KR101348319B1 - Insulator of overhead line for high voltage distribution - Google Patents

Abstract

The present invention is to minimize the effect of an electromagnetic wave on a human which is near the electromagnetic wave by effectively shielding the electromagnetic wave generated in an overhead line for extra-high voltage distribution with the insulating cover unit of an insulator of an overhead line for extra-high voltage distribution, and to minimize a total damage to the insulator by protecting the insulator from corona even if the insulation of the insulator is partly broken.

Description

Insulator of overhead wire for extra-high voltage distribution {insulator of overhead line for high voltage distribution}

The present invention relates to insulated insulators of overhead wires for high voltage distribution, and more particularly to insulated insulators for overhead wires for supporting high voltage distribution.

In general, insulator is an insulator that is fixed on a wrought iron fixed through a band to an electric pole and is used to insulate the spiral portion of an overhead wire for special high voltage distribution and mechanically maintain or support it at the same time.

The insulator simply has a function of fixing the overhead cable for the extra-high voltage distribution, and in order to install the overhead cable for the extra-high voltage distribution in general, the worker is pulled by hand to connect the loose portion so that the middle part sags downward.

An example of such an insulator is disclosed in Korean Utility Model Registration No. 20-0338694 (registered Jan. 05, 2004, hereinafter referred to as 'Patent Document 1').

The insulator 1 according to the prior art, as shown in FIG. 1, has a support 3 on a temporary plate 9 which is movably installed on a wrought iron 7 installed in the pole 5. Is installed.

However, according to the insulator according to the prior art, since a large amount of electromagnetic waves are generated in the supporting high-voltage distribution cable, there is a problem that if a person stays for a long time at a close distance, it may have a harmful effect on the human body.

In addition, the insulator according to the prior art has a problem that if any part of the insulation is broken, a corona phenomenon may occur and thus be totally broken.

Korean Utility Model Registration No. 20-0338694 (registered on January 05, 2004)

SUMMARY OF THE INVENTION An object of the present invention is to provide an insulator of an overhead high voltage distribution overhead wire that can shield electromagnetic waves generated from a supporting overhead voltage distribution wire.

In addition, even if the insulation is partially destroyed, the overall breakdown is to provide an insulator of the overhead wire for the high voltage distribution that can be minimized.

In order to achieve the above object, the insulator of the overhead wire for special high voltage distribution according to the present invention is:

Insulator body provided with an insulating material;

A bracket provided on an upper portion of the insulator body and supporting a processing wire for extra-high voltage distribution mounted on the upper portion of the insulator body;

A cable through hole is formed to surround the insulator body and the bracket, and a through cable for an extra-high voltage distribution cable supported by the bracket is formed therein, and an electromagnetic shielding layer formed on the insulating layer and the upper and lower surfaces of the insulating layer. An insulation cover unit comprising a bracket cover disposed on an upper portion of the outer surface and surrounding the bracket, and an insulator cover disposed on the lower portion of the bracket cover and surrounding the insulator body;

A displacement detecting unit having a piezoelectric element provided in the bracket cover and generating electricity by pressing the sensor contact unit provided in the bracket when the insulating cover unit is inclined out of a fixed position;

An alarm unit provided to be exposed to the outside from an upper portion of the bracket cover, and receiving an electric signal generated from the displacement detection unit to convert it into a warning signal to inform the outside; And

A controller configured to control the alarm unit to generate a warning signal from the alarm unit when it is determined that the inclination of the insulation cover unit is out of an allowable range based on a result detected by the displacement detector;

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A van der Waals adhesive part is provided on an inner side surface of the insulator cover in which the insulating cover unit is in contact with the insulator body.

The lower end of the insulation cover unit is characterized in that the insulator binding portion of the fringe shape cut radially when viewed from the bottom.

According to the present invention, the insulation cover unit of the insulated insulator of the high voltage distribution wire can effectively shield the electromagnetic waves generated from the high voltage distribution wire, thereby minimizing the influence of electromagnetic waves on people located in close proximity. You can do that.

In addition, even when the insulation insulator of the insulated insulator cover unit of the high-voltage power distribution wire is partially destroyed, the entire breaker of the insulator can be minimized by protecting the insulator from the corona.

1 is a view showing a state in which the insulating insulator according to the prior art is installed on the wrought iron fixed to the pole;
2 is an exploded perspective view showing a state before the insulation cover unit of the insulator of the insulated insulator of the extra-high voltage distribution wire according to the present invention is coupled to surround the insulator body and the bracket;
3 is a side cross-sectional view of the insulating cover unit of FIG. 2, FIG.
Figure 4 is a control block diagram of the insulator of the insulated wire for extra high voltage distribution according to the present invention,
FIG. 5 is a diagram illustrating an example in which an alarm unit notifies the outside of the insulation cover unit due to a change in the position of the processing wire for the extra-high voltage distribution of FIG. 3.

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

As shown in FIGS. 2 and 4, the insulator 100 of the insulated insulator 100 of the extra-high voltage distribution according to the present invention is provided with an insulator body 110 made of an insulating material and an upper portion of the insulator body 110. And an insulating cover unit 200 provided to enclose the insulator main body 110 and the bracket 120 to support the processing wire L for the extra-high voltage distribution to be mounted to the upper portion of the insulator main body 110. And a displacement detection unit 300, an alarm unit 400, and a control unit 500.

Accordingly, the insulation cover unit 200 further improves the insulation efficiency of the insulator body 110, and before the insulation cover unit 200 is peeled off from the in-situ position protecting the insulator body 110 and the bracket 120. This can be easily recognized by the manager so that the necessary actions can be taken in advance.

The insulator main body 110 is installed on a wrought iron (see FIG. 1) and serves to support the wrought iron and the processing wire L for special high voltage distribution so as not to be in electrical contact with each other. As shown in FIG. 5, the convex portion 111 protrudes convexly and the concave portion 113 recessed in the vertical direction.

The bracket 120 has a structure in which one side is rotatably open to the other side so that the processing wire L for the extra-high voltage distribution seated to the upper portion of the insulator main body 110 can be accommodated and installed, and the processing wire for the extra-high voltage distribution After the (L) is accommodated is provided with a structure in which one side is closed by the locking means.

As an embodiment of the present invention, as shown in Figures 2 and 3, the upper middle of the bracket 120, the piezoelectric elements 320 to be described later of the displacement sensing unit 300 to be spaced apart from each other to be installed between The sensor contact portion 121 is provided with a pair of small plates.

Insulating cover unit 200, as shown in Figure 2, the cable through-hole 201 is formed so that the overhead (L) for the extra-high voltage distribution is supported by the bracket 120 is easily penetrated, Figure 3 As shown in FIG. 2, the cross-sectional view includes an insulating layer 210 and an electromagnetic shielding layer 220 formed on upper and lower surfaces of the insulating layer 210, and as shown in FIGS. The bracket cover 230 is provided to surround the bracket 120, and the insulator cover 240 is disposed below the bracket cover 230 to surround the insulator body 110.

Accordingly, the insulating cover unit 200 including the insulating layer 210 and the electromagnetic wave shielding layer 220 can effectively shield the electromagnetic waves generated from the overhead power distribution line L, thereby being located at a close distance. The influence of electromagnetic waves on a person may be minimized, and even if the insulation of the insulator body 110 is partially destroyed, the entire breakage of the insulator body 110 may be minimized by protecting the insulator body 110 from the corona.

The electromagnetic shielding layer 220 may be formed on the outer surface and the inner surface of the insulating cover unit 200 made of the insulating layer 210 by a method such as zinc spraying, plating, and coating of a conductive paint.

In one embodiment of the present invention, the bracket cover 230 is provided in a substantially cylindrical shape with a lower opening to surround the bracket 120, the insulator cover 240 is a convex portion at the top of the insulator body 110 It is preferable that the upper and lower portions are opened to cover the degree of 111, and the bracket cover 230 and the insulator cover 240 are integrally formed.

Meanwhile, as illustrated in FIG. 3, the van der Waals adhesive part 241 is provided on an inner side surface of the insulator cover 240 in which the insulating cover unit 200 is in contact with the insulator body 110.

The van der Waals adhesive part 241 is carbon nano-processed to about 10 μm in length and about 5 μm in diameter so that strong van der Waals adhesive force acts between the insulating cover unit 200 and the insulator body 110. A plurality of bristles are provided on the inner side surface of the insulator cover 240.

Accordingly, when the insulation cover unit 200 covers the insulator body 110 and the bracket 120 to cover the insulator body 200, the van der Waals adhesive part 241 provided on the inner side surface of the insulator cover 240 of the insulation cover unit 200. ) And the van der Waals adhesive force is strongly applied between the upper surface of the insulator body 110 so that the center of the upper surface of the bracket cover 230 of the insulation cover unit 200 meets the center of the insulator body 110 in a vertical line. It is possible to minimize the separation of the insulating cover unit 200 from the position (see FIG. 3).

2 and 3, the lower end of the insulating cover unit 200 is formed with a fringe-shaped insulator binding portion 243 radially cut when viewed from the bottom.

Accordingly, when the insulator body 110 and the bracket 120 are covered to cover the insulator body 110 and the bracket 120 by the insulating cover unit 200, the lower end of the insulator cover 240 is initially insulated from the insulator body 110. Contact with the convex portion 111 and the gap between the insulator binding portions 243 of each of the insulator cover 240, but when the lower end of the insulator cover 240 enters the recess 113 of the insulator body 110 within the insulator cover The lower end of the 240 may be elastically closed to grip the insulator body 110 in close contact.

As shown in FIG. 3, the displacement detector 300 is fixed to the bracket cover 230 by the fixing part 310 fixed to the center of the upper surface of the bracket cover 230 and the fixing part 310. When the insulation cover unit 200 is inclined out of a fixed position, the piezoelectric element 320 generates electricity by pressing the sensor contact portion 121 provided in the bracket 120, the fixing unit 310, and the piezoelectric element ( One side is connected to the fixing part 310 in the bracket cover 230 and the other side extends downward to the piezoelectric element 320 so as to connect between the 320 includes a connecting rod 330 connected to the piezoelectric element 320. .

Accordingly, as shown in FIG. 5, when the insulation cover unit 200 slides from the upper surface of the insulator main body 110 due to sagging of the processing wire L for the extra-high voltage distribution, the bracket cover is removed. The piezoelectric element 320 that is fixedly connected to the 230 and installed between the sensor contacts 121 may be pressurized by the sensor contacts 121 to generate electricity for operating the alarm unit 400.

The piezoelectric element 320 uses a piezo effect in which voltage is generated by electrical polarization when pressure is applied to the crystal, and includes an artificial crystal such as barium titanate.

On the other hand, the displacement detection unit 300 may be provided so as to be able to transmit and receive with the control unit 500 via the fixing unit 310.

The alarm unit 400 is provided to be exposed to the outside from the upper portion of the bracket cover 230, as shown in Figure 5, by receiving an electrical signal generated from the displacement detection unit 300 to convert it into a warning signal Notify outside

Accordingly, when the insulation cover unit 200 is moved out of the correct position protecting the insulator body 110 and the bracket 120, the manager may easily recognize the external cover.

In one embodiment of the present invention, the uppermost of the alarm unit 400 is preferably provided with an LED warning light. As an embodiment of the present invention, the warning signal generated by the alarm unit 400 is described as a light signal, but as another embodiment of the present invention, the warning signal generated by the alarm unit 400 in addition to It can be a variety of acoustic signals, or it can be a transmission signal sent to a remote administrator.

As shown in FIG. 4, when it is determined that the inclination of the insulation cover unit 200 is out of an allowable range based on a result detected by the displacement detecting unit 300, the controller 500 may determine that the alarm unit 400 is not present. The insulator main body 110 is provided on a wrought iron provided with the insulator main body 110 to control the alarm unit 400 so as to generate a warning signal, or is provided to enable wired / wireless transmission and reception with the displacement detecting unit 300 and the alarm unit 400 at a remote location.

Accordingly, when the displacement detecting unit 300 detects that the insulation cover unit 200 deviates from the correct position protecting the insulator body 110 and the bracket 120, the controller 500 may easily recognize it from the outside. By the control of the alarm unit 400 may be operated.

For example, the allowable range of the inclination of the insulating cover unit 200 may be approximately + 5 ° to -5 °. In addition, the inclination angle of the insulation cover unit 200 may be determined by the controller 500 based on the magnitude of the voltage generated by the piezoelectric element 320 of the displacement sensing unit 300.

As an embodiment of the present invention, the control unit 500 is provided to control the operation of the alarm unit 400 based on the result detected by the displacement detection unit 300, but as another embodiment of the present invention If the warning signal generated by the alarm unit 400 is only a light signal, the piezoelectric element of the displacement detection unit 300 may be embedded by embedding a circuit or a chip in the displacement detection unit 300 itself without providing the control unit 500 separately. When electricity is generated at 320, it may be immediately applied to the alarm unit 400 to generate a light signal.

By such a configuration, a process of operating the insulator 100 of the overhead wire for special high voltage distribution according to the present invention will be described with reference to FIGS. 2 to 5.

First, in the state where the center of the upper surface of the bracket cover 230 of the insulation cover unit 200 meets the center of the insulator body 110 in a vertical line, no warning signal is generated from the alarm unit 400. .

Next, when the insulation cover unit 200 is separated from the fixed position due to the sagging of the processing wire L for the special high voltage distribution, etc., the bracket cover 230 of the insulation cover unit 200 is inclined so that the bracket cover ( The piezoelectric element 320 fixedly connected to the 230 is also inclined together, so that pressure is applied to the piezoelectric element 320 by any one of the plates of the sensor contact portion 121 formed of a pair of plates.

When the pressure is applied to the piezoelectric element 320, electricity is generated in the piezoelectric element 320, and the electric signal is transmitted to the control unit 500 and controlled by the control unit 500 to be converted into a warning signal by the alarm unit 400. Will be done.

Accordingly, according to the present invention, the insulation cover unit 200 can effectively shield the electromagnetic waves generated in the overhead cable for special high voltage distribution, thereby minimizing the influence of electromagnetic waves on people located in close proximity. In addition, before the insulation cover unit 200 is peeled off from the position in which the insulator body 110 and the bracket 120 are protected, the administrator can easily recognize and take necessary measures in advance.

While the invention has been described in connection with what is presently considered to be practical exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims.

110: insulator body 120: bracket
121: sensor contact 200: insulation cover unit
210: insulating layer 220: electromagnetic shielding layer
230: bracket cover 240: insulator cover
241: Van der Waals bond portion 243: Insulator binding portion
300: displacement detection unit 320: piezoelectric element
400: alarm unit 500: control unit

Claims (1)

Insulator body 110 provided with an insulating material;
A bracket 120 provided at an upper portion of the insulator body 110 to support a processing wire L for an extra-high voltage distribution seated at an upper portion of the insulator body 110;
A cable through hole 201 is formed to surround the insulator main body 110 and the bracket 120, and the processing wire L for the extra-high voltage distribution supported by the bracket 120 is formed therein. It consists of an insulating layer 210 and the electromagnetic shielding layer 220 formed on the upper and lower surfaces of the insulating layer 210, the appearance is provided in the upper bracket cover 230 surrounding the bracket 120 and the, An insulation cover unit (200) provided at a lower portion of the bracket cover (230), the insulator cover (240) surrounding the insulator body (110);
The piezoelectric element 320 provided in the bracket cover 230 to generate electricity by pressing the sensor contact portion 121 provided in the bracket 120 when the insulating cover unit 200 is inclined out of a fixed position. Displacement detection unit 300 having a;
An alarm unit 400 provided to be exposed to the outside from the upper portion of the bracket cover 230 and receiving an electrical signal generated from the displacement detecting unit 300 and converting it into a warning signal to inform the outside; And
If it is determined that the inclination of the insulation cover unit 200 is out of an allowable range based on a result detected by the displacement detecting unit 300, the alarm unit 400 may generate a warning signal from the alarm unit 400. Control unit 500 for controlling the;
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A van der Waals adhesive part 241 is provided on an inner side surface of the insulator cover 240 in which the insulation cover unit 200 is in contact with the insulator body 110.
Insulation insulator of the high-voltage power distribution overhead wire is characterized in that the lower end of the insulation cover unit 200 is formed with a fringe-shaped insulator binding portion (243) cut radially when viewed from the bottom.

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