KR100755888B1 - Waterproof terminal of transformer - Google Patents

Abstract

The present invention relates to a waterproof terminal connected to the low pressure side of the transformer, the bushing is installed on one side of the casing of the transformer connected to the low pressure end; A bus bar having one end connected to an outer side of the bushing to which at least one cable is connected; And an insulating part for molding the bus bar.

Transformer, busbar, bushing, insulation, electric shock, short circuit

Description

Waterproofing Terminal of Distribution Transformer

1 is a perspective view for explaining the appearance of a transformer;

2 is a cross-sectional view illustrating a conventional terminal structure.

3 is an exploded cross-sectional view illustrating a conventional terminal structure.

4 is a front view (A) and a side view (B) for explaining the terminal structure according to the present invention.

5 is an exploded front view of each part for explaining the terminal structure according to the present invention;

6 is a perspective view for explaining a terminal structure according to the present invention;

7 is a cross-sectional view for explaining the structure of the connection tab in the present invention.

8 is a cross-sectional view for explaining the structure of the coupling terminal in the present invention.

Explanation of symbols on the main parts of the drawings

20 casing 21 inner cable

22: internal terminal 23: internal connection nut

30: bushing 31: insulator

32: center rod 40: bracket

41: bracket bolt 42: bracket nut

50: busbar 60: insulation

61 through hole 62 cap connection

63: cap 64: connection

66: connection tab 70: low voltage cable

72: coupling terminal 75: coupling bolt

The present invention relates to a waterproof terminal of the transformer, and more particularly to a waterproof terminal connected to the low pressure side of the transformer.

In general, a transformer is a voltage conversion device composed of a plurality of windings and a common iron core and applying an alternating voltage to one winding to induce a voltage proportional to the turn ratio to the other winding by an electromagnetic induction phenomenon.

In addition, power transformers are installed in transmission and distribution systems for the purpose of supplying power with little loss of energy from the power source to the consumer by changing the voltage and current.

The transformer consists of windings, iron cores, tanks, insulators, coolers and accessories, and converts voltage and current for efficient transportation and supplies them according to the customer's required voltage.

Insulation media used in transformers are classified into oil or SF ₆ gas, mold resin, air, and the like. Insulating oil is generally used (inflow transformer), but gas transformers using SF ₆ gas insulation media are also used. Dry transformers using mold resin or air as an insulating medium are widely used in indoors and buildings, but they are difficult to apply to power transformers due to high voltage limitations.

The classification of transformer is divided into general classification, classification of cooling method, and classification for use. The general classification is based on iron core structure, cooling medium, tap-changing method and number of windings. It is classified as gas type and it is classified by use purpose and technology by winding and iron core manufacturing technology, cooling technology, insulation technology, power supply and control technology, switching and emergency protection technology, and others (management and inspection technology).

Meanwhile, technologies related to transformers include iron core and winding technology, insulation technology, cooling technology, power supply and current control, stray load loss technology, and each technical field has the following characteristics.

(1) iron core and winding technology

Since the iron core used in the transformer is a passage for magnetic flux, one with a high permeability and less iron loss should be used.

Laminated layers of silicon steel with a silicon content of 0.35mm to 0.2mm with a silicon content of about 4% overlap each other. Silicon steel sheet is largely divided into non-oriented silicon steel sheet and oriented silicon steel sheet. However, transformers have a large number of oriented silicon steel sheets having a high permeability in the rolling direction and low iron loss. The iron core wound around the loop in the rolling direction is called a winding iron core, and is widely used as a core for transformers for columnar transformers because the excitation current can be reduced and the economic efficiency is good.

Iron cores of power transformers are usually three-phase, three- or three-phase five-membered structures, and have been developed by applying magnetic flux distribution and vibration analysis techniques. In particular, the three-phase pentagonal structure is a structure that lowers the height of the transformer. Recently, iron loss has been significantly reduced by applying amorphous iron cores.

In addition, the winding technology sets the method and conductor size of the winding according to the voltage and current to develop and apply the miniaturization and lightweight technology of the transformer.The winding method employs a high-capacity winding or a shielded continuous winding, which is ideal for lightning shock voltage. Winding technology has been applied to avoid.

Commonly used conductor windings are paper-insulated ones, but some windings use enameled conductors, and the winding technology in which the entire winding is molded into a bundle by curing the resin is applied to the transformer for distribution. have.

(2) insulation technology

Electrical insulation of transformer is made by transformer oil, insulating paper, resin and so on. In order to further optimize the insulation structure, low dielectric constant insulation paper is adopted to reduce the dielectric constant difference between oil and insulation paper to rationalize the electric field strength and distribution, thereby minimizing the transformer's miniaturization and insulation strength. In particular, the improvement of the insulation structure through application at the winding end of the low dielectric constant insulating paper has improved the breakdown voltage performance of about 20% compared to the conventional insulation structure. Insulation method that uses resin in insulation material by integrally molding with conductor is much higher than conventional dry transformer, and it is structurally strong and does not adopt oil.

Bushings are used to isolate the input and output terminals of a transformer. Single bushings are used for voltages below 30kV, and compound bushings are used for voltage ranges from 30kV to 77kV. Particularly, in the case of high voltage, an insulated tube is inserted between the magnetic insulator tube and the center conductor to fill the insulated bushing and the insulation paper and the metal foil are alternately wound around the conductor to form a capacitor to uniform the potential applied to the insulator. One capacitor bushing is used a lot.

(3) cooling technology

The cooling system for cooling the heat generated by the transformer should be selected according to the capacity of the transformer, the ambient conditions at the installation site and the operating conditions. Small capacity power distribution transformers use panel type radiators with increased heat dissipation area, and large capacity power transformers use forced cooling. The forced cooling method uses an oil cooler using a forced oil pump, an air cooler using an air circulation fan, or a water cooler using a water circulation pump, and a finned tubular cooler to increase heat exchange efficiency using a cooling medium. Is commonly used.

The panel radiator has a method of attaching the assembled panel to the tank and a method of directly processing the pleated cooling fins in the tank, the pleated cooling fins is a method of miniaturizing the transformer and saving oil.

In addition, the finned tubular cooler, which is a forced cooling method, is a method in which a tube is specially processed in duplicate and has a high cooling efficiency. In addition, in order to increase the cooling effect, the winding of the transformer also makes oil ducts to smooth the flow of oil, thereby preventing heat from imposed burial and maximizing the cooling effect.

(4) Power supply and current control, stray load loss technology

In large-capacity power transformers, stray load loss and local overheat generated in the conductor due to leakage magnetic flux generated from the winding act as a deterrent to power conversion efficiency. Therefore, measures to reduce such losses and overheating are necessary. To solve this problem, the leakage flux distribution and temperature rise are calculated by solving the magnetic flux distribution phenomenon by finite element method, differential method, magnetic moment method, and current vector potential method.

As shown in FIG. 1, a transformer having the technical characteristics as described above is typically provided with a casing 11 having a winding or the like embedded therein for power conversion and a side of the casing 11. It consists of a high voltage terminal 12 for connecting the high voltage terminal and the high voltage cable, and a low voltage terminal 13 installed on one side of the casing 11 to connect the low voltage terminal and the low voltage cable of the power conversion circuit.

When the transformer formed above is a ground-mounted transformer, the primary terminal (i.e., high voltage inlet terminal) is a relatively high voltage distribution voltage, and thus the outside of the terminal maintains a safe electrical insulation state, but the secondary terminal (i.e., low voltage) is used. In the case of a low voltage terminal for outputting a low voltage cable outputting a low voltage is relatively frequently made a problem that the electrical insulation state is not complete.

As a technique for solving this problem, there is a secondary terminal device of a transformer disclosed as Utility Model Publication No. 20-2000-0000170 on January 15, 2000.

As shown in FIGS. 2 and 3, the secondary terminal device of the transformer disclosed in the Utility Model Publication No. 20-2000-0000170 has one end portion 13a installed inside the casing 10. A center rod which is connected to the low voltage stage 19 of the power conversion circuit of the transformer 10 and the other end 13c is formed out of the casing 11 and an insulating material (for example, magnetic insulator) The center rod is formed in the center of the insulating bushing (13a) which is installed in contact with the casing (11).

The low voltage terminal 13 is fixed to the casing 11 by a bracket 14, a bolt (not shown) and a nut 15.

A bus bar 16 is connected to the other end 13a of the central rod.

A coupling portion 16a is formed at one side of the bus bar 16 so that the other end 13a of the central rod is inserted into and coupled to the coupling portion 16a. At this time, a fixing end is formed at one side of the outer circumferential surface of the other end 13a to secure the coupling, and the pin hole 16a formed at one side of the coupling part 16a has a fixing pin 16c in close contact with the fixing end. Insert it through and fix it.

On the other hand, the bus bar 16 is formed with a plurality of coupling holes (16d) for coupling a plurality of coupling terminals 18, each of which is connected to a plurality of low-voltage cables 17 with a bolt.

The conventional terminal device configured as described above is used to cover the bus bar 16 to protect the bus bar 16, so that it is somewhat safe in a rain situation, but the low voltage terminal when the transformer is installed and operated on the ground Since the outside of (13) and the lower end of the bus bar 16 is exposed to the outside, when the transformer is flooded in a rainy season or heavy rain, there is a problem that a short circuit is caused by incomplete insulation.

In particular, when a person is in contact with a transformer or a bus bar, there is a problem of risk of causing an electric shock accident.

It is an object of the present invention to provide a waterproof terminal of a transformer which prevents a short circuit or an electric shock by forming a waterproof structure that electrically insulates the low voltage terminal side of the transformer.

The present invention is a bushing installed on one side of the casing of the transformer is connected to the low-pressure end of the transformer, one end of the bus bar is connected to the outer side of the bushing and at least one cable is connected to achieve the above object; Insulating portion for molding the bus bar, the bus bar is formed with at least one coupling hole, the insulating portion is formed through holes penetrating at the same position as the coupling hole is received at one end of the cable to one side of the through hole To provide a waterproof terminal of the transformer connected to the coupling hole.

delete

The cable is connected to a coupling hole of the bus bar through a terminal having a first bolt or a first nut formed at one side thereof, and a second nut or a second bolt coupled to the first bolt or the first nut through the coupling hole. It is configured to further include, characterized in that the first nut or the second bolt is fastened through the other side of the through hole formed in the insulating portion.

The insulating part may be formed to further include a connection part extending from one side of the through hole and having a first screw part formed on an outer circumferential surface or an inner circumferential surface thereof.

The connection part may further include a connection tab, wherein a second screw part is formed at one end of the inner circumferential surface or the outer circumferential surface thereof and is screwed to the first screw part, and the inner circumferential surface of the other end is formed to be in close contact with the outer circumferential surface of the cable. .

The other end of the connection tab is formed with an inner diameter of at least two steps, it is possible to cut to match the outer diameter of the cable.

The insulating portion is characterized in that it further comprises a cap for sealing the other side of the through hole.

The insulating portion is characterized in that it further comprises a cap connecting portion extending to the other side of the through hole.

It characterized in that it further comprises a cap for sealing the cap connecting portion.

The cap connection portion or the cap is characterized in that the screw coupling or fitting.

The insulating portion is characterized in that made of a polymer material.

The present invention provides a contact portion between the cap and the cap connection portion, a contact portion between the connection tab and the cable, a contact portion between the connection tab and the connection portion, and a contact portion between the bushing and the insulation portion. Characterized in that it further comprises a filler to be filled.

The present invention made as described above can prevent the external exposure of the conductor due to the cable connection to prevent a short circuit or electric shock.

(Example)

The waterproof terminal of the transformer according to the present invention will be described in detail with reference to the accompanying drawings showing a preferred embodiment of the present invention.

4 is a front view (A) and a side view (B) for explaining the terminal structure according to the present invention, Figure 5 is an exploded front view of each part for explaining the terminal structure according to the present invention, Figure 6 Is a perspective view for explaining the structure of the terminal according to the present invention, Figure 7 is a cross-sectional view for explaining the structure of the connection tab in the present invention, Figure 8 is a cross-sectional view for explaining the structure of the coupling terminal in the present invention.

As shown in FIG. 4, the waterproof terminal of the transformer according to the present invention includes a bushing 30 fastened to the casing 20 of the transformer with a bracket 40, a bolt 41, and a nut 42, and the bushing ( 30 is connected to the bus bar 50 to which a plurality of low voltage cables 70 are connected, and insulating means for insulating the bus bar 50.

The bushing 30 has an inner end portion 32a and a bus bar at which a terminal 22 fixed to one end of a cable 21 connected to a low voltage end of a power conversion circuit installed inside a transformer is fixed by a nut 23. The center rod 32 including the outer end portion 32b to which the 50 is connected, and an insulating material (for example, magnetic material) are coupled to the middle outer peripheral surface of the center rod, and the bracket 40 is attached to the casing 20. It is composed of the insulator 31 is fastened by the).

In the case of the outer end portion 32b, the bus bar 50 is coupled to each other by pin coupling or screw coupling. In the embodiment of the present invention, pin coupling is described as an example. Coupling groove 32c is formed.

The bus bar 50 has a plate structure, and a plurality of joining holes (not shown) are formed (two rows and three columns in the embodiment of the present invention) and are formed at one end of the bushing 30. Coupling portion 52 is fastened to the center rod 32 of the hollow portion 53 is inserted into the outer end portion (32b) is formed.

In this case, since the bus bar 50 is connected to a plurality of low-voltage cables 70 to form a thickness considering the load and tension to prevent deformation.

The insulating part 60 is made of a polymer material and is molded to the bus bar 50.

In addition, through holes (not shown) are formed in upper and lower portions corresponding to the coupling holes, and cap connection parts 62 and connection parts 64 are formed at upper and lower ends of the through holes, respectively.

The cap connecting portion 62 is for waterproofing the space required when the low-voltage cable 70 is coupled to the coupling hole, the cap whose outer peripheral surface is fitted to the inner surface of the cap connecting portion 62 for sealing ( 63) is required.

Here, in the embodiment of the present invention, in order to seal the through-hole of the insulating portion 60, the cap connecting portion 62 is formed as described above and sealed with the cap 63, but in some cases the cap The upper end of the through hole may be sealed directly with the cap 63 without forming the connecting portion 62.

The connecting portion 64 extends at the lower end of the through hole, and a screw is formed on the outer circumferential surface (may be formed on the inner circumferential surface in some cases).

The connection tab 66 screwed to the connection portion 64 is for sealing the lower end of the through hole by bringing the inner circumferential surface into close contact with the outer circumferential surface of the low pressure cable 70.

To this end, at one end of the connection tab 66, a screw coupled to the screw formed on the contact portion 64 is formed on the inner circumferential surface (may be formed on the outer circumferential surface), the other end of the contact It is formed of a multi-stage inner diameter (in the embodiment of the present invention formed in three stage inner diameter) so that the inner diameter can be adjusted according to the outer diameter of the low-voltage cable 70 to be.

In other words, since the low voltage cable 70 generally uses a cable whose thickness is preset according to the power capacity, the inner diameter of the connection tab 66 is formed in multiple stages according to the outer diameter of the cable having a high frequency of use. A first portion 66a equal to the entire inner diameter of the connection tab 66, a second portion 66b extending to the first portion 66a and having a small inner diameter, and extending to the second portion 66b; And a third portion 66c formed with a smaller inner diameter.

At this time, the respective portions are connected to each other through an extension of the tapered structure, and the tapered portion should be formed at the end portion of the third portion 66c.

The tapered portions of the respective portions are in close contact with the outer circumferential surface of the low pressure cable 70.

Therefore, when cutting the lower portion according to the thickness of the low-voltage cable 70, the tapered portion should be cut so that the upper portion remains.

The low voltage cable 70 connected to the coupling hole of the bus bar 50 has a coupling nut 73 formed at one side thereof for easy fastening, and the coupling terminal 72 coupled to one end of the low pressure cable 70. Need.

The low voltage cable 70 connected to the coupling terminal 72 covers the connection tab 66 to contact the coupling hole of the bus bar 50 through the connection portion 64 extending below the through hole. The coupling bolt 75 is inserted through the cap connecting portion 62 to be fastened to the coupling nut 73.

Then, the connecting tab 66 is turned to engage with the connecting portion 64, and the cap 63 is covered with the cap 63 to seal the cap.

At this time, a contact portion between the cap 63 and the cap connecting portion 62, a contact portion between the connecting tab 66 and the low voltage cable 70, and between the connecting tab 66 and the connecting portion 64. A sealing material (for example, an adhesive or a filler that is changed from a liquid state to a solid state) is filled between a contact portion of the bushing and one side of the insulator 31 of the bushing 30 and a part of the insulating portion 60 in contact with it. It is preferable to bond each other to complete the sealing.

When the plurality of low voltage cables 70 are connected to the bus bar 50 as described above, the bus bar 50 is coupled to the outer end 32b of the bushing 30, and the pin 55 is connected to the bus. It is coupled to the pin hole (52a) formed in the coupling portion 52 of the bar 50 is in close contact with the pin coupling groove (32c) formed in the outer end portion (32b) to fasten each other firmly.

To this end, another pinhole for inserting the pin 55 into the insulating portion 60 corresponding to the position of the pinhole 52a formed in the coupling portion 52 of the bus bar 50 should be formed.

On the other hand, when the bus bar 50 and the bushing 30 is coupled to the pin 55 as described above, the pin 55 is made of a metal material, the pin 55 is the bus bar Since the contact with the 50 and the center rod 32 does not completely eliminate the risk of a short circuit or an electric shock, in order to prevent a short circuit or an electric shock, a pin cap connecting portion having a structure similar to the cap connecting portion 62 is formed, and the pin The cap connecting portion may be sealed with a pin cap.

Alternatively, the outer end portion 32b of the center rod 32 may be formed of a bolt, and the hollow portion 53 of the coupling portion 52 may be formed of a nut to screw each other together.

In the above description, the characteristics of the present invention have been described taking the connection relationship between the low voltage terminal and the low voltage cable as an example. However, in the case of a device in which the connection portion of the conductor is exposed to the outside, the present invention may be applied to other electric devices other than the transformer.

The present invention made as described above provides an effect of preventing the short-circuit or electric shock accidentally by preventing exposure of the low-voltage terminal of the transformer, and the bus bar connected thereto.

Claims (16)

Bushing is installed on one side of the casing of the transformer and connected to the low voltage stage of the transformer, A bus bar having one end connected to an outer side of the bushing and having at least one cable connected thereto; Insulating part for molding the bus bar, At least one coupling hole is formed in the bus bar, and the insulating part is formed with a through hole penetrating at the same position as the coupling hole, so that one end of the cable is received at one side of the through hole and connected to the coupling hole. Waterproof terminal of the transformer. delete 3. The cable of claim 2, wherein the cable is connected to a coupling hole of the bus bar through a terminal having a first bolt or a first nut formed on one side thereof, and coupled to the first bolt or the first nut through the coupling hole. And a second nut or a second bolt, wherein the first nut or the second bolt is fastened through the other side of the through hole formed in the insulating part. The waterproof terminal of claim 2 or 3, wherein the insulating part further comprises a connection part extending from one side of the through hole and having a first screw part formed on an outer circumferential surface or an inner circumferential surface. [5] The connecting tab according to claim 4, wherein the connecting portion has a second screw portion formed on one end of an inner circumferential surface or an outer circumferential surface thereof and is screwed to the first screw portion, and an inner circumferential surface of the other end is formed to be in close contact with the outer circumferential surface of the cable. Waterproof terminal of a transformer, characterized in that it comprises a. 6. The waterproof terminal of claim 5, wherein the other end of the connection tab is formed to have an inner diameter of at least two stages, and can be cut to fit the outer diameter of the cable. 6. The waterproof terminal of claim 5, further comprising a filler filled in a contact portion between the connecting portion and the connecting tab to improve sealing property. 6. The waterproof terminal of claim 5, further comprising a filler filled in a contact portion of the connection tab and the cable. The waterproof terminal of claim 2 or 3, wherein the insulation part further comprises a cap for sealing the other side of the through hole. 10. The waterproof terminal of claim 9, wherein the cap further comprises a filler filled in a contact portion of the through hole. 4. The waterproof terminal of claim 2 or 3, wherein the insulation part further comprises a cap connection part extending from the other side of the through hole. 11. The waterproof terminal of claim 10, further comprising a cap that seals the cap connecting portion. 12. The waterproof terminal of claim 11, wherein the cap connection part or the cap is screwed or fitted. 12. The waterproof terminal of claim 11, further comprising a filler filled in a contact portion between the cap connecting portion and the cap. The waterproof terminal of claim 1, wherein the insulation part is made of a polymer material. The waterproof terminal of claim 1, further comprising a filler filled in a contact portion between the bushing and the insulation.

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