cylinder C2 is operated, the horizontal axis 61 connected to the lever 62 rotates, and when the horizontal axis 61 rotates, the pressing plate 60 rotates at the same time. As a result, when the cylinder C2 is operated, While the pressing plate 60 operates as shown in FIGS. 12A and 12B and FIGS. 17A and 17B, the heat sink 2a stacked on the upper side is pressed downward, whereby the connecting portions 2b of the heat sink 2a stacked up and down are in close contact with each other. do.

The cylinders C3 are installed in the brackets 26 of both frames 20 as shown in FIGS. 11 and 13A and 13B, and the levers 72 are connected to the cylinders C3. Therefore, when the cylinder C3 is operated, the lever 72 is operated, and when the lever 72 is operated, a pair of heat absorption rings 70 are operated at the same time around the vertical axis 71, resulting in a cylinder ( When C3) is operated, a pair of heat absorbing rings 70 is inserted between the connecting portions 2b of the heat sink 2a stacked up and down while operating as shown in FIGS. 13A, 13B and 18A, 18B, whereby a pair of rows Absorption ring 70 absorbs heat generated during welding to prevent the opening of the connection portion of the connection hole (2c).

In the drawings, reference numeral 90 denotes a controller, which automatically controls the operation of a pair of welding torches 80, motors M1, M2, and cylinders C1, C2, C3. do.

The process and operation relationship of welding the connection holes (2c) of the heat sink (2a) constituting the heat sink (2) with the heat dissipation plate automatic welding device for a transformer of the present invention configured as described above will be described in detail.

First, before the operation, the distance between the two frames 20 is precisely preset by adjusting the position of the other frame 20 according to the size and the welding position of the heat sink 2a to be welded. The controller 90 is preset when the pair of welding torches 80 are rotated to be exactly 180.6 ° by the motor M2, and when the jig lifting platform 30 is lowered to stack the next heat sink 2a after welding. And by the motor (M1) is set in advance so that the jig lifting platform 30 is accurately lowered only by the height of the heat sink (2a).

Then, as shown in FIGS. 15A and 15B, the connecting portions 2b of the heat dissipating plate 2a are sandwiched and supported respectively on the upper sides of the jig 50, and the lower heat dissipating plate 2a supported by the jig 50 as shown in FIGS. 16A and 16B. When another heat sink 2a is stacked on the upper portion of the heat sink 2a, the connection portion 2b and the connection hole 2c of the heat sink 2a stacked vertically face each other precisely by the guides 23c of the gear boxes 23 on both sides. do. At this time, the pressing plate 60 is maintained vertically as shown in Figs. 16a, 16b, the pair of heat absorption ring 70 is maintained in the open state as shown in Figs. 16a, 16b, the pair of The welding torch 80 remains elevated as shown in FIGS. 16A and 16B.

After the two heat sinks 2a are stacked up and down on the top of the jig 50, and the cylinder C2 is operated by the controller 90 in this state, the pressing plate 60 is driven by the lever 62 and the horizontal shaft 61. Since the heat sink 2a stacked on the upper side is pressed downward while rotating as shown in Figs. 17A and 17B, the connecting portions 2b of the heat sink 2a stacked up and down as a result are in close contact with each other.

After operating the cylinder C2 and pressing the connecting portions 2b of the heat sinks 2a stacked up and down by pressing the pressing plate 60 to bring them into close contact with each other, in this state, when the cylinder C3 is operated by the controller 90, the lever ( 72 is operated, the pair of heat absorbing ring 70 by the lever 72 is rotated about the vertical axis 71 as shown in Figs. 18a, 18b, the connecting portion 2b of the heat sink 2a stacked up and down Sandwiched between

After operating the cylinder C3 and inserting a pair of heat absorption rings 70 between the connecting portions 2b of the heat sink 2a stacked up and down, and then operating the cylinder C1 with the controller 90 in FIGS. 19A and 19B As described above, the welding platform 40 moves downward along the rail 25, and as a result, the pair of welding torches 80 installed on the welding platform 40 simultaneously move downwards and connect the stacked holes (up and down). The connection part of 2c) is lowered to the position where it can weld correctly.

When the pair of welding torches 80 are moved downward by the cylinder C1 to a position at which the connecting portions of the connecting holes 2c stacked up and down can be accurately welded, the motor 90 is then controlled by the controller 90. Is automatically driven, and a welding rod is automatically supplied to the pair of welding torches 80 by the controller 90.

As described above, when the motor M2 is driven, the drive gear 41 is driven simultaneously. When the drive gear 41 is driven, the driven gear 42 is driven at the same time. When the driven gear 42 is driven, a pair of welding torches ( As the 80 rotates simultaneously, as a result, the pair of welding torches 80 rotates while drawing a semi-circular trajectory of approximately 180.6 degrees by the motor M2 to accurately weld the connecting portions of the connecting holes 2c stacked up and down. Done. At this time, the heat generated during welding is absorbed by the pair of heat-absorbing ring 70 sandwiched between the connecting portion (2b) of the heat sink (2a) and released to the outside, so that a hole in the connecting portion of the connecting hole (2c) during welding Is prevented.

When the pair of welding torches 80 rotate about 180.6 ° half a turn and the welding is completed, the driving of the motor M2 and the supply of the welding rods are automatically stopped by the controller 90, and also by the controller 90. C1) is operated so that the welding platform 40 moves upward along the rail 25 as shown in FIGS. 20A and 20B.

After the welding is completed, the driving of the motor M2 and the supply of the welding rod are stopped, and the welding platform 40 is raised to its original state. When the motor M1 is driven in the forward direction by the controller 90, the driving shaft 24 simultaneously When the drive shaft 24 is driven, the helical gear 23b is driven at the same time. When the helical gear 23b is driven, the helical gear 23a is driven at the same time. When the helical gear 23a is driven, the screw rod 21 is driven. ), The jig lifting platform 30 with the female thread 31 screwed to the threaded rod 21 as a result of the height of the heat sink 2a by the female screw 21 as shown in Figure 20a, 20b The rail 22 moves downward accurately. At this time, when the jig lifting platform 30 is moved downward exactly by the height of the heat sink 2a, the driving of the motor M1 is automatically stopped by the controller 90.

When the jig lifting platform 30 moves to the bottom, as shown in FIGS. 20A and 20B, another heat sink 2a is stacked on the top of the heat sink 2a, and the following welding operation is sequentially performed while going through the same process as described above. When the welding of the heat sinks 2a is completed, the welded heat sink 2a is pulled out and the jig lifting platform 30 is raised as the first time. The connection hole 2c of (2a) can be welded simply and easily automatically.

Therefore, according to the present invention, the heat sinks 2a are sequentially stacked on the upper part of the jig 50, and a pair of welding torches 80 can weld the connection portions of the connection holes 2c automatically and simply. This has the advantage of greatly improving productivity and workability.

In addition, according to the present invention there is an advantage that can be mass-produced as a whole because it can automatically improve the productivity and workability by automatically welding the connecting portion of the connection hole (2c), in particular time and personnel through automatic welding Since it can reduce the manufacturing cost and cost can be economically reduced.

In addition, according to the present invention, since the connection part of the connection hole 2c is automatically welded by a pair of rotating welding torches 80, the connection part can be welded constantly and smoothly, thereby improving the precision of welding. There is an advantage that can be made, thereby preventing the defect of the product and at the same time has the advantage to prevent the leakage of insulating oil to the outside by maintaining the airtight.

1 is a perspective view showing an installation state of the radiator for transformer.

Figure 2 is an exploded perspective view showing a heat sink structure of the radiator.

3 is a perspective view of the present invention.

4 is a front view of the present invention.

5 is a side view of the present invention.

6 is a plan view of the present invention.

Figure 7a, 7b is an exemplary view showing a coupling state of the base and the frame according to the present invention.

8 is a perspective view showing the main portion of the present invention.

Figure 9a, 9b, 9c is an exemplary view showing a jig lifting platform according to the present invention.

10a, 10b is an exemplary view showing a welding platform according to the present invention.

11 is a perspective view showing a pressing plate and a heat absorption ring according to the present invention.

12a, 12b is an exemplary view showing an operating state of the pressing plate according to the present invention.

Figure 13a, 13b is an exemplary view showing an operating state of the heat absorption ring according to the present invention.

14a to 20b is an exemplary view showing an operating state of the present invention.

Figure 21 is a cross-sectional view of the heat sink showing the welded state in accordance with the present invention.

<Code Description of Main Parts of Drawing>

2: heat sink 2a: heat sink

2b: connection part 2c: connection hole

10: base 20: frame

30: jig platform 40: welding platform

50: jig 60: pressing plate

70: heat absorption ring 80: welding torch

M1, M2: Motor C1, C2, C3: Cylinder

Claims (7)

Frames 20 which are respectively disposed perpendicular to the upper sides of the base 10; A jig lifting platform 30 and a welding lifting platform 40 respectively installed on the front center and the upper part of the frame 20 so as to be liftable; A jig 50 provided at an upper portion of the jig lifting platform 30 to support a connection part 2b of the heat sink 2a; A pressing plate 60 installed rotatably in a vertical line on the frame 20 to closely connect the connecting portions 2b of the heat sink 2a stacked up and down; A pair of heat absorbing rings 70 installed rotatably on a horizontal line on the frame 20 and fitted between the connecting portions 2b of the heat sinks 2a stacked up and down; A pair of welding torches 80 rotatably installed on the welding platform 40 to weld connecting portions of the connecting holes 2c stacked up and down; A motor (M1) (M2) for operating the jig lifting table 30 and the welding torch 80, respectively; Automatic welding device for a heat sink for the transformer comprising a cylinder (C1) (C2) (C3) for operating the welding platform 40, the pressing plate 60 and the heat absorption ring (70), respectively. According to claim 1, The one side frame 20 is fixed to the upper portion of the base 10, the upper portion of the base 10 is provided with a rail 11 and the rack 12, the other side frame 20 ) Is movably connected to the rail 11 from side to side, the other frame 20 is rotatably installed on the pinion (20a) to be fitted to the rack 12, the handle (20b) to the pinion (20a) Heat sink automatic welding device for a transformer, characterized in that the connection. According to claim 1, The frame 20 is provided with a screw rod 21 for elevating the jig lifting platform 30 and the rail 22 for guiding the lifting, the helical gear (top) of the screw rod (21) A gear box 23 having 23a and 23b is installed, a screw rod 21 is installed in the helical gear 23a, and a drive shaft 24 connected to the motor M1 in the helical gear 23b. This is installed, the jig lifting platform 30 is a heat sink automatic welding device for a transformer, characterized in that the female screw 31 is connected to the screw rod 21 by screwing. According to claim 1, wherein the frame 20 is provided with a rail 25 for guiding the lifting of the welding platform 40, the welding platform 40 is engaged with the drive gear 41 connected to the motor (M2). Heat sink automatic welding device for a transformer characterized in that the driven gear 42 for rotating the welding torch 80 in the forward and reverse direction is installed. According to claim 1, wherein the pressing plate 60 is provided with a horizontal axis 61 rotatably connected to the bracket 26 of the frame 20, one end of the lever 62 is connected to the horizontal axis 61 Heat dissipating plate automatic welding device for a transformer, characterized in that the cylinder (C2) is connected to the other end of the lever (62). According to claim 1, wherein the pair of heat absorption ring 70 is rotatably connected to each other through a vertical axis 71 connected to the bracket 26 of the frame 10, the pair of heat absorption ring 70 One end of the lever 72 is connected to each other, the heat sink automatic welding device for a transformer, characterized in that the cylinder (C3) is connected to the other end of the lever (72). The inner diameter (L1) of the upper connecting hole (2c) provided in each of the upper and lower connecting portions (2b) of the heat dissipating plate (2a) is laminated larger than the inner diameter (L2) of the lower connecting hole (2c). Heat sink automatic welding device for a transformer, characterized in that formed.

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