KR101480049B1 - device for manufacturing cooling duct for transformer coil - Google Patents

Abstract

The present invention relates to an apparatus to manufacture a coil cooling duct for a transformer, which attaches and fixates upper insulating paper on a cooling duct where a duct is attached and fixated on lower insulating paper at a predetermined interval. The apparatus to manufacture a coil cooling duct for a transformer comprises: an upper insulating paper supply wheel which is installed in the upper part of the cooling duct moving horizontally and has wound upper insulating paper; an upper insulating paper supply unit which is formed with a tension wheel which is installed in the upper side of a part where the cooling duct and the upper insulating paper are in contact with each other; an adhesive coating unit which is installed between the upper insulating paper supply wheel and the upper insulating paper tension wheel and coats the bottom of the upper insulating paper with adhesive; a press wheel which is installed in the rear side of the tension wheel and rotates in order to continuously press the cooling duct to which the upper insulating paper is attached; and a press unit which is formed with a press wheel spring which adds a pressure to the press wheel downwards so that the press wheel is not separated from the cooling duct to which the upper insulating paper is attached by being formed in the upper wheel part of the press wheel.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a coil cooling duct manufacturing apparatus for a transformer,

The present invention relates to an apparatus for manufacturing a coil cooling duct for a transformer, and more particularly, to an apparatus for manufacturing a cooling duct having an upper insulating sheet adhered to an upper portion of a duct fixed to an upper portion of a lower insulating sheet by an automatic apparatus.

Generally, a cooling duct is a component that cools the heat generated inside a winding constituting a transformer.

The transformer includes a primary winding and a secondary winding, and a housing for accommodating the winding, wherein the high voltage supplied through the mains lead can be used in a power consumer such as a factory and a home, Is filled with insulating oil having an insulating property for cooling the heat generated in the heat exchanger.

In order to allow the insulating oil to pass through the winding, a cooling duct is provided between the winding layer and the winding layer during the winding of the primary and secondary coils, so that the insulating oil moves through the space formed by the duct, Increase.

These conventional cooling ducts are made by manual processes, resulting in a huge loss of labor, a lack of quality accuracy, a high product defect rate, and an extremely low productivity. In addition, there is also a problem that a large amount of workforce is required to manufacture such a cooling duct.

In order to solve such a problem, Korean Patent No. 10-0346139 discloses a 'cooling duct automatic bending system' capable of manufacturing a cooling duct by an automatic apparatus.

However, the conventional art has the problem that the insulating paper is attached only to the lower part of the duct, and there is a limit to the insulating effect during use, and there is a high possibility that the duct is separated from the insulating paper during use.

In order to solve such a problem, a cooling duct having an upper insulating paper, a manufacturing apparatus and a manufacturing method thereof, as disclosed in Korean Patent No. 10-1100680, is disclosed.

This conventional invention increases the insulation effect by attaching the insulating paper to the upper part of the duct, thereby improving the durability by reducing the possibility of separating the duct from the insulating paper.

However, the conventional invention has a problem that when an adhesive is applied to insulating paper using a roller, it is not uniformly applied.

In addition, in the method of performing adhesion by using a conventional press, there is a problem that when the position of the duct is deviated, the entire process is stopped and the operation speed is slowed down.

Korean Patent No. 10-0346139 (July 12, 2002) Korean Registered Patent No. 10-1100680 (December 23, 2011)

The apparatus for manufacturing a coil cooling duct for a transformer according to the present invention is intended to provide a coil cooling duct manufacturing apparatus for a transformer which can uniformly apply an adhesive to an upper insulating paper and continuously pressurize and adhere the cooling duct.

The apparatus for manufacturing a coil cooling duct for a transformer according to the present invention is an apparatus for manufacturing a coil cooling duct for a transformer in which an upper insulating paper is adhered and fixed to a cooling duct in which ducts are adhered and fixed to a lower insulating paper at regular intervals, An upper insulating paper feeding wheel which is installed on an upper portion of the upper insulating paper feeding wheel and has an upper insulating paper feeding wheel on which the upper insulating paper is wound and a tension wheel installed on an upper surface of the cooling duct and the upper insulating paper, An adhesive application unit installed between the tension wheels and applying an adhesive to the bottom surface of the upper insulating paper; a pressing wheel installed at the rear of the tension wheel and rotating to continuously press the cooling duct to which the upper insulating paper is adhered; A press wheel formed on the shaft of the press wheel, And a press wheel unit that presses the press wheel in a downward direction so as not to be separated from the cooling duct to which the sub-insulating paper is adhered.

Preferably, the adhesive application unit includes an adhesive sprayer for spraying an adhesive to the bottom surface of the upper insulating paper, a tank for storing the adhesive, and a pump for feeding the adhesive stored in the tank to the adhesive sprayer, The adhesive dispenser according to the present invention is characterized in that the adhesive dispenser includes a scattering prevention chamber for covering the end portion of the injector and the upper insulating paper coated with the adhesive sprayed from the injector to prevent the adhesive from scattering in all directions, And a collecting chamber connected to a lower portion of the collecting chamber.

More preferably, the press wheel is formed with grooves corresponding to the shape of the cooling duct to which the upper insulating paper is adhered on the outer circumferential surface, wherein a tension wheel spring is formed on the tension wheel shaft, And presses the tension wheel in a downward direction so as not to be separated from the cooling duct to which the upper insulating paper is adhered.

Still more preferably, the press unit further comprises a brush provided at the rear of the press wheel and provided with a foreign matter reservoir at a lower portion thereof.

1 is a front view showing a conventional cooling duct automatic bending system.
2 is a schematic view showing an apparatus for manufacturing a coil cooling duct for a transformer according to the present invention.
3 is a front view showing an upper insulating paper supply unit and an adhesive applying unit of the coil cooling duct manufacturing apparatus for a transformer according to the present invention.
4 is a front view showing a press unit of a coil cooling duct manufacturing apparatus for a transformer according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The present invention relates to an apparatus for manufacturing a coil cooling duct for a transformer that allows easy passage of insulating oil through a coil for a transformer, thereby enhancing cooling efficiency.

First, prior to describing the present invention, a conventional apparatus for manufacturing a cooling duct as shown in Fig. 1 will be described. FIG. 1 is a front view of a conventional cooling duct automatic bending system, in which a duct 60 is fixed and bonded to an upper portion of a lower insulating paper 40 to produce a cooling duct 20.

3 is a front view showing an upper insulating sheet feeding unit and an adhesive feeding unit of the apparatus for manufacturing a coil cooling duct for a transformer according to the present invention, and FIG. 4 is a front view of the apparatus for manufacturing a coil cooling duct for a transformer according to the present invention. As shown in the front view of the press unit of the coil cooling duct manufacturing apparatus for a transformer according to the present invention, the upper insulating sheet feeding unit 100, the adhesive applying unit 200, and the press unit 300 are constituted by a cooling duct The upper insulating paper 80 is adhered to the upper portion of the upper insulating paper 20.

The upper insulating paper supply unit 100 will be described. The upper insulating paper supply unit 100 includes an upper insulating paper supply wheel 120 and a tension wheel 140.

The upper insulating paper feed wheel 120 is wound by the upper insulating paper 80 and connected to the shaft of the upper insulating paper feed wheel 120 by an upper insulating paper feed wheel motor (80) to the upper part of the cooling duct (20).

The tension wheel 140 is installed on the upper surface where the cooling duct 20 and the upper insulating paper 80 are in contact with each other. The tension wheel 140 maintains the upper insulating paper 80 between the upper insulating paper supply wheel 120 and the lower insulating paper 80 so that an adhesive sprayed from the adhesive sprayer 220, . A tension wheel spring 142 is formed on the upper portion of the shaft of the tension wheel 140 so as to apply pressure to the tension wheel 140 in a downward direction so that the upper insulating paper 80 is closely attached to the upper portion of the cooling duct 20, Thereby forming the cooling duct 20 having the upper insulating paper.

The adhesive applying unit 200 will be described below. The adhesive application unit 200 includes an adhesive injector 220, an adhesive supply unit 240, a scattering prevention chamber 260, and a collection chamber 280.

The adhesive injector 220 is installed between the upper insulating paper supply wheel 120 and the tension wheel 140 and injects adhesive to the bottom surface of the upper insulating paper 80. The adhesive sprayer 220 can apply the adhesive to the bottom surface of the upper insulating paper 80 more uniformly than to apply the adhesive to the upper insulating paper 80 by applying an adhesive to the conventional roller.

The adhesive feeder 240 consists of a tank 242 and a pump 244.

The tank 242 is connected to a pump 244, which will be described later. The tank 242 is formed in the form of a rectangular box having an internal space, and stores the adhesive therein. The tank 242 is connected to the pump by a pipe and supplies an adhesive to the pump 244 so that the adhesive sprayer 220 can spray the adhesive due to the pump 244.

The pump 244 is connected by a tube between the adhesive sprayer 220 and the adhesive tank 242 so that the adhesive stored in the adhesive tank 242 is sent to the adhesive sprayer 220.

The shatterproof chamber 260 surrounds the upper insulating paper 80 to which the adhesive sprayed from the adhesive sprayer 220 and the adhesive sprayed from the adhesive sprayer 220 are applied. The shake-proof chamber 260 has a rectangular box shape. A lower portion of the shake-preventing chamber 260 has an insertion port through which the end of the adhesive sprayer 220 is inserted, and a hole through which the upper insulating paper 80 can pass is formed on both sides And a discharge port connected to the collection chamber 280, which will be described later, are formed. The shatterproof chamber 260 is sealed so that the adhesive sprayed from the adhesive sprayer 220 is prevented from scattering and is applied only to the upper insulating paper 80.

The collection chamber 280 is formed in the shape of a rectangular box which is connected to the lower part of the scatter preventive chamber 260 and is detachable. The collection chamber 280 is filled with residual adhesive injected from the inside of the anti-scattering chamber 260. The collection chamber 280 removes the adhesive stored in the fog prevention chamber 260 when a certain amount of the adhesive is stored therein.

The press unit 300 will be described. The press unit 300 is composed of a press wheel 320, a press wheel spring 340, and a brush 360.

The press wheel 320 is installed at the rear of the tension wheel 140 and has a groove 322 formed on the outer circumferential surface of the press wheel 320 so as to correspond to the duct 60 and is rotated by a press wheel motor . The press wheel 320 is closely attached to the upper surface of the cooling duct 20 to which the upper insulating paper 80 is adhered and applies pressure so that the cooling duct 20 and the upper insulating paper 80 are more closely attached. In addition, by continuously applying pressure to the cooling duct 20 to which the upper insulating paper 80 is adhered, the pressure is continuously applied while the cooling duct 20 to which the upper insulating paper 80 is adhered moves to reduce the production time give.

The press wheel spring 340 is formed on the shaft of the press wheel 320 so as to press the press wheel 320 downward so that the press wheel 320 is not separated from the cooling duct 20 having the upper insulating paper .

The brush 360 is fixed to the rear of the press wheel 320 so that the brush of the brush is in contact with the press wheel. The brush 360, which is in contact with the press wheel 320, removes foreign matter adhering to the outer circumferential surface of the press wheel 320 when the press wheel 320 rotates. The foreign matter removed by the brush 360 is provided in the lower portion of the brush 360 and the press wheel 320 in contact with the foreign matter storage container 362 so that the cooling duct 20 ) To prevent foreign matter from falling.

Hereinafter, the manufacturing process of the present invention will be described.

1, a cooling duct 20 having a duct 60 adhered and fixed to a top surface of a lower insulating paper 40 at predetermined intervals is manufactured and supplied to the manufacturing apparatus of the present invention. When the cooling duct 20 is supplied to the manufacturing apparatus of the present invention, the upper insulating paper feed wheel 120 is operated to move the upper insulating paper 80 to the tension wheel 140 via the inside of the scatter preventing chamber 260 . When the upper insulating paper 80 passes through the inside of the anti-scattering chamber 260, the adhesive injector 220 injects the adhesive toward the bottom of the upper insulating paper 80 from inside the anti-scattering chamber 260. The upper insulating paper 80 on which the adhesive is sprayed moves to the tension wheel 140 and meets the cooling duct 20. [ The upper insulating paper 80 on which the adhesive is sprayed on the bottom surface portion is brought into contact with the upper surface portion of the cooling duct 20 and the tension wheel 140 is pressurized so that the upper insulating paper 80 and the cooling duct 20 are in close contact with each other, The cooling duct 20 to which the heat exchanger 80 is adhered is formed. Thereafter, the cooling duct 20 to which the upper insulating paper 80 is adhered is moved to the lower portion of the press wheel 320. When the cooled duct 20 to which the moved upper insulating paper 80 is adhered is moved to the lower portion of the press wheel 320, the press wheel 320 rotates and the cooling duct 20 to which the upper insulating paper 80 is adhered The cooling duct 20 to which the upper insulating paper 80 is adhered by the groove 322 formed on the outer circumferential surface of the press wheel 320 formed to correspond thereto is pressed and adhered without a phenomenon that the position of the duct 60 is released.

When the upper insulating paper 80 is securely adhered and fixed to the upper surface of the cooling duct 20 by the rotation of the press wheel 320, the cooling duct 20, to which the upper insulating paper 80 is adhered, The adhesive and the pressurization are carried out while continuously moving without a step for stopping the pressurization.

As described above, according to the present invention, there is provided an apparatus for manufacturing a cooling duct in which an upper insulating paper is adhered to an upper surface of a cooling duct to which a duct is adhered and fixed to an upper surface of a lower insulating paper, And it is to be understood that the above-described embodiments are only examples, so that the true scope of the present invention should be determined by the appended claims.

20: cooling duct 40: lower insulating sheet
60: duct 80: upper insulating paper
100: upper insulating paper supply unit 120: upper insulating paper supply wheel
140: upper insulating paper tension wheel 200: adhesive supply unit
220: Adhesive sprayer 240: Adhesive supply part
242: Adhesive tank 244: Pump
260: Adhesive spraying chamber 280: Adhesive collecting chamber
300: Press unit 320: Press wheel
322: groove 340: press wheel spring
360: Brush 362: Dust receptacle

Claims (6)

An apparatus for manufacturing a coil cooling duct for a transformer in which an upper insulating paper (80) is adhered and fixed to a cooling duct (20) to which a duct (60) is adhered and fixed to a lower insulating paper (40)
The upper insulating paper feed wheel 120 is installed on the upper portion of the cooling duct 20 which moves horizontally and is wound around the upper insulating paper 80 and the upper insulating paper feed wheel 120 on which the cooling air duct 20 and the upper insulating paper 80 contact An upper insulating paper supply unit 100 comprising a tension wheel 140 installed on an upper surface thereof;
An adhesive applying unit 200 installed between the upper insulating paper supply wheel 120 and the upper insulating paper tension wheel 140 and applying an adhesive to the bottom surface of the upper insulating paper 80;
A pressing wheel 320 installed to the rear of the tension wheel 140 and rotating to continuously press the cooling duct 20 to which the upper insulating paper 80 is adhered, And a press wheel spring 340 that presses the press wheel 320 downward so that the press wheel 320 is not separated from the cooling duct 20 to which the upper insulating paper 80 is adhered, (300) for cooling a coil of the transformer. The method according to claim 1,
The adhesive application unit (200)
An adhesive sprayer 220 for spraying an adhesive to the bottom of the upper insulating paper 80,
An adhesive supply unit 240 comprising a tank 242 in which the adhesive is stored and a pump 244 for feeding the adhesive stored in the tank 242 to the adhesive sprayer 220. [ Duct manufacturing apparatus. 3. The method of claim 2,
The adhesive feeder 240 is configured to feed,
An anti-scattering chamber 260 for covering the end of the injector 220 and the upper insulating paper 80 coated with the adhesive sprayed from the injector 220 to prevent the adhesive from scattering in all directions, Further comprising a collection chamber (280) connected to a lower portion of the coil cooling duct (260). The method according to claim 1,
The press wheel (320)
And a groove (322) corresponding to the shape of the cooling duct (20) to which the upper insulating paper (80) is adhered is formed on the outer circumferential surface. The method according to claim 1,
A tension wheel spring 142 is formed on an upper portion of the axis of the tension wheel 140 so that the tension wheel 140 is rotated in a direction of the tension wheel 140 so as not to be separated from the cooling duct 20 to which the upper insulating paper 80 is adhered. Down direction of the coil cooling duct. The method according to claim 1,
The press unit (300)
Further comprising a brush (360) provided at the rear of the press wheel (320) and provided with a foreign matter storage container (362) at a lower portion thereof.

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