KR101285140B1 - Apparatus and method for inspecting high voltage lead-through - Google Patents

Abstract

PURPOSE: A device and a method for inspecting high voltage bushing are provided to determine the failure of the bushing in the same condition as a busing-mounted state by installing an upper housing and a lower housing on the high voltage bushing. CONSTITUTION: An inspection device includes an upper housing (100), a lower housing (150), a fixing member (110), a gas supply pipe (130), a pressure measuring hole (34), and a pressure sensing member. The upper housing is combined with an upper flange (16) and inserts the upper part of busing inside. The lower housing is combined with a lower flange (20) and inserts the lower part of the busing inside. An upper combination end (102) forms an upper through hole (104). A lower combination end forms a lower thorough hole (154). The fixing member fixes the upper and the lower housing to the upper and lower flange. The gas supply pipe leads gas to the inside of the upper and the lower housing. The pressure measuring hole communicates to measure the inner pressure of the bushing. The pressure sensing member is installed in the pressure measuring hole and measures the inner pressure of the bushing.

Description

[0001] Apparatus and method for inspecting high-voltage bushings [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an inspection apparatus and an inspection method for a high-voltage bushing, and more particularly, to an inspection apparatus and an inspection method of a high-voltage bushing for detecting a breakdown and a defect of a high-

Generally, power supplied from power plants and power plants at high pressure is converted and supplied to a low voltage that can be used by consumers such as homes and industrial sites through a transformer. In this case, a transformer is a generic term for a device for changing an AC voltage and an electric current value by an electromagnetic induction action. In particular, as described above, a transformer converts a high-voltage power supplied from a power plant and a power station into a low- .

Although the structure of a general transformer may vary depending on the capacity and the voltage, it generally includes a winding and an iron core for performing the function of the transformer, and these windings and the iron core are mounted in a tank filled with insulating oil This insulating oil (insulating oil) is an insulating material of the winding, preventing moisture and dust from penetrating into it and lowering the dielectric strength, and at the same time, it dissipates the heat generated by the iron core and the coil by convection and radiation of oil.

In addition, a general transformer is provided with a high-voltage bushing as a connecting member for applying a high-voltage power supplied from the outside through a winding.

Such a high-pressure bushing is disclosed in Korean Registered Utility Model No. 20-0462698. When a high-pressure bushing installed in a transformer is defective, a separate inspection apparatus has not been developed, so that the bushing is replaced with a new one without judging the integrity of the bushing.

As a result, even if the bushing is determined to be defective according to the abnormality of the peripheral device, the normal bushing is replaced and consumed, so that the long working time is consumed due to the erroneous operation and the economic loss due to the replacement of the expensive bushing occurs.

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide a high voltage bushing capable of determining whether a bushing installed in a transformer is defective or not, And a method for inspecting the same.

According to an aspect of the present invention, there is provided an inspection apparatus for inspecting a bushing for delivering high-voltage electricity to a transformer, the inspection apparatus comprising: A lower housing having a lower flange and a lower flange, the upper housing being coupled to an upper flange of a bushing having a plurality of upper coupling holes formed therein and having an interior hollow therein and an upper portion of the bushing inserted therein; A lower housing coupled to the upper housing and having a hollow inside and having a lower portion of the bushing inserted therein; an upper coupling end protruding outwardly from one end of the upper housing and having a plurality of upper through holes formed vertically through the lower housing; A lower coupling step formed outwardly at one end of the lower coupling hole and having a plurality of lower through holes vertically penetrating therethrough, A fixing member inserted into the upper and lower through holes and the upper and lower coupling holes to fix the upper and lower flanges to the upper and lower flanges, A gas supply pipe connected to the inside of the upper and lower housings to guide gas into the upper and lower housings, a pressure measuring hole connected to the inside of the bushing and communicating with the bushing to measure the internal pressure of the bushing, And a pressure sensing member installed in the pressure measurement hole and measuring the internal pressure of the bushing.

The upper and lower housings further include a pressure gauge connected to the inside of the upper and lower housings and measuring a gas supplied into the upper and lower housings.

And a sealing member formed of an elastic material between the upper and lower flanges and the upper and lower flanges to seal the joining portions of the upper and lower flanges and the upper and lower coupling ends to prevent leakage of gas do.

The pressure sensing member is made of a pressure sensor and measures the internal pressure of the bushing to detect damage of the bushing when a pressure of "0" is sensed.

An inspecting method for inspecting a bushing for transferring electricity of a high voltage to a transformer, the inspecting method comprising inserting upper and lower sealing members on upper and lower surfaces of upper and lower flanges, respectively, A sealing member inserting step of positioning the coupling holes of the flange coaxially and sealing the joint portions of the upper and lower flanges and the upper and lower coupling ends; A housing coupling step in which the through holes of the upper and lower coupling ends are coaxially positioned with the coupling holes and the upper and lower housings are coupled to the bushing by fastening the fixing members, A pressure gauge is provided in a pressure measuring tube formed on an outer circumferential surface of the upper and lower housings to pressurize the inside of the upper and lower housings, And measuring an inner pressure of the bushing by detecting a pressure of the bushing by measuring the inner pressure of the bushing by providing a pressure sensing member in the pressure measurement hole of the bushing.

The apparatus and method for testing a high voltage bushing according to the present invention have the following effects.

The present invention can determine whether or not the bushing is defective by inserting the upper and lower housings in a high-voltage bushing, injecting gas into the inside of the high-voltage bushing, and inspecting the bushing under the same condition as the case where the bushing is mounted on the gas insulated busbar.

Therefore, it is possible to determine the normal state and the defective state of the accurate bushing, thereby preventing the unnecessary bushing from being consumed and the economic loss due to the use of the expensive bushing can be prevented.

In addition, since the defect of the product can be checked by inspecting the bushing which is new, it is possible to shorten the work time consumed in mounting the defective bushing in the transformer, and to confirm the correctness of the bushing.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a cross sectional view showing a high voltage bushing to be inspected by the present invention.
2 is a cross-sectional view showing a configuration of a preferred embodiment of a high-voltage bushing inspection apparatus according to the present invention.
3 is a partial cross-sectional view showing a configuration of a preferred embodiment of a high-voltage bushing inspection apparatus according to the present invention.
4 is a block diagram showing a configuration of a preferred embodiment of the high-voltage bushing inspection method according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of a high-voltage bushing inspection apparatus and an inspection method according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a cross-sectional view showing a state in which a high-voltage bushing inspecting apparatus according to the present invention is installed in a transformer, FIG. 2 is a sectional view showing a configuration of a preferred embodiment of a high-voltage bushing inspecting apparatus according to the present invention, A partial cross-sectional view showing a configuration of a preferred embodiment of a high-voltage bushing inspection apparatus according to the present invention is shown.

As shown in FIGS. 1 to 3, the high-voltage electricity generated by the power plant is transmitted to the transformer 1 through a gas insulated bushing (GIB). Between the transformer (1) and the gas insulated bus bar (2), a high voltage bushing (10) is provided as a transmitting member for transmitting high voltage electricity to the transformer (1).

The bushing 10 is formed as an upper casing 12 and a lower casing 14, respectively, and the inside of the upper and lower casings 12 and 14 is hollow. Inside the upper and lower casings 12 and 14, a high voltage conductor 26 to be described later is installed vertically. The upper and lower casings 12 and 14 block leakage of a high voltage applied to the bushing 10 to the outside.

An upper flange 16 is formed at a lower portion of the upper casing 12. The upper flange 16 is formed to protrude radially with respect to the central axis of the upper casing 12. And the gas insulated busbars 2 or the upper housing 100 are tightly fixed to the upper surface of the upper flange 16.

An upper fitting hole 18 is formed on the upper and lower surfaces of the upper flange 16. The upper coupling hole 18 is formed in a circular shape so that a plurality of upper and lower coupling holes 18 are vertically penetratingly formed radially with respect to the central axis of the upper casing 12. A coupling bolt (not shown) is coupled to an upper portion of the upper coupling hole 18 so as to be coaxial with a coupling hole of a gas insulated bus bar 2 to be described below, And is firmly fixed to the flange 16.

On the upper side of the upper casing (12), a gas insulated bus bar (2) is provided. The gas-insulated busbars 2 are installed outside the upper casing 12, and the insulating gas 5 is filled in the gas-insulated busbars 2. SF6 gas is used as the insulating gas 5, and any insulating gas can be used. Insulating gas 5 is filled in the gas insulated bus bar 2 so as to have a pressure of 5 kgf / cm 2 to insulate conductors inside the gas insulated bus bar 2.

A lower flange 20 is formed on the upper portion of the lower casing 14. The lower flange 20 is formed to protrude radially with respect to the central axis of the lower casing 14. A bushing chamber (6) of the transformer (1) is coupled to the lower surface of the lower flange (20).

A lower fitting hole 22 is formed on the upper and lower surfaces of the lower flange 20. The lower fitting hole 22 is formed in a circular shape so that a plurality of upper and lower lower fitting holes 22 are vertically penetratingly formed radially with respect to the central axis of the lower casing 14. [ A fixing hole (not shown) of the bushing chamber 6 is coaxially positioned at a lower portion of the lower coupling hole 22 and a coupling bolt (not shown) is coupled to the bushing chamber 6, (20) is firmly fixed.

The lower casing (14) of the bushing (10) is installed inside the transformer (1). The transformer (1) is hollowed and filled with a transformer insulating oil (7). The transformer insulating oil 7 is mainly used for insulating and cooling the bushing 10, and the insulating oil 7 is mainly used for the insulation and cooling of the bushing 10. The insulating oil 7 is a mineral oil, alkene benzene, polybutene, alkylnaphthalene, alkyldiphenylethane, silicone oil, . The transformer 1 is a device that converts and supplies high-voltage power supplied through the bushing 10 to a low voltage that can be used in a home or industrial field.

A contact pin 24 is formed on the upper casing 12. The contact pin 24 is connected to the conductor of the gas insulated bus bar 2 so that high voltage electricity is applied to the bushing 10. A high voltage conductor (26) is installed inside the bushing (10). The high-voltage conductor 26 has a cylindrical shape and is formed long in the vertical direction. The high-voltage conductor 26 serves to transmit a high voltage, which is transmitted through the contact pin 24, to the transformer 1 through the upper and lower casings 12 and 14.

The hollow interior of the upper and lower casings (12, 14) is filled with insulating oil (28). The insulating oil 28 is mainly used for insulating and cooling the high voltage conductor 26, such as mineral oil, alkene benzene, polybutene, alkyl naphthalene, alkyl diphenyl ethane, silicone oil and the like. The insulating oil 28 is stored in the upper and lower casings 12 and 14 communicating with each other and a pressure measurement space 30 in which a portion of the upper end of the upper casing 12 is not filled with the insulating oil 28, .

The pressure measuring space 30 is formed in the upper casing 12 and the pressure measuring space 30 is an empty space in which the insulating oil 28 is not filled.

A pressure sensing pipe (32) is installed on the inner circumferential surface of the upper casing (12). The pressure sensing tube 32 is formed in a hollow tube shape and is formed long in the vertical direction. The pressure sensing pipe 32 is installed vertically along the inner circumferential surface of the upper casing 12 and has a pressure measurement hole 34 whose one end is installed in the pressure measurement space 30 and whose other end is communicated with the outside, . The pressure sensing pipe 32 serves to communicate between the outside and the pressure measuring space to measure the pressure of the pressure measuring space 30.

That is, when the bushing 10 is broken and the external insulating gas 5 permeates the inside of the bushing 10, the pressure of the pressure measuring space 30 rises and the pressure sensing pipe 32 The pressure in the bushing 10 is sensed through the bushing 10 to check whether the bushing 10 is damaged.

The inspection apparatus for inspecting a bushing (10) for transferring high-voltage electricity to a transformer, the inspection apparatus comprising: a bushing (10) having a plurality of upper coupling holes (18) An upper housing 100 coupled to the upper flange 16 of the bushing 10, the upper portion of the bushing 10 being inserted therein; The lower housing 150 is coupled to a lower flange 20 of a bushing 10 having a plurality of lower coupling holes 22 formed to be vertically penetrated, )and; An upper coupling end 102 protruding outward at one end of the upper housing 100 and having a plurality of upper through holes 104 formed to pass through the upper and lower ends; A lower coupling end 152 protruding outward at one end of the lower housing 150 and having a plurality of lower through holes 154 formed to pass through the upper and lower ends; The upper and lower through holes 104 and 154 and the upper and lower coupling holes 18 and 22 are positioned coaxially with each other and the upper and lower through holes 104 and 154 and the upper and lower coupling holes 18 and 22 A fixing member 110 inserted into the upper and lower flanges 16 and 20 to fix the upper and lower housings 100 and 150; A gas supply pipe 130 connected to the inside of the upper and lower housings 100 and 150 to guide gas into the upper and lower housings 100 and 150 and a gas supply pipe 130 connected to the inside of the bushing 10, A pressure measurement hole 34 communicating with the pressure measurement hole 34 so that the internal pressure of the bushing 10 is measured and a pressure sensing member 170 installed in the pressure measurement hole 34 for measuring the internal pressure of the bushing 10 .

The upper housing (100) is installed on the outer side of the upper casing (12). The upper housing 100 has a cylindrical shape, and its interior is hollow so that the upper side is closed and the lower side is opened. The upper casing 12 is installed inside the upper housing 100 to block the upper casing 12 from the outside.

An upper coupling end 102 is formed at the lower end of the upper housing 100. The upper coupling end 102 protrudes horizontally outward with respect to the central axis of the upper housing 100. The upper coupling end 102 is a portion that is in close contact with the upper surface of the upper flange 16.

An upper through hole 104 is formed on the upper and lower surfaces of the upper coupling end 102. The upper through-holes 104 are formed in a plurality of upper and lower portions radially through the central axis of the upper housing 100. The upper through hole 104 is coaxially positioned with the upper coupling hole 18 and the fixing member 110 to be described below is fastened to the upper housing 100 so that the upper housing 100 is fixed to the upper flange 16 .

A fixing member 110 is installed in the upper through hole 104 and the upper coupling hole 18. The fixing member 110 includes a fixing bolt 112 and a fixing nut 114 to firmly fix the upper and lower housings 100 and 150 and the bushing 10.

An upper sealing member 120 is provided between the upper coupling end 102 and the upper flange 16. The upper sealing member 120 may be formed of elastic rubber, urethane, silicone, or the like, and is formed into a circular ring shape. And is installed between the upper coupling end 102 and the upper flange 16 to block external air from entering the interior of the upper housing 100.

An upper insertion hole 122 is formed on the upper and lower surfaces of the upper sealing member 120 so as to be vertically penetrated. A plurality of upper insertion holes 122 are formed radially in relation to the central axis of the upper sealing member 120. A fixing bolt 112 is inserted into the upper insertion hole 122.

A gas supply pipe 130 is formed on a side surface of the upper housing 100. The gas supply pipe 130 has a cylindrical shape and protrudes rightward. The gas supply pipe 130 is hollow and communicates with the inside of the upper housing 100, and the supply hose 132 is coupled to the gas supply pipe 130. The gas supply pipe 130 serves to guide the supply of nitrogen (N 2) or dry air supplied by the supply hose 132 into the upper housing 100.

A pressure measuring pipe 140 is formed on the lower side of the gas supply pipe 130. The pressure measuring pipe 140 has a cylindrical shape and is formed to protrude rightward. The pressure measuring pipe 140 is hollow and communicates with the inside of the upper housing 100, and a pressure gauge 142 is installed in the pressure measuring pipe 140. The pressure measuring tube 140 is provided with the pressure gauge 142 to measure the inner pressure of the upper housing 100.

That is, at the time of inspecting the bushing 10, gas is injected through the gas supply pipe 130 to form the same external environment as the insulating gas 5 of the gas insulated busbar 2, And the gas is injected into the upper housing 100 to generate an internal pressure of 5 kgf / cm2 or more.

The lower housing (150) is installed on the outer side of the lower casing (14). The lower housing 150 has a cylindrical shape and is hollow so that the lower side is closed and the upper side is opened. The lower housing (150) is provided with the lower casing (14) to block the lower casing (14) from the outside.

A lower coupling end 152 is formed at an upper end of the lower housing 150. The lower coupling end 152 is horizontally protruded outward with respect to the center axis of the lower housing 150. The lower coupling end 152 is a portion which is in close contact with the upper surface of the lower flange 20.

A lower through hole 154 is formed on the upper and lower surfaces of the lower coupling end 152. The lower through-holes 154 are radially formed in the upper and lower portions of the lower housing 150. The lower through hole 154 is coaxial with the lower coupling hole 22 and the fixing bolt 112 is fastened to the lower housing hole 150 so that the lower housing 150 is firmly fixed to the lower flange 20.

A lower sealing member 160 is installed between the lower coupling end 152 and the lower flange 20. The lower sealing member 160 may be formed of elastic rubber, urethane, silicone, or the like, and is formed in a circular ring shape. And is installed between the lower coupling end 152 and the lower flange 20 to block external air from flowing into the lower housing 150.

On the upper and lower surfaces of the lower sealing member 160, a lower insertion hole 162 formed to be vertically penetrated is formed. A plurality of lower insertion holes 162 are formed radially in relation to the center axis of the lower sealing member 160. A fixing bolt 112 is inserted into the lower insertion hole 162.

A gas supply pipe 130 is formed on a side surface of the lower housing 150. The gas supply pipe 130 has a cylindrical shape and protrudes rightward. The gas supply pipe 130 is hollow and communicates with the inside of the upper housing 100, and the supply hose 132 is coupled to the gas supply pipe 130. The gas supply pipe 130 serves to guide the supply of nitrogen (N 2) or dry air supplied by the supply hose 132 into the lower housing 150.

A pressure measuring pipe 140 is formed on the gas supply pipe 130. The pressure measuring pipe 140 has a cylindrical shape and is formed to protrude rightward. The pressure measuring pipe 140 is hollow and communicates with the inside of the lower housing 150, and a pressure gauge 142 is installed in the pressure measuring pipe 140. The pressure measuring tube 140 is provided with the pressure gauge 142 to measure the internal pressure of the lower housing 150.

That is, at the time of inspecting the bushing 10, gas is injected through the gas supply pipe 130 to form the same external environment as the insulating gas 5 of the gas insulated busbar 2, And the gas is injected into the upper housing 100 to generate an internal pressure of 5 kgf / cm2 or more.

A pressure sensing member (170) is installed in the pressure measurement hole (34) of the bushing (10). The pressure sensing member 170 is a general pressure sensor, and a detailed description thereof will be omitted. The pressure sensing member 170 is coupled to the pressure measurement hole 34 to measure a pressure in the pressure measurement space 30 of the bushing 10. [

The pressure sensing member 170 is connected to the pressure gauge 172. The pressure gauge 172 diffuses the pressure of the pressure measurement space 30 inside the bushing 10 measured by the pressure sensing member 170 with a numerical value so that the operator can visually confirm the measured value.

That is, when the bushing 10 is in a normal state, the pressure of the pressure measurement space 30 is detected as "0 ", and when the bushing 10 is damaged and is in an abnormal state, The gas injected into the bushing 10 penetrates into the bushing 10 through the damaged portion and the pressure of the pressure measuring space 30 rises.

Accordingly, the pressure sensing member 170 measures the pressure gauge 172, and the pressure gauge 172 senses a pressure of '0' or higher to confirm whether the bushing 10 is in a normal state or an abnormal state.

Hereinafter, the operation of the high-voltage bushing inspection apparatus and method according to the present invention will be described with reference to FIGS. 1 to 4. FIG.

The upper and lower sealing members 160 are inserted into the upper and lower surfaces of the upper and lower flanges 16 and 20 to inspect the bushing for transmitting the high voltage electricity to the transformer according to the present invention, A sealing member inserting step S130 of coaxially positioning the insertion holes 122 and 162 of the lower sealing member 160 and the fitting holes 18 and 22 of the upper and lower flanges 16 and 20, And the through holes 104 and 154 of the upper and lower coupling ends 102 and 152 are coaxially positioned in the coupling holes 18 and 22 and the fixing bolts 112 are fastened A housing coupling step S140 of coupling the upper and lower housings 100 and 150 to the bushing 10 and the supply hose 132 to the gas supply pipe 130 formed on the outer circumferential surface of the upper and lower housings 100 and 150 A pressure gauge 142 is installed in the pressure measuring pipe 140 formed on the outer circumferential surface of the upper and lower housings 100 and 150, A pressure measuring step S160 for measuring the pressure inside the upper and lower housings 100 and 150 and a pressure sensing member 170 installed in the pressure measuring hole 34 of the bushing 10, An internal pressure measuring step S170 for measuring the pressure of the fluid.

First, when an abnormality occurs in the bushing 10 mounted on the transformer 1, an insulating oil removing step S100 for discharging the insulating oil 28 stored in the transformer 1 is performed. In the insulating oil removing step S100, a pump is connected to a discharge pipe provided at the lower part of the transformer 1, and the insulating oil is transferred to the oil tank.

When the insulating oil removing step (S100) is completed, an insulating gas removing step (S110) for removing the insulating gas (5) filled in the gas insulated busbars (2) is performed. The insulating gas removing step S110 cuts off the coupling member 8 which communicates the horizontal housing 3 of the gas insulated busbars 2 and the vertical housing 4. [ A gas collector is connected to the vertical housing 4 to remove the insulating gas 5 in the vertical housing 4 in order to remove the insulating gas 5 filled in the vertical housing 4.

When the removal of the insulating gas 5 inside the vertical housing 4 is completed, a bushing separation step S120 for separating the bushing 10 is performed. The bushing separation step S120 removes the fastening bolts for fixing the bushing 10 and the vertical housing 4 and removes the fastening bolts for fixing the bushing 10 and the bushing chamber 6, The bushing (10) is removed from the transformer (1) and the gas insulated bus bar (2).

When the bushing 10 is separated from the transformer 1, a sealing member engaging step (S130) for engaging the sealing members 120 and 160 to the upper and lower flanges 16 and 20 of the bushing 10 is performed. The sealing member engaging step S130 may be performed by inserting the sealing members 120 and 160 so that the insertion holes 122 and 162 of the sealing members 120 and 160 and the coupling holes 18 and 22 of the upper and lower flanges 16 and 20 are coaxially positioned. Are coupled to the upper and lower surfaces of the upper and lower flanges, respectively.

When the sealing members 120 and 160 are coupled, a housing coupling step (S140) for coupling the upper and lower housings 100 and 150 to the outside of the bushing 10 is performed. In the housing coupling step S140, the upper and lower housings 100 and 150 are coupled to the upper and lower surfaces of the sealing members 120 and 160 coupled to the upper and lower surfaces of the upper and lower flanges 16 and 20, respectively. The fixing bolts 112 are fastened to the upper and lower flanges 16 and 20 and the upper and lower coupling ends 102 and 152 to firmly fix the upper and lower housings to the bushings 10.

That is, the sealing members 120 and 160 are coupled between the upper and lower flanges 16 and 20 and the upper and lower coupling ends 102 and 152 so that the upper and lower flanges 16 and 20 and the upper and lower housings 100 and 150 The air can be prevented from entering through the joint portion of the gasket.

When the housing coupling step S140 is completed, a gas injection step (S150) is carried out to form the same test conditions as those in the state where the bushing 10 is mounted on the gas insulated bus bar 2. The gas injection step S150 connects the supply hose 132 to the gas supply pipe 130 formed in the upper and lower housings 100 and 150 and supplies nitrogen gas N2 or dry air, The upper and lower housings 100 and 150 are filled with gas.

When the gas is filled in the upper and lower housings 100 and 150, a pressure measuring step (S160) is performed to measure the pressure inside the upper and lower housings 100 and 150. [ In the pressure measuring step S160, the gas filled in the upper and lower housings is charged at 5 kgf / cm2 or more to perform the test under the same condition as that of the insulated gas 5. A pressure gauge 142 is installed on the outer circumferential surface of the upper and lower housings 100 and 150 so that the operator visually confirms the pressure gauge 142 and charges the inside of the upper and lower housings 100 and 150 with a pressure of 5 kgf / do.

When the gas filling of the upper and lower housings 100 and 150 is completed, a pressure sensing member 170 is installed in the pressure measurement hole 34 of the bushing 10 to measure the internal pressure of the bushing 10 The measurement step S170 is performed.

The internal pressure measuring step S170 senses the pressure of the pressure measurement space 30 formed inside the bushing 10 using the pressure sensing member 170. [ When the internal pressure of the bushing 10 is sensed by the pressure sensing member 170, a pressure value is displayed on the pressure gauge 172 connected to the pressure sensing member 170. The operator measures and calculates the internal pressure value of the bushing 10 in units of one hour, and measures the bushing 10 for 24 hours.

When the internal pressure of the bushing 10 is measured, the ambient temperature of the bushing 10 is measured using a temperature sensor. Since the internal pressure of the bushing 10 may vary depending on the ambient temperature of the bushing 10, an inspection error of the bushing according to the ambient temperature of the bushing 10 is checked.

When the bushing 10 is damaged and gas stored in the upper and lower housings 100 and 150 flows into the bushing 10, the internal pressure of the bushing 10 rises.

Accordingly, when the pressure range of the pressure gauge 172 is measured to be + 0.1 kgf / cm 2 or more, the error range of the pressure value according to the ambient temperature is selected to be ± 0.1 kgf / .

 When the new bushing 10 is installed in the transformer 1, the sealing member inserting step S130, the housing coupling step S140, the gas injecting step S150, the pressure measuring step S160, It is possible to determine whether or not the bushing 10 is defective through step S170.

The scope of the present invention is not limited to the above-described embodiments, and many other modifications based on the present invention will be possible to those skilled in the art within the scope of the present invention.

10. Bushing 100. Upper housing
102. Upper coupling end 104. Upper through hole
120. Upper sealing member 130. Gas supply pipe
132. Supply hose 140. Pressure measuring tube
142. Pressure gauge 150. Lower housing
152. Lower coupling end 154. Lower through hole
160. Lower sealing member 170. Pressure sensitive member
172. Pressure gauge

Claims (5)

1. An inspection apparatus for inspecting a bushing for delivering high-voltage electricity to a transformer,
The upper housing 100 is coupled to the upper flange 16 of the bushing 10 in which a plurality of upper coupling holes 18 are formed so as to be vertically penetrated and into which the upper portion of the bushing 10 is inserted. )and;
The lower housing 150 is coupled to a lower flange 20 of a bushing 10 having a plurality of lower coupling holes 22 formed to be vertically penetrated, )and;
An upper coupling end 102 protruding outward at one end of the upper housing 100 and having a plurality of upper through holes 104 formed to pass through the upper and lower ends;
A lower coupling end 152 protruding outward at one end of the lower housing 150 and having a plurality of lower through holes 154 formed to pass through the upper and lower ends;
The upper and lower through holes 104 and 154 and the upper and lower coupling holes 18 and 22 are positioned coaxially with each other and the upper and lower through holes 104 and 154 and the upper and lower coupling holes 18 and 22 A fixing member 110 inserted into the upper and lower flanges 16 and 20 to fix the upper and lower housings 100 and 150;
A gas supply pipe 130 connected to the inside of the upper and lower housings 100 and 150 to guide gas into the upper and lower housings 100 and 150;
A pressure measuring hole (34) connected to the inside of the bushing (10) and communicating with the internal pressure of the bushing (10) to measure the pressure;
And a pressure sensing member (170) installed in the pressure measurement hole (34) for measuring an internal pressure of the bushing (10).
[2] The apparatus of claim 1, wherein the upper and lower housings (100, 150)
And a pressure gauge (142) connected to the inside of the upper and lower housings (100, 150) and measuring a gas supplied into the upper and lower housings (100, 150).
2. The apparatus of claim 1, wherein between the upper and lower flanges (16, 20) and the upper and lower coupling ends (102, 152)
And a sealing member (120, 160) made of an elastic material and sealing the joint between the upper and lower flanges (16, 20) and the upper and lower coupling ends (102, 152) .
The pressure sensing member (170) according to claim 1, wherein the pressure sensing member (170) is formed of a pressure sensor and measures the internal pressure of the bushing (10) to detect damage of the bushing Inspection device of high voltage bushing.
A method of inspecting a bushing for delivering high-voltage electricity to a transformer,
The upper and lower sealing members 160 are inserted into the upper and lower surfaces of the upper and lower flanges 16 and 20 so that the insertion holes 122 and 162 of the upper and lower sealing members 160 and the upper and lower flanges 16 A sealing member inserting step (S130) of coaxially positioning the coupling holes (18, 22) of the upper and lower flanges (16, 20) and the upper and lower flanges (16, 20) and the upper and lower coupling ends (102, 152);
The upper and lower coupling ends 102 and 152 are respectively installed on the upper and lower surfaces of the upper and lower sealing members 160 and the through holes 104 and 154 of the upper and lower coupling ends 102 and 152 are inserted into the coupling hole 18 (S140) for positioning the upper and lower housings (100, 150) to the bushing (10) by clamping the fixing member (110);
A gas injection step (S150) of injecting gas by connecting a supply hose (132) to a gas supply pipe (130) formed on an outer circumferential surface of the upper and lower housings (100, 150);
A pressure measuring step S160 of measuring a pressure inside the upper and lower housings 100 and 150 by providing a pressure gauge 142 to the pressure measuring tube 140 formed on the outer circumferential surface of the upper and lower housings 100 and 150;
An internal pressure measuring step S170 in which the pressure sensing member 170 is installed in the pressure measurement hole 34 of the bushing 10 to measure the internal pressure of the bushing 10 to detect damage to the bushing 10, ). ≪ / RTI >

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