KR20100062152A - Multi-function epoxy bushing improved electrical performance - Google Patents

Abstract

PURPOSE: A multi-functional epoxy bushing with improved electrical performance is provided to simultaneously detect a voltage and verify the active state and the frosty state of lines by forming two electrodes into a double structure. CONSTITUTION: A first detection electrode(130) performs a first function by detecting a voltage which flows through a conductive rod(120). A second detection electrode(140) performs a second function by detecting the voltage. The first detection electrode and the second detection electrode are arranged into a double structure. The conductive rod and the detection electrodes are inserted into an epoxy insulator(110). The epoxy insulator is integrated with a flange(112).

Description

Multi-function Epoxy Bushing Improved Electrical Performance

The present invention relates to a multi-function epoxy bushing with improved electrical performance. In particular, the two electrodes are arranged in a double structure to provide various functions such as voltage detection, presence of live lines, determination of phases and conditions of lines. The present invention relates to a multifunctional epoxy bushing with improved electrical performance.

In general, the epoxy bushing is formed of a resin of an insulating material and a semiconducting material for the purpose of electrical insulation and equal distribution of voltage and shielding, and is installed at a portion where voltage is introduced into a heavy electric machine 50 such as a transformer or a switch. At this time, the high pressure bushing is installed on the high pressure side (primary side) and the low pressure bushing is installed on the low pressure side (secondary side) according to the insulation class.

Conventional epoxy bushings can be easily identified by checking whether the live wire, and equipped with a detection function that can confirm the phase, by enabling the distribution current by enabling the charged current as a signal power source. In addition, the epoxy bushing is more stable voltage value than the current transformer can solve the malfunction of the heavy electric machine, it is equipped with a voltage detection function for detecting failure or abnormal power supply, it is easy to carry out post-management such as maintenance and repair have.

1 and 2 show a cross-sectional view and an exploded perspective view of the epoxy bushing for voltage detection according to the prior art. In the conventional voltage detecting epoxy bushing, as illustrated in FIGS. 1 and 2, the conductive rod 20 and the detection electrode 30 are formed by insert molding to the epoxy insulating material 10.

The epoxy insulating material 10 is integrally formed with a flange 12 that can be assembled to a heavy electric machine 50 such as a transformer, a switch and the like.

The conductor rod 20 forms one or two or more o-ring grooves 22 on one side, which is an insertion portion of the heavy electric machine 50, to bond the O-rings 25, and to the epoxy insulating material 10 by insert molding. It is configured by. The conductor rod 20 forms an O-ring groove 21 at the other side of the heavy electric machine 50 and couples the O-ring 24 to the epoxy insulating material 20 by insert molding. ), The sealing between the forming through hole 11 and the outer circumferential surface of the conductor rod 20 was further maximized. In addition, the conductor rod 20 is cured for a predetermined time by applying a sealant (not shown) to the outer surface in order to block the leakage of gas or oil through the molding through hole 11 of the epoxy insulating material 10 After the mold is bonded to the epoxy insulating material 10 in the mold (not shown).

The detection electrode 30 includes a ring-shaped metal ring 32 and a plurality of metal connection terminals 31 fastened to the metal ring 32. The connection terminal 31 is configured to be connected to the outside to detect whether the line is live or voltage.

At this time, the detection electrode 30 is connected to a lighting lamp (not shown) to check whether the line is live, or connected to the control box, detector or the like to detect the voltage.

However, such a conventional voltage detecting epoxy bushing has a disadvantage in that it is not possible to simultaneously perform the line detection and voltage detection functions because the detection electrode 30 is composed of one. That is, only one function is selected and configured, whether only the line is live or only the voltage detection function is performed.

In addition, although the detection electrode 30 used in the conventional voltage detecting epoxy bushing is press-molded in the epoxy insulating material 10 as described above, the epoxy insulating material 10, the conductive rod 20, and the Since the detection electrode 30 and the O-rings 24 and 25 are each made of different materials, different pressure-molded parts of the epoxy insulating material 10 and the epoxy insulating material 10 may be formed by different linear expansion coefficients. A gap Cap is formed between the materials to generate a discharge at a portion where the gap Cap is formed when a high voltage is applied. In addition, when the epoxy bushing having such a structure is used for a long time, there is a problem in that partial discharge is intensified and insulation breakdown occurs.

Accordingly, the present invention has been made to solve the above problems, and a first object of the present invention is to arrange two electrodes in a double structure to perform various functions such as voltage detection, live state of a line, phase formation and line state. To provide a multi-functional epoxy bushing that can be performed at the same time.

A second object of the present invention is to provide a multifunctional epoxy bushing which can extend the life of the product by forming a semiconductive film on the conductor rod and the detection electrode of the epoxy bushing to minimize the dielectric breakdown caused by partial discharge.

It is a third object of the present invention to provide a multifunctional epoxy bushing which can improve electrical performance by forming a leakage preventing film (silicon film) on a conductor rod and a detection electrode of an epoxy bushing to correct thermal shrinkage caused by a difference in the coefficient of linear expansion. There is.

The fourth object of the present invention is to form a semi-conductive film on the conductive rod and the detection electrode of the epoxy bushing, and then to form a leakage preventing film (silicon film) thereon, thereby minimizing the dielectric breakdown caused by partial discharge and at the same time the difference in the coefficient of linear expansion. It is to provide a multifunctional epoxy bushing that can compensate for the heat shrinkage generated.

Multifunctional epoxy bushing according to the present invention for achieving the above object, the conductor rod 120; The conductor rod 120 is disposed in a dual structure with a first detection electrode 130 that senses a voltage flowing through the conductor rod 120 and performs a first function, and the first detection electrode 130. The second detection electrode 140 and the conductor rod 120 and the first and second detection electrodes 130 and 140 which perform a second function by sensing a voltage flowing through the insert are inserted therein, and a transformer It is characterized in that it comprises a; epoxy insulating material 110 formed integrally with the flange 112 that can be assembled to the heavy electric machine 150 of the switchgear.

The first detection electrode 130 has a plurality of connection terminals formed at predetermined intervals on the metal ring 132 having a plurality of cutting grooves 133 formed at regular intervals, and the metal ring 132 between the cutting grooves 133. 131 is provided.

The second detection electrode 140 is formed of a metal ring 142 and the metal ring 142 at regular intervals and a plurality of connection terminals inserted into the cutout groove 133 of the first detection electrode 130 ( 141).

The first function includes a live state of a line, an open phase, a power supply function of a control circuit, and the second function includes a voltage detection function.

The first function includes a voltage detection function, and the second function includes a live state of a line, an open phase, and a power supply function of a control circuit.

The multifunctional epoxy bushing is characterized in that a semiconductive film is formed by applying a semiconductive paint to the conductor rod 120.

The multifunctional epoxy bushing is characterized in that a silicon film is formed on the semiconductive film of the conductor rod 120.

The multifunctional epoxy bushing is characterized in that a silicon film is formed on the conductor rod (120).

The multifunctional epoxy bushing is characterized in that the semi-conductive paint is applied to the first and second detection electrodes (130, 140).

The conductor rod 120 is characterized in that one or more O-ring grooves 122 are formed on one side, which is an insertion portion of the heavy electric machine 150, and the O-ring 125 is coupled to the O-ring grooves 122.

The conductor rod 120 is characterized in that one or more O-ring grooves 121 are formed on the other side of the outer portion of the heavy electric machine 150 and the O-rings 124 are coupled to the O-ring grooves 121.

According to the multifunctional epoxy bushing with improved electrical performance according to the present invention, two electrodes can be arranged in a double structure to simultaneously perform various functions such as voltage detection, live state of a line, phase formation and line state, etc. It has the advantage of convenient safety management during smooth supply, maintenance and inspection.

In addition, by forming a semi-conductive film on the conductor rod and the detection electrode of the epoxy bushing to be an equipotential during discharge, there is an advantage that can minimize the breakdown by the partial discharge to extend the life of the product.

In addition, by forming a liquid silicon film on the conductor rod and the detection electrode of the epoxy bushing to correct the thermal shrinkage caused by the difference in the linear expansion coefficient, it is possible to improve the electrical performance.

In addition, by forming a semiconductive film on the conductor rod and the detection electrode of the epoxy bushing, and then forming a liquid silicon film thereon, it is possible to minimize thermal breakdown caused by the difference in the coefficient of linear expansion while minimizing the dielectric breakdown caused by partial discharge. .

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

3 and 4 are a cross-sectional view and an exploded perspective view of the multi-functional epoxy bushing improved electrical performance according to a preferred embodiment of the present invention. 5 and 6 are exploded and combined perspective views of the first and second detection electrodes used in the present invention.

As shown in FIGS. 3 and 4, the multifunctional epoxy bushing having improved electrical performance according to the present invention has the conductor rod 120 and the first and second detection electrodes 130 and 140 inserted into the epoxy insulating material 110. It is constructed in combination.

The epoxy insulating material 110 is integrally formed with a flange 112 that can be assembled to a heavy electric machine 150, such as a transformer, a switch. At this time, the flange 112 is fastened by the fastening member of the bracket, bolt and nut when assembled with the heavy electric machine 150 to form a ground plane.

The conductor rod 120 is formed by forming one or more O-ring grooves 122 on one side which is an insertion portion of the heavy electric machine 150 to combine the O-ring 125 and the insert molding to the epoxy insulating material 110 by insert molding It is desirable to be. In addition, the conductor rod 120 forms an O-ring groove 121 on the other side, which is an outer portion of the heavy electric machine 150, and combines the O-ring 124 therein and insert inserts into the epoxy insulation 120. To combine. At this time, the O-rings 124 and 125 serve to further maximize the sealing between the molded through hole 111 of the epoxy insulating material 110 and the outer circumferential surface of the conductor rod 120.

In addition, the conductive rod 120 is coated with a semi conductive paste on the surface in order to prevent the gas or oil from leaking through the molded through hole 111 of the epoxy insulating material 110, and then It cures by time and forms a semiconductive film (not shown). Next, the conductive rod 120 having the semiconductive film formed thereon is bonded to the epoxy insulating material 110 by insert molding using a mold (not shown). In this case, the semiconducting film formed on the surface of the conductive rod 120 serves to prevent the corona by making the equipotential between the conductive rod 120 and the epoxy insulating material 110.

In addition, as another embodiment of the present invention, the silicon film 123 is formed by thinly applying liquid silicon to the surface of the conductive rod 120 on which the semiconductive film is formed. In this case, the silicon film 123 not only functions as a leakage preventing film, but also functions as a cushioning function to correct a thermal contraction rate caused by a difference in the coefficient of linear expansion with the epoxy insulating material 110.

In addition, as another embodiment of the present invention, the silicon film 123 may be formed by applying a thin layer of liquid silicon on the surface of the conductive rod 120. In this case, as described above, the silicon film 123 not only functions as a leakage preventing film but also functions as a cushioning function for correcting a thermal shrinkage rate caused by a difference in the coefficient of linear expansion with the epoxy insulating material 110.

As described above, the present invention forms the silicon film 123 on the conductor rod 120, so that the sanding operation as in the prior art does not have to be performed for the adhesion of the epoxy insulating material 110 and the conductor rod 120. In addition to simplifying the work process, it is possible to minimize the partial discharge due to the equipotential distribution, thereby increasing the life of the product. In addition, it is possible to lower the defective rate of the product in the manufacturing process has the advantage of reducing the manufacturing cost.

The first detection electrode 130 detects the voltage flowing through the conductor rod 120 to perform a first function. As illustrated in FIGS. 4 to 6, the plurality of cutout grooves 133 are spaced at predetermined intervals. The metal ring 132 and the metal ring 132 formed between the cutting grooves 133 are provided with a plurality of connection terminals 131 formed at regular intervals. Here, the function and the role of the first function is determined according to the external devices connected to the plurality of connection terminals 131. That is, when a lighting lamp (not shown) is connected to the connection terminal 131 of the first detection electrode 130, it determines whether the line is in a live state, whether there is an open phase, and controls the connection terminal 131. When connected to equipment, it detects the voltage.

The second detection electrode 140 senses a voltage flowing through the conductor rod 120 to perform a second function. As shown in FIGS. 4 to 6, the metal ring 142 and the metal ring A plurality of connection terminals 141 are formed at 142 at regular intervals and are inserted into the cutout groove 133 of the first detection electrode 130. Here, the second function, as with the first function, its function and role are determined according to the external devices connected to the plurality of connection terminals 141. That is, when a lighting lamp (not shown) is connected to the connection terminal 141 of the second detection electrode 140, whether the line is in a live state, whether or not an image is formed, and controlling the connection terminal 141, inspection When connected to equipment, it detects the voltage.

Here, as shown in FIG. 6, the first detection electrode 130 and the second detection electrode 140 have the second detection electrode 140 in the cutting groove 133 of the first detection electrode 130. The metal ring 142 of the second detection electrode 140 is inserted into the metal ring 132 of the first detection electrode 130 so that the connection terminal 141 is positioned in a double structure. In this case, the first and second detection electrodes 130 and 140 disposed in the dual structure are coupled to the epoxy insulating material 110 by insert molding.

On the other hand, it is preferable that the first and second detection electrodes 130 and 140 are coated with a semiconductive paint on their respective surfaces and then cured for a predetermined time to form a semiconductive film. In this case, the semiconducting film serves to prevent the corona by making the equipotential between the first and second detection electrodes 130 and 140 and the epoxy insulating material 110.

Meanwhile, the first function of the first detection electrode 130 and the second function of the second detection electrode 140 may be configured to have different functions.

As described above, in the multifunctional epoxy bushing according to the present invention, the semiconducting paint is applied to the inner conductor rod 120 and the first and second detection electrodes 130 and 140 during automatic press molding, thereby realizing at an equipotential. Insulation breakdown caused by discharge can be minimized to maximize product life.

In addition, by applying a thin layer of liquid silicone to the conductive rod 120 to form a leakage prevention film, it is possible to make an epoxy bushing with improved electrical performance by correcting the thermal shrinkage caused by the difference in the coefficient of linear expansion with the epoxy insulating material (110).

In addition, the heat shrinkage rate caused by the difference in the coefficient of linear expansion with the epoxy insulating material 110 can be corrected to minimize the failure rate and to maximize the life can be mass-produced.

In addition, by arranging the first and second detection electrodes 130 and 140 in a dual structure to have different functions, the voltage detection, the presence and absence of the live state of the line, the detection of the state of the line, the power of the control circuit This has the advantage of being able to perform several functions at the same time.

Although the present invention has been described in detail only with respect to the described embodiments, it will be apparent to those skilled in the art that various changes and modifications can be made within the technical scope of the present invention, and such modifications and modifications belong to the appended claims.

1 and 2 are a cross-sectional view and an exploded perspective view of the epoxy bushing for voltage detection according to the prior art

3 and 4 are cross-sectional and exploded perspective view of the multi-functional epoxy bushing improved electrical performance according to a preferred embodiment of the present invention

5 and 6 are an exploded perspective view and a combined perspective view of the first and second detection electrodes used in the present invention

[Description of Code for Major Parts of Drawing]

100: epoxy bushing 110: epoxy insulating material

111: forming through hole 112: flange

120: conductor rod 121, 122: O-ring groove

123: liquid silicon film 124, 125: O-ring

130: first detection electrode 131: connection terminal

132: metal ring 133: incision groove

140: second detection electrode 141: connection terminal

142: metal ring

Claims (11)

A conductor rod 120; A first detection electrode 130 for sensing a voltage flowing through the conductor rod 120 to perform a first function; A second detection electrode 140 disposed in a dual structure with the first detection electrode 130 and sensing a voltage flowing through the conductor rod 120 to perform a second function; And Epoxy in which the conductor rod 120 and the first and second detection electrodes 130 and 140 are insert-molded therein and integrally formed with a flange 112 that can be assembled to the heavy electric machine 150 of a transformer or a switch. Insulation material 110; multifunctional epoxy bushing comprising a. The method of claim 1, wherein the first detection electrode 130 is: The metal ring 132 formed with a plurality of cutting grooves 133 at regular intervals, and the plurality of connection terminals 131 formed at a predetermined interval on the metal ring 132 between the cutting groove 133 is characterized in that it is provided with Multifunctional epoxy bushing. The method of claim 2, The second detection electrode 140 is A metal ring 142 and a plurality of connecting terminals 141 are formed at a predetermined interval on the metal ring 142 and are inserted into the cutting groove 133 of the first detection electrode 130. Multifunctional epoxy bushing. The method of claim 1, The first function includes a live state of a track, an open phase, a power supply function of a control circuit, Wherein said second function comprises a voltage detection function. The method of claim 1, The first function includes a voltage detection function, The second function is a multi-functional epoxy bushing, characterized in that it includes a live state of the line, the presence of phase, the power supply function of the control circuit. The method of claim 1, wherein the multifunctional epoxy bushing is: Multifunctional epoxy bushing, characterized in that the semi-conductive film was formed by applying a semi-conductive paint to the conductor rod (120). The method of claim 6, The multifunctional epoxy bushing Multifunctional epoxy bushing characterized in that a silicon film is formed on the semiconductive film of the conductor rod (120). The method of claim 1, The multifunctional epoxy bushing Multifunctional epoxy bushing characterized in that a silicon film is formed on the conductor rod (120). The method of claim 1, The multifunctional epoxy bushing A multifunctional epoxy bushing characterized by coating a semiconductive paint on the first and second detection electrodes (130 and 140). The method of claim 1, The conductor rod 120 is Multifunctional epoxy bushing, characterized in that one or more O-ring grooves 122 are formed on one side which is an insertion portion of the heavy electric machine 150 and O-rings 125 are coupled to the O-ring grooves 122. The method of claim 1, The conductor rod 120 is Multifunctional epoxy bushing, characterized in that one or more O-ring grooves 121 are formed on the other side of the outer portion of the heavy electric machine 150 and O-rings 124 are coupled to the O-ring grooves 121.

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