KR101915323B1 - Plug-in bushing and method of testing for withstanding voltage - Google Patents

Abstract

[PROBLEMS] To provide a plug-in bushing and a withstand voltage test method capable of saving space and improving work efficiency in a power apparatus having a cable head capable of connecting a power cable terminal in a plug-in type.
[MEANS FOR SOLVING PROBLEMS] A plug-in bushing comprises a rod-shaped inner conductor, an epoxy bushing formed on an outer circumferential surface of the inner conductor so as to expose both ends of the inner conductor, A second insulation reinforcing portion formed on an outer circumferential surface of the end connection side of the epoxy bushing; a compression device for pressing the second insulation reinforcement portion against the cable head; And a conductor plug for electrically connecting the internal conductor and the termination connection structure. The electric field mitigation portion of the first insulation reinforcement portion and the conductive portion of the second insulation reinforcement portion are electrically connected to the conductive layer formed on the outer peripheral surface of the epoxy bushing, respectively.

Description

PLUG-IN BUSHING AND METHOD OF TESTING FOR WITHSTANDING VOLTAGE BACKGROUND OF THE INVENTION 1. Field of the Invention [0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plug-in type bushing for charging a power device such as a gas insulated switch (GIS) or a transformer and an electric strength test method using the same.

Generally, electric power equipment used in waterproofing facilities is equipped with a circuit breaker, disconnector, bus line, lightning arrester, etc. in a grounded container filled with insulating gas such as sulfur hexafluoride (SF ₆ ) A transformer in which an insulating gas such as sulfur hexafluoride (SF ₆ ) gas or an insulating oil is sealed as an insulating medium in a case accommodating a gas insulated switchgear, a coil and an iron core is known. When installing power equipment such as gas insulated switchgear or transformer on site, it shall be subjected to a withstand voltage test to ensure that it maintains the dielectric strength to withstand use.

Conventionally, withstanding voltage test of a power device such as a gas insulated switchgear or a transformer is carried out by, for example, inspecting a bushing having a hollow insulation structure in one end in a gas-insulated device, (For example, see FIG. 1 of Patent Document 1).

The withstand voltage test of a power device connected to a power device of a plug-in type power cable terminal is performed by, for example, connecting a terminal connector provided at one end of a test lead cable to the device, (For example, Patent Document 2).

Patent Document 1: JP-A-59-47907 Patent Document 2: JP-A-7-270484

However, in the method of FIG. 1 of Patent Document 1, the space in the overheated air side may be small, but the internal space of the gas-insulated switching device is opened to the atmosphere at the time of mounting or disassembling the test bushing, It is necessary to sew the gas. Therefore, it takes a great deal of effort and work time, and work efficiency is bad. The same is true for transformers.

On the other hand, according to the method described in Patent Document 2, since the test lead cable can be connected to the power device in the plug-in type, there is an advantage that the sewing process of the insulating gas is not required. However, since a test lead cable is disposed at the time of the withstand voltage test of the power equipment, a relatively large end connection unit is provided, and therefore, it is necessary to secure a large space. The air terminal connection portion provided on the test lead cable is replaced with a simple type using a heat shrinkable tube. In this case, however, it is also necessary to secure a sufficient space in consideration of the bending radius of the test lead cable.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is an object of the present invention to provide a plug-in bushing and a withstand voltage test method that can save space and power efficiency of a power device such as a gas insulated switchgear, a transformer, The purpose.

A plug-in bushing according to the present invention is a plug-in bushing for allowing a power cable terminal to be connected in a plug-in type to a power device having a device side bushing and a cable head having a device side conductor,

A rod-shaped inner conductor,

An epoxy bushing formed on an outer circumferential surface of the inner conductor, the epoxy bushing being formed of an epoxy resin so that both ends of the inner conductor are exposed;

A first insulation reinforcing portion made of a rubber-made condenser concealed on the outer peripheral surface on the air side of the epoxy bushing,

A second insulation reinforcing portion which is fitted in an outer peripheral surface of the end portion of the epoxy bushing and is inserted into a receiving hole of the device side bushing,

And a compression device for pressing the second insulation reinforcing portion against the cable head,

Wherein the first insulation reinforcing portion includes an insulation portion formed of an insulating rubber material, an electric field relieving portion made of a conductive rubber material and formed of a plurality of tubular electrodes,

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Wherein the second insulation reinforcing portion is made of a rubber stress cone having an insulating rubber portion and a conductive portion formed in a bell mouth shape,
A conductive layer is formed on the outer circumferential surface of the epoxy bushing,
Wherein the electric field relaxation portion is buried in the insulation portion so that the electric field relaxation portion partially overlaps in the longitudinal direction in which the adjacent electrodes do not contact,
The plurality of tubular electrodes include a tubular electrode having the largest outer diameter and including an electrode tapered portion arranged from the front end side to the center portion and a cylindrical electrode having a larger diameter toward the rear end side, Respectively,
Wherein the first insulation reinforcing portion is disposed on the outer periphery of the conductive layer so that the tip end side of the tubular electrode having the largest outer diameter comes into contact with the end side end portion of the conductive layer,

And the second insulation reinforcing portion is disposed on the outer periphery of the conductive layer so that the conductive portion contacts the end-connection-side end portion of the conductive layer.

Here, in the plug-in bushing, the side to be attached to the cable head of the power device is referred to as a 'terminal connection side' and the side to which the voltage is applied is referred to as a ' do.

The withstand voltage test method according to the present invention is characterized in that the plug-in bushing is mounted on the cable head to overcharge the power device.

According to the plug-in bushing of the present invention, there is no need to use a power cable for over-charging the power equipment such as a gas insulated switchgear or a transformer, so space can be saved. In addition, since it is possible to connect to a power device in which an insulating gas such as a gas insulated switchgear or the like is sealed in a plug-in type, the mounting work is extremely easy and the sewing process for insulating gas is also unnecessary. Therefore, according to the plug-in bushing of the present invention, it is possible to save space and increase the working efficiency when power is supplied to a power device such as a gas insulated switchgear.

Further, according to the withstand voltage test method of the present invention, since the installation and disassembly work of the plug-in bushing for overcharging the power equipment is improved, the working efficiency is remarkably improved.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a view showing a power device to which a plug-in bushing according to an embodiment can be connected. Fig.
2 is an enlarged view of a cable head mounted on a power device.
3 is a view showing a plug-in bushing according to the first embodiment.
Fig. 4 is an enlarged view of a terminal-connection side of the plug-in bushing according to the first embodiment. Fig.
5 is a view showing the connection state of the plug-in bushing and the cable head according to the first embodiment.
6 is an enlarged view of a connection portion of the plug-in bushing and the cable head according to the first embodiment.
7 is a view showing a plug-in bushing according to the second embodiment.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

[First Embodiment] Fig.

Fig. 1 is a view showing a power device to which a plug-in bushing according to the present embodiment can be connected, and Fig. 2 is an enlarged view of a cable head mounted on a power device.

1, the power-supply device 100 includes a circuit breaker 31, a disconnecting unit 32, a bus-line electric line 33, and the like within a grounding container 101 in which an insulating gas such as SF ₆ is sealed. (3) of the gas insulated switchgear. The power supply apparatus 100 includes an elephant section 100B as a connection section for connecting the device accommodating section 100A accommodating the charger 3 and a power cable (not shown) for charging the charger 3, .

The cable head 2 is provided in the element portion 100B and the power cable terminal subjected to termination processing corresponding to the cable head 2 can be connected in a plug-in type. During normal operation of the power device 100, the cable head 2 is used in a state in which the power cable terminal is connected.

As shown in Fig. 2, the cable head 2 has a device side bushing 21, a device side conductor 22, and the like.

The device-side bushing 21 is a hollow molded product made of, for example, a hard insulator such as an epoxy resin. The apparatus-side bushing 21 includes a cylindrical head portion 21a, a bell-shaped body portion 21b, a conductive coating material applied on the surface thereof, and a bell mouth- A shielding portion 21c having a concave portion, a flange-shaped device fixing portion 21d protruding outward in the radial direction, and an insulating cylinder portion 21e. On the other hand, the shape of the device side bushing 21 is not limited to this.

The device fixing portion 21d is formed to be larger than the aperture of the opening 101a so as to be caught by the opening 101a of the grounding container 101. [ A conductive layer (not shown) is formed on the outer surface extending from the shielding portion 21c to the bolt insertion side of the device fixing portion 21d by applying a conductive paint. This conductive layer comes into contact with the grounding container 101, so that the outer surface of the shielding portion 21c becomes the ground potential. The insulating tube portion 21e is extended to the rear end side of the device fixing portion 21d. The plug-in bushing 1 connected to the ground on the grounding container 101 side of the power unit and the cable head 2 is formed by the insulating cylinder portion 21e because the conductive layer is not provided on the outer circumferential surface of the insulated cylinder portion 21e. Ground is insulated.

The device side bushing 21 is inserted into the grounding container 101 via the opening 101a. A ring-shaped concave groove (not shown) is formed on the contact face of the grounding container 101 or the device fixing portion 21d, and a seal member (not shown) such as an O ring or a packing is disposed in the concave groove. In this state, the device side bushing 21 is hermetically fixed to the grounding container 101 by fastening the device fixing portion 21d to the grounding container 101 with a plurality of bolts. That is, the insulating gas sealed in the grounding container 101 does not leak out from the opening 101a.

The device side conductor 22 is a metal member suitable for energizing copper, copper alloy, aluminum, aluminum alloy, or the like. The device side conductor 22 is formed integrally with the device side bushing 21 by molding.

The device side conductor 22 includes a conductor withdrawing portion 22a protruding from the distal end portion 21g of the device side bushing 21 and a cylindrical portion 22b embedded in the inner circumferential surface of the head portion 21a of the device side bushing 21. [ A neck portion 22c for connecting the conductor withdrawing portion 22a and the cylindrical portion 22b and a locking portion 22d projecting from the neck portion 22c toward the receiving port 21f of the device side bushing 21, .

The conductor lead portion 22a is electrically connected to the charging portion 3 via the high-voltage conductor (not shown) on the device side in the grounding container 101. [

The one end side of the conductive ring-shaped contact 23 (so-called tulip contact) is engaged with the engagement portion 22d. A conductor connection terminal (not shown) connected to the power cable is caught or the conductor plug 16 (described later) of the plug-in bushing 1 is inserted into the other end side of the ring- The device side conductor 22 is electrically connected to the plug-in bushing 1 via the ring-shaped contact 23.

As described above, the power device 100 is provided with a cable head 2 that can connect the power cable in a plug-in type. The cable head 2 includes a device side bushing 21 capable of inserting the end connection side of the plug-in bushing 1, a device side conductor 22 electrically connected to the conductor plug 16, And a ring-shaped contact 23 connected to the device side conductor 22 and the other end connected to the conductor plug 16.

When installing the power-supply device 100 on site, it is confirmed whether or not the withstand voltage test is carried out to maintain the dielectric strength withstanding use. When performing the withstand voltage test, the plug-in bushing 1 according to the present embodiment is used.

Further, the element section 100B is configured to be rotatable so that the upper and lower sides can be reversed. That is, in the normal state, the cable head 2 is positioned downward so as to secure the stability of the connection state with the power cable (refer to FIG. 1) (See Fig. 5).

Fig. 3 is a view showing the plug-in bushing 1 according to the present embodiment, and Fig. 4 is an enlarged view of the end-connection side of the plug-in bushing 1. Fig. The plug-in bushing 1 is provided with a cable 2 for a power device 100 (see FIG. 1) having a cable head 2 capable of connecting the power cable in a plug- And is mounted on the head 2 to overcharge.

For convenience of explanation, in the plug-in bushing 1, the side on which the power device 100 is mounted to the cable head 2 with the flange portion 122 as a boundary is referred to as a " Is called the " air side ". In the following description, the side to be inserted into the cable head 2 (upper side in FIG. 3) may be referred to as a "front end side" and the opposite side (lower side in FIG. 3) may be referred to as a "rear end side".

3, the plug-in bushing 1 includes an inner conductor 11, an epoxy bushing 12, a first insulation reinforcement 13, a second insulation reinforcement 14, a compression device 15, A plug 16 and the like.

The inner conductor 11 is a rod-like member made of metal suitable for energizing copper, a copper alloy, aluminum, or an aluminum alloy. A conductor plug 16 is connected to the front end (terminal connection side) of the inner conductor 11, and a lead wire for applying a voltage to the rear end (air side) is connected.

The epoxy bushing 12 is made of an epoxy resin and is formed on the outer circumferential surface of the inner conductor 11 by molding to expose the inner conductor 11 from both ends. A flange portion 122 having an outer diameter larger than the end connecting side and the air-side side is formed between the end connection side and the air-side side of the epoxy bushing 12. The first insulation reinforcing portion 13 is formed on the outer peripheral surface on the air side of the epoxy bushing 12 and the second insulation reinforcing portion 14 is formed on the outer peripheral surface of the end connection side.

The outer surface of the epoxy bushing 12 extending from the front end portion 13a of the first insulation reinforcing portion 13 to the rear end portion 14a of the second insulation reinforcing portion 14 is coated with a conductive paint, The conductive layer 121 is formed. 3 and 4, the dotted line indicating the conductive layer 121 is shown inside the outer periphery of the epoxy bushing 12 for convenience of explanation. The shielding layer of the epoxy bushing 12 is formed by setting the conductive layer 121 to the ground potential.

Side end of the conductive layer 121 is in contact with the tip end side of the electrode 132 of the first insulation reinforcing portion 13 and forms an electrode tapered portion 132a having a gentle inclination. By this inclination, the electric field concentrated on the end on the air-side side of the conductive layer 121 is relaxed. The end of the conductive layer 121 on the end connection side is in contact with the conductive portion 142 of the second insulation reinforcing portion 14 to form a tapered portion having a gentle inclination. By this inclination, the electric field concentrated on the end of the conductive layer 121 on the end connecting side is relaxed.

In this embodiment, the conductive layer 121 is formed on the outer peripheral surface extending from the front end portion 13a of the first insulation reinforcing portion 13 to the rear end portion 14a of the second insulation reinforcing portion 14. However, An insulating portion may be provided for separating the conductive layer 121 from the intermediate portion and electrically separating the ground layer on the termination side from the ground layer on the air side.

The first insulation reinforcing portion 13 is a condenser cone formed in a spindle shape as a whole, and is fitted to the air side of the epoxy bushing 12. The first insulation reinforcing portion 13 includes an insulating portion 131 and a plurality of tubular electrodes 132. Specifically, the center of the electrode 132 is composed of a tubular electrode having the largest outer diameter including the electrode tapered portion 132a, and a plurality of cylinders in which the diameter gradually decreases from the center toward the rear end, . The insulating portion 131 is made of an insulating rubber material such as ethylene propylene rubber (EP rubber) or silicone rubber. The electrode 132 is made of a conductive rubber material which is made conductive by incorporating carbon black or the like into an insulating rubber material. This electrode 132 is an electric field relieving portion of the first insulation reinforcing portion 13.

The electrode 132 is buried in the insulating portion 131 such that the adjacent electrodes do not contact each other and partially overlap each other in the longitudinal direction. The distal end side of the electrode 132 (the distal end side of the tubular electrode having the largest outer diameter) is connected to the outer periphery of the conductive layer 121 so as to come into contact with the end portion of the conductive layer 121 formed in the epoxy bushing 12 . As a result, the tubular electrode having the largest outer diameter among the electrodes 132 becomes the ground potential, and the remaining plurality of cylindrical electrodes function as a capacitor by sharing a voltage. The local concentration of the electric field on the side of the air is mitigated by the first insulation reinforcing portion 13 (condenser cone).

In addition, the relative positions of the epoxy bushing 12 and the cylindrical electrode forming the condenser and the number of electrodes are not limited to the present embodiment, but can be changed as appropriate.

The second insulation reinforcing portion 14 is a stress cone made of rubber and made of ethylene propylene rubber (EP rubber), silicone rubber or the like which is formed in a spindle shape as a whole and is fitted to the terminal connection side of the epoxy bushing 12 Loses. The second insulation reinforcing portion 14 includes an insulation rubber portion 141 on the front end side and a conductive portion 142 on the rear end side, which are formed of an insulating rubber material. Here, the conductive portion 142 is formed of a conductive rubber material and is integrally formed with the insulating rubber portion 141 by molding. The conductive portion 142 is not necessarily formed of a conductive rubber material. For example, the conductive portion 142 may be formed by applying a conductive paint to the surface of the insulating rubber material.

The insulating rubber portion 141 and the conductive portion 142 are integrally formed. The conductive part 142 is formed in a bell mouth shape and is connected to the conductive layer 121 formed in the epoxy bushing 12. The localized concentration of the electric field on the terminal-connection side is alleviated by the second insulation reinforcing portion (14).

The outer periphery of the insulating rubber portion 141 of the second insulation reinforcing portion 14 has a shape corresponding to the receiving port 21f of the cable head 2 to be mounted, 2 to the receiving port 21f.

The compression device 15 is provided with a pusher 151, a spring 152, a presser flange 153, and the like. The compression device 15 is fixed to the epoxy bushing 12 by means of a clamp 41.

The tip opening 151a of the push rod 151 is formed in a trumpet shape along the outer peripheral surface of the rear end side of the second insulation reinforcing portion 14 (the outer peripheral surface of the conductive portion 142). A plurality of spring receiving portions 151c are formed along the circumferential direction at the rear end portion 151b of the push rod 151. [ A coil-shaped spring 152 is mounted on the spring receiving portion 151c.

A projecting portion 153a for supporting the rear end portion of the spring 152 is formed inside the rear end portion of the press-fitting flange 153. A plurality of screw holes 153b for tightening the bolts 43 are formed on the outer circumference of the rear end of the press-fitting flange 153 on the same circumference. A plurality of insertion holes 153c for inserting the bolts 42 are formed on the distal end of the pressing flange 153 on the same circumference.

The circumferential positions of the bolt 42 and the bolt 43 are shifted so as not to interfere with each other. A notch portion (not shown) is provided at a position corresponding to the bolt 42 of the fixing portion 41a of the fastener 41 so that the bolt 42 can be mounted on the cable head 2. [

The clamp 41 has a metal cylindrical portion 41b located on the outer periphery of the flange portion 122 of the epoxy bushing 12 and a spring portion 41b formed to protrude outward in the radial direction from the tip side of the metal cylindrical portion 41b, A fixing portion 41a protruding inward in the radial direction from the rear end side of the metal cylindrical portion 41b and fixed to the flange portion 122 of the epoxy bushing 12, And a holding portion 41c that is hooked to the rear end face (the air side). An insertion hole 41d is formed at a position corresponding to the screw hole 153b formed in the pressing flange 153 at the fixing portion 41a of the fixing member 41. [

The holding portion 41c of the fixing bracket 41 is hooked to the rear end surface 122a (base side) of the flange portion 122 of the epoxy bushing 12, (153). The bolt 43 is inserted into the insertion hole 41d and fastened to the screw hole 153b of the press fitting flange 153 so that the fastener 41 is fixed to the press fitting flange 153. The compression device 15 is fixed to the epoxy bushing 12 in a state in which the spring 152 is supported.

In the rear end surface of the insulation sleeve portion 21e of the cable head 2, a buried metal fitting 44 is disposed at a position corresponding to the insertion hole formed in the pressing flange 153. [ The plug-in bushing 1 is attached to the cable head 2 by inserting the bolt 42 into the insertion hole 153c of the press-fitting flange 153 and tightening the bolt 42 to the embedding metal. At this time, the second insulation reinforcing portion 14 is pressed to the cable head 2 side by the compression device 15, and the second insulation reinforcing portion 14 is elastically deformed to come in close contact with the inner surface of the cable head 2 .

Like the internal conductor 11, the conductor plug 16 is made of a metal material suitable for energization and is connected to the tip of the internal conductor 11. [ The conductor plug 16 facilitates the mounting operation of the plug-in bushing 1 to the cable head 2 and protects the leading end of the inner conductor 11 from being damaged.

The conductor plug 16 has a small diameter portion 16a on the tip end side connected to the device side conductor 22 and a large diameter portion on the rear end side connected to the internal conductor 11 16b are extended.

A conductor insertion hole 16c for inserting the tip end of the inner conductor 11 is formed at the rear end face center of the large diameter portion 16b. In addition, a concave groove 16d in which a spring contact (not shown) is disposed is formed on the inner circumferential surface of the conductor insertion hole 16c. As a spring-like contact, a multilam band (not shown), which is a multi-point contact type contact, is disposed.

On the outer peripheral surface of the rear end of the large-diameter portion 16b of the conductor plug 16, screw holes 16e penetrating in the radial direction are formed at a plurality of places (for example, three places) along the circumferential direction. The end of the inner conductor 11 is inserted into the conductor insertion hole 16c of the conductor plug 16 and the fixing screw (not shown) is inserted into the screw hole 16e to tighten the conductor plug 16, (11) and electrically connected thereto. A multi-ram band (not shown) is interposed between the conductor plug 16 and the internal conductor 11, so that both are well conducted.

Here, if the fixing screw is located in a portion near the shield at the rear end of the device-side conductor 22, the fixing screw may protrude due to an electric field entering the shield, which may cause generation of a partial discharge . Therefore, the fixing screw (not shown) mounted on the screw hole 16e is positioned deeper than the shield (arcuate portion) of the rear end portion of the equipment side conductor 22 of the cable head 2 The screw hole 16e is formed so that the screw hole 16e is positioned at the side of the screw hole 16e. This makes it difficult to receive the influence of the electric field entering the shield of the device side conductor 22.

As a spring contact member, a ball seal (BAL SEAL) may be applied instead of a multi-ram band. In this case, the concave groove 16d becomes a shape suitable for disposing the seal.

Although the spring contact is provided on the inner peripheral surface (recessed groove 16d) of the conductor insertion hole 16c, it may be provided on the outer periphery of the tip of the internal conductor 11. However, in consideration of the molding of the epoxy bushing 12, it is preferable that the spring-like contact is provided in the recessed groove 16d formed in the inner circumferential surface of the conductor insertion hole 16c as in the present embodiment.

A ring-shaped insulating stopper 19 is provided between the conductor plug 16 and the epoxy bushing 12, that is, on the end surface of the epoxy bushing 12. The front end face of the insulating stopper 19 abuts against the rear end face of the conductor plug 16. The outer periphery of the rear end face of the insulating stopper 19 protrudes to the rear end side so as to cover the outer periphery of the tip end portion of the epoxy bushing 12 in this embodiment. The insulating stopper 19 causes the second insulation reinforcing portion 14 (stress cone), which is pressed by the compression device 15, to protrude toward the tip side when the plug-in bushing 1 is mounted on the cable head 2 Prevent it from coming out. When inserting the plug-in bushing 1 into the cable head 2, since the insulating stopper 19 makes sliding contact with the inner surface of the cable head 2, the inner surface of the cable head 2 can be prevented from being damaged .

A step portion (shoulder portion) is provided on the distal end face of the large-diameter portion 16b which is a portion where the small-diameter portion 16a extends from the conductor plug 16, and a first insulator 18 is provided on the step portion . Here, the outer periphery of the front end face stepped portion of the large-diameter portion 16b of the conductor plug 16 and the inner periphery of the first insulator 18 are screwed together. The first insulator 18 is made of, for example, somalite (trade name) which is ultra high molecular weight polyethylene.

When the plug-in bushing 1 is mounted on the cable head 2, the large-diameter portion 16b of the conductor plug 16 is inserted into the inner peripheral surface of the apparatus-side bushing 21 while sliding. At this time, if the shoulder portion of the large-diameter portion 16b comes into contact with the inner peripheral surface of the device-side bushing 21, there is a fear that the inner peripheral surface of the device- Here, since the first insulator 18 is provided on the shoulder portion of the large-diameter portion 16b, it is possible to effectively prevent the inner peripheral surface of the device-side bushing 21 from being damaged due to the insertion of the conductor plug 16.

In the conductor plug 16, a second insulator 17 is provided at the tip of the small-diameter portion 16a. Here, the threaded portion provided on the end face of the conductor plug 16 and the threaded hole provided on the rear end face of the second insulated body 17 are screwed. The second insulator 17 is composed of, for example, somalite (trade name) which is ultra high molecular weight polyethylene.

When the plug-in bushing 1 is mounted on the cable head 2, the small-diameter portion 16a of the conductor plug 16 is electrically connected by making contact with the rear end of the ring-shaped contact 23 (tulip contact).

Normally, when the power cable terminal is mounted on the cable head 2, the conductor connection terminal on the power cable terminal side is provided with a holding structure by the ring-shaped contact 23, A protruding engagement structure is provided so that the distal end surface of the conductor connection terminal does not contact the engagement portion 22d of the device-side conductor 22. In the present embodiment, the conductor plug 16 (small-diameter portion 16a) of the plug-in bushing 1 is not provided with a latching structure for catching the ring-shaped contact 23 (tulip contact) 1) to the cable head 2, the tip of the plug-in bushing 1 (the second insulator 17) touches the device-side conductor 22 (the engaging portion 22d) ) Is completed. Therefore, if the conductor plug 16 directly contacts the device-side conductor 22, the device-side conductor 22 may be damaged. Since the second insulator 17 is interposed between the device side conductor 22 and the front end of the conductor plug 16, the insertion of the plug-in bushing 1 into the cable head 2 causes the device side conductor 22 Can be effectively prevented from being damaged.

When the conductor plug 16 directly contacts the device side conductor 22, the conductor plug 16 can be directly connected to the device side conductor 22 or the ring contact 23 So that current flows (sorting occurs). In this state, if a large current flows due to a short-circuit accident or the like, the energizing section becomes hot and the device-side conductor 22 and the conductor plug 16 may be melted. Here, the second insulator 17 is interposed between the conductor plug 16 and the equipment-side conductor 22, so that the conductor plug 16 and the equipment-side conductor 22 do not directly communicate with each other, . That is, since the classification does not occur, the device-side conductor 22 and the conductor plug 16 are not melted even if a short-circuit accident occurs.

Fig. 5 is a view showing the connection state between the cable head and the plug-in bushing, and Fig. 6 is an enlarged view of the connection portion between the cable head and the plug-in bushing.

5, when the electric power device 100 is subjected to the withstanding voltage test, the cable head 2 is positioned at the upper side (the leading end side of the cable head 2 is directed downward) . Then, the plug-in bushing 1 is mounted on the cable head 2 of the power unit 100.

Specifically, as shown in Fig. 6, the plug-in bushing 1 is inserted into the cable head 2 of the power device 100 and into the receiving port 21f of the device side bushing 21. As shown in Fig. The plug-in bushing 1 is inserted to a position where the second insulator 17 touches the end face of the engaging portion 22d of the device-side conductor 22. In this state, the inner peripheral surface of the rear end (upper side in Fig. 6) of the ring-shaped contact 23 (tulip contact) comes into contact with the outer periphery of the distal end portion of the conductor plug 16 (here the distal end portion of the small diameter portion 16a).

The bolt 42 is used to fix the flange 153 to the embedding metal 44 in the rear end face of the device side bushing 21 (the insulating barrel 21e). At this time, the second insulation reinforcing portion 14 is pressed and elastically deformed at the front end side (lower side in Fig. 6) by the compression device 15 previously fitted in the plug-in bushing 1, .

As described above, the mounting operation of the plug-in bushing 1 to the cable head 2 is extremely simple.

The conductor plug 16 is placed in the receiving port 21f corresponding to the head portion 21a of the apparatus side bushing 21 while the plug bushing 1 is mounted on the cable head 2. [ In other words, the conductor plug 16 is located on the inner periphery of the cylindrical portion 22b of the device-side conductor 22. The second insulation reinforcing portion 14 is located in the receiving port 21f corresponding to the portion extending from the body portion 21b of the device side bushing 21 to the shielding portion 21c. The compression device 15 is located in the receiving port 21f corresponding to the portion extending from the device fixing portion 21d of the device side bushing 21 to the insulating tubular portion 21e.

The second insulation reinforcing portion 14 is pressed toward the device side bushing 21 by the compression device 15 so as to apply a predetermined surface pressure to the interface between the second insulation reinforcing portion 14 and the device side bushing 21 Surface pressure is applied to the end connection side.

The base side of the plug-in bushing 1 is insulated by the dielectric strength of the epoxy bushing 12 itself and the voltage division by the capacitor of the first insulation reinforcement 13. [

As described above, the plug-in bushing 1 has a sufficient insulation performance on the end-connection side and the air-side, and therefore is extremely useful when overcharging the power device 100, such as a withstand voltage test.

Thus, the plug-in bushing 1 includes the rod-like internal conductor 11, the epoxy bushing 12 formed so that both ends of the internal conductor 11 are exposed on the outer peripheral surface of the internal conductor 11, A second insulating reinforcing portion 14 formed on an outer peripheral surface of the epoxy bushing 12 on the terminal connection side and a second insulating reinforcing portion 14 formed on the outer peripheral surface of the epoxy bushing 12 on the terminal connection side, A cable 15 which is connected to the end of the end connecting side of the internal conductor 11 and which is connected to the internal conductor 11 and the device side conductor 22 (cable head 2) And a conductor plug 16 for electrically connecting them. The electrode 132 (electric field mitigation portion) of the first insulation reinforcing portion 13 and the conductive portion 142 of the second insulation reinforcement portion 14 are electrically connected to the conductive layer 142 formed on the outer peripheral surface of the epoxy bushing 12, (Not shown).

According to the plug-in bushing 1, it is not necessary to use a power cable provided with an end connection portion on the side of the air for applying a voltage when the power device 100 such as a gas insulated switchgear or a transformer is overcharged. I can do it. In addition, since it is possible to connect to the power device 100 in which the insulated gas such as the gas insulated switchgear or the gas insulated transformer is sealed in the plug-in type, the mounting work is extremely easy and the sewing process of the insulated gas is also unnecessary. In addition, the disassembling operation becomes easy. Particularly, in the case where the structure in which the ring-shaped contacts 23 are not provided on the plug-in bushing 1 side is not provided as in the present embodiment, the tip end of the plug-in bushing 1 (the second insulator 17) Since the plug-in bushing 1 is structured so as not to be caught by the ring-shaped contact 23, it is extremely easy to disassemble the plug-in bushing 1 Work becomes possible. Therefore, space saving and work efficiency can be improved when the power device 100 such as a gas insulated switchgear is overcharged.

According to the withstand voltage test method using the plug-in bushing 1, since the mounting and dismounting work of the plug-in bushing 1 for overcharging the power device 100 is improved as described above, the working efficiency is remarkably improved, The withstand voltage test of the power-supply device 100 can be performed extremely simply.

[Second Embodiment]

Next, a second embodiment of the plug-in bushing of the present invention will be described in detail with reference to Fig. 3, 4, and 6 are denoted by the same reference numerals, and detailed description thereof is omitted.

For convenience of explanation, in the plug-in bushing 5, the side on which the power device 100 is mounted to the cable head 2 with the flange portion 522 as a boundary is referred to as a " Is called the " air side ". In the following description, the side to be inserted into the cable head 2 (upper side in Fig. 7) may be referred to as a "front side" and the opposite side (lower side in Fig. 7) may be referred to as a "rear side".

7, the plug-in bushing 5 includes an inner conductor 11, an epoxy bushing 52, a first insulation reinforcement 53, a second insulation reinforcement 14, a compression device 15, A plug 16 and the like.

The epoxy bushing 52 is made of an epoxy resin and the internal conductor 11, the epoxy bushing 52 and the shielding metal fitting 532 are integrally formed by molding to expose the internal conductor 11 from both ends do. A flange portion 522 having an outer diameter larger than the end connecting side and the air-side side is formed between the end connecting side and the air-side side of the epoxy bushing 52. The shielding metal fitting 532 is located on the outer peripheral surface of the flange portion 522, and the rear end side (air side) is embedded in the epoxy bushing 52. A first insulation reinforcing portion 53 is integrally formed on the outer peripheral surface on the air side of the epoxy bushing 52 by a mold and a second insulation reinforcing portion 14 is formed on the outer peripheral surface of the end connection side.

In the epoxy bushing 52, an outer circumferential surface extending from the distal end portion 53a of the first insulation reinforcing portion 53 (front end surface of the shielding metal 532) to the rear end portion 14a of the second insulation reinforcing portion 14, A conductive layer 521 is formed by applying a conductive paint, for example. 7, the dotted line representing the conductive layer 521 is shown inside the outer periphery of the epoxy bushing 52 for convenience of explanation. By setting the conductive layer 521 to the ground potential, a shielding layer of the epoxy bushing 52 is formed.

The end portion of the conductive layer 521 on the air side side is in contact with the distal end surface of the shielding metal fitting 532 of the first insulation reinforcing portion 53. Since the electric field relaxation structure is formed in the rear end side (tubular portion 532a) of the shielding metal fitting 532, the electric field concentration at the end on the air side of the conductive layer 521 is alleviated. The end of the conductive layer 521 on the end connection side is in contact with the conductive portion 142 of the second insulation reinforcing portion 14 to form a tapered portion having a gentle inclination. By this inclination, the electric field concentrated on the end of the conductive layer 121 on the end connecting side is relaxed.

The first insulation reinforcing portion 53 is integrally formed by a mold on the outer circumferential surface on the air side of the epoxy bushing 52 to form a polymer bushing on the air side of the plug-in bushing 5. Here, the first insulation reinforcing portion 53 includes a polymer covering body 531 and a shielding metal fitting 532. The polymer covering body 531 is made of a polymer insulating material such as silicone rubber. The shielding metal fitting 532 is made of a conductive rubber material which is made conductive by incorporating carbon black or the like into an insulating rubber material. This shielding metal fitting 532 is an electric field relief portion of the first insulation reinforcing portion 53.

The polymer covering body 531 is provided on the outer circumferential surface on the air side of the epoxy bushing 52 and a plurality of wall portions are formed on the outer circumference of the polymer covering body 531 along the longitudinal direction of the polymer covering body 531.

The shielding metal fitting 532 includes a tubular portion 532a buried concentrically with the inner conductor 11 on the tip side of the epoxy bushing 52 on the air side and a tubular portion 532b extending from the distal end side of the tubular portion 532a An intermediate portion 532b which has a rear end portion in contact with the distal end portion of the polymer covering body 531 and a metal portion 532b which is provided on the outer peripheral surface of the flange portion 522 of the epoxy bushing 52, And a flange portion 532c.

Since the rear end portion (the rear end portion of the tubular portion 532a) of the shielding metal fitting 532 is on a section circular arc, the shielding metal fitting 532 has an electric field relaxation structure and alleviates the electric field on the air side of the epoxy bushing 52 .

The compression device 15 is provided with a pusher 151, a spring 152, a presser flange 153, and the like. The compression device 15 is fixed to the epoxy bushing 52 by a shielding metal fitting 532.

A projecting portion 153a for supporting the rear end portion of the spring 152 is formed inside the rear end portion of the press-fitting flange 153. A plurality of screw holes 153b for tightening the bolts 45 are formed on the outer circumference of the rear end of the press fitting flange 153 on the same circumference. A plurality of insertion holes 153c for inserting the bolts 42 are formed on the distal end of the pressing flange 153 on the same circumference.

Further, the circumferential positions of the bolt 42 and the bolt 45 are shifted from each other so as not to interfere with each other. A notch portion (not shown) is provided at a position corresponding to the bolt 42 of the metal flange portion 532c of the shielding metal fitting 532 so as to mount the bolt 42 to the cable head 2. [ A plurality of insertion holes for inserting the bolts 45 are formed on the distal end face of the metal flange portion 532c of the shielding metal fitting 532 on the same circumference.

The bolt 45 is inserted into the insertion hole of the metal flange portion 532c of the shielding metal fitting 532 and tightened to the screw hole 153b of the press fitting flange 153 so that the press fitting flange 153 is fitted to the shielding metal fitting 532 . The compression device 15 is fixed to the epoxy bushing 52 in a state in which the spring 152 is supported.

The other configuration of the end connection side of the plug-in bushing 5 and the mounting method thereof to the cable head 2 are the same as those of the plug-in bushing 1 of the first embodiment, and the description thereof will be omitted.

Since the structure of the plug-in bushing 5 of the second embodiment and the plug-in bushing 1 of the first embodiment are the same as that of the plug-in bushing 5 of the second embodiment, The effect as an effect and withstand voltage test method is the same as that of the plug-in bushing 1 of the first embodiment. Since the air side of the plug-in bushing 5 is integrally molded by the mold, more stable electric characteristics of the air side are obtained compared with the insulation performance of the plug-in bushing 1 on the air side.

Although the invention made by the present inventors has been specifically described based on the embodiments, the present invention is not limited to the above embodiments, and can be changed without departing from the gist of the invention.

For example, the plug-in bushings 1 and 5 may be applied not only to the withstand voltage test but also as a bushing that constantly overcomes the power device 100. In this case, a machining line, a lead line, and the like are connected to the rear end (on the air side) of the plug-in bushes 1, 5. In the case of the plug-in bushing 1, it is very suitable because it does not deteriorate the first insulation reinforcing portion 13 made of rubber by ultraviolet rays, particularly when it is used for overturning to power equipment 100 installed indoors . In the case of the plug-in bushing 5, since the polymer bushing is formed on the side of the air, it is very suitable as a bushing which constantly overturns the plug-in bushing 1.

The embodiments described above are to be considered in all respects as illustrative and not restrictive. The scope of the present invention should be construed as including all changes within the meaning and scope equivalent to the claims defined in the claims.

1, 5 plug-in bushing
2 cable head
3 live part
11 Internal conductor
12, 52 Epoxy Bushing
13, 53 First insulation reinforcing portion
14 Second insulation reinforcing portion
15 Compressor
16 conductor plug
17 Second insulator
18 First insulator
19 Insulation stopper
21 Device side bushing
22 Device side conductor
23 Ring contact
41 bracket
42 volts
43 volts
44 Reclamation bracket
45 volts
100 power equipment
100A device accommodating portion
100B Elephant part
101 grounding container
121, 521 conductive layer
122, 522,
131 insulation
132 Electrodes
141 Insulating rubber part
142 conductive part
151 Pusher
152 spring
153 Push Flange
531 Polymer coated body
532 Shielding bracket

Claims (10)

1. A plug-in bushing for overturning a power device having a device side bushing and a device cable side conductor capable of connecting the power cable terminal in a plug-in type,
A rod-shaped inner conductor,
An epoxy bushing formed on an outer circumferential surface of the inner conductor, the epoxy bushing being formed of an epoxy resin so that both ends of the inner conductor are exposed;
A first insulation reinforcing portion made of a rubber-made condenser concealed on the outer peripheral surface on the air side of the epoxy bushing,
A second insulation reinforcing portion which is fitted in an outer peripheral surface of the end portion of the epoxy bushing and is inserted into a receiving hole of the device side bushing,
And a compression device for pressing the second insulation reinforcing portion against the cable head,
Wherein the first insulation reinforcing portion includes an insulation portion formed of an insulating rubber material, an electric field relieving portion made of a conductive rubber material and formed of a plurality of tubular electrodes,
Wherein the second insulation reinforcing portion is made of a rubber stress cone having an insulating rubber portion and a conductive portion formed in a bell mouth shape,
A conductive layer is formed on the outer circumferential surface of the epoxy bushing,
Wherein the electric field relaxation portion is buried in the insulation portion so that the electric field relaxation portion partially overlaps in the longitudinal direction in which the adjacent electrodes do not contact,
The plurality of tubular electrodes include a tubular electrode having the largest outer diameter and including an electrode tapered portion arranged from the front end side to the center portion and a cylindrical electrode having a larger diameter toward the rear end side, Respectively,
Wherein the first insulation reinforcing portion is disposed on the outer periphery of the conductive layer so that the tip end side of the tubular electrode having the largest outer diameter comes into contact with the end side end portion of the conductive layer,
Wherein the second insulation reinforcing portion is disposed on the outer periphery of the conductive layer so that the conductive portion contacts the end-connection-side end portion of the conductive layer. The method according to claim 1,
Wherein a flange portion having an outer diameter larger than that of the end connection side and the air side is formed between the end connection side and the air introduction side of the epoxy bushing. 3. The method of claim 2,
Wherein the compression device comprises:
A tip end of which is formed in a trumpet shape along an outer peripheral surface of the conductive portion,
A spring mounted on a spring receiving portion formed at a rear end of the presser,
And a pushing flange having a protrusion for supporting a rear end portion of the spring. The method of claim 3,
A clamp is fitted to the rear end face of the flange portion,
And the front end surface of the fixture is in contact with a rear end surface of the press fitting flange. The method according to claim 1,
And a conductor plug for electrically connecting the inner conductor and the cable head is connected to a tip end of the inner conductor on a terminal connection side. A method for testing a withstand voltage of a power device, comprising: mounting the plug-in bushing of claim 1 on the cable head to overcharge the power device.
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