KR101750711B1 - insulation structure for polymer insulator - Google Patents

Abstract

The present invention relates to a new structure of a polymer insulator insulation structure which can prevent a safety accident from being caused by exposing an end of a polymer insulator for connecting an end of a high-voltage cable to an electrode wire.
According to the polymer insulator insulation structure according to the present invention, after the dead end cover 6 is coupled to the outside of the dead end clamp 5, the flange portion 4b at the most rear side of the polymer insulator 4 The tip of the auxiliary insulation cover 10 covers the outside of the flange portion 4b of the polymer insulator 4 and the auxiliary insulation cover 10 10 cover the outside of the distal end portion of the dead end cover 6.
The auxiliary insulating cover 10 is fixed to the polymer insulator 4 so that the rear end of the auxiliary insulating cover 10 is connected to the connecting portion of the polymer insulator 4, The connection portion of the polymer insulator 4 is exposed to the outside, thereby preventing an electric shock or a power failure from occurring.

Description

An insulation structure for a polymer insulator

The present invention relates to a new structure of a polymer insulator insulation structure which can prevent a safety accident from being caused by exposing an end of a polymer insulator for connecting an end of a high-voltage cable to an electrode wire.

Generally, in the case of supplying electricity to each customer by using a wire line method in which a high-voltage line crosses the air, the high-voltage line is fixed to the electric pole arranged so as to be spaced apart at regular intervals so that the high-

1 and 2, the electric wire 3 is provided on the electric wire, the polymer insulator 4 is connected to the electric wire 3, and the end of the polymer insulator 4 is connected to a high- And a dead end clamp 5 for fixing the body 1.

Therefore, the end of the high-voltage line 1 is fixed to the dead-end clamp 5, and the high-voltage line 1 fixed to the dead-end clamp 5 is interconnected with the jump line 2, And are continuously connected.

At this time, the dead end clamp 5 is made of a conductive metal material, and the high voltage line 1 and the jump line 2 are electrically connected through the dead end clamp 5.

The polymer insulator 4 is provided with an insulating portion 4a made of a polymer material having a plurality of flange portions 4b formed at an intermediate portion thereof and has a connecting bar 4c made of a metallic material, The connecting bar 4c is connected to the dead end clamp 5 so that the supporting bar 4d is fixed to the wire 3 so that the end of the high wire 1 is connected to the wire 3 And at the same time, the high-voltage line 1 and the precursor 3 can be insulated from each other.

Meanwhile, in this case, since the dead end clamp 5 is exposed to the outside, an operator who performs alga or electric work contacts the dead end clamp 5 to be subjected to an electric shock accident, .

Recently, a dead end cover 6 covering the dead end clamp 5 is coupled to the outside of the dead end clamp 5 to prevent the bird or the operator from touching the dead end clamp 5 have.

The dead end cover 6 is formed in a cylindrical shape made of an insulating synthetic resin material and has a through hole 6a through which the jump line 2 passes, ) Of the dead end clamp 5 are fitted to each other and fitted to each other so as to surround the dead end clamp 5.

At this time, the connection bar 4c of the polymer insulator 4 connected to the dead end clamp 5 is made of a metallic material as a conductive material, so that power applied to the dead end clamp 5 is applied to the connection bar 4c And an electric shock or a power failure may occur even when a bird or an operator touches the connecting bar 4c.

The dead end cover 6 is made sufficiently long to cover the connecting bar 4c of the polymer insulator 4 connected to the dead end clamp 5 so that when the dead end cover 6 is coupled, The connection bar 4c of the polymer insulator 4 can be prevented from touching the connecting bar 4c of the polymer insulator 4. This prevents the bird or the operator from contacting the connecting bar 4c of the polymer insulator 4. [

The structure of such a dead end cover 6 is described in detail in a number of prior documents, including the registration practice model 20-0236127 and the registration practice model 20-0442863, and a detailed description thereof will be omitted.

However, since the dead end cover 6 is displaced from the fixed position and the connecting bar 4c of the polymer insulator 4 is exposed to the outside, .

Thus, conventionally, after the dead end cover 6 is coupled, the end of the polymer insulator 4 and the dead end cover 6 is wrapped with an insulating tape so that the dead end cover 6 is fixed so as not to move. However, It is not possible to completely fix the dead end cover 6 so that the dead end cover 6 does not move and it is very troublesome to wind the insulation tape around the polymer insulator 4 and the dead end cover 6. [

Therefore, there is a need for a new method to solve such a problem.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems and it is an object of the present invention to provide a method for preventing a safety accident by exposing an end portion of a polymer insulator 4 for connecting an end portion of a high- And it is an object of the present invention to provide a polymer insulator insulation structure of a new structure.

The polymer insulator is connected to the end of the polymer insulator and is connected to the high voltage line. In order to achieve the above object, according to the present invention, And a dead end cover (6) coupled to the outside of the dead end clamp (5), wherein the polymer insulator (4) has a plurality of flange portions And a supporting bar 4d provided at both ends of the insulation part 4a and the connection part 4c and the supporting bar 4d, Further comprising a secondary insulation cover (10) of a synthetic resin material coupled to the outside of the connection part of the dead end cover (6), wherein the secondary insulation cover (10) do

According to another aspect of the present invention, the auxiliary insulating cover 10 is extended in the front-rear direction, and a coupling hole 11 is formed in the front surface of the auxiliary insulating cover 10 so that the insulating portion 4a penetrates therethrough, 6 is formed in a cylindrical shape having an opening 12 into which a front end portion of the polymer insulator 6 is inserted.

According to still another aspect of the present invention, an insertion groove (14) is formed in the inner peripheral surface of the front end of the auxiliary insulation cover (10) for inserting and fixing the peripheral portion of the flange portion (4b) of the polymer insulator A polymer insulator isolation structure is provided.

According to another aspect of the present invention, a plurality of cushion ribs 18 extending inward from an inner circumferential portion of the auxiliary insulating cover 10 and having an inner end closely contacting the front end peripheral surface of the dead end cover 6, So that the dead end cover 6 and the auxiliary insulating cover 10 can be prevented from colliding with each other and being damaged when the dead end cover 6 or the auxiliary insulating cover 10 flows A polymeric insulator structure is provided.

According to another aspect of the present invention, the dead end cover 6 is disposed inside the dead end cover 6 so as to be positioned at the periphery of the high-voltage line 1 fixed to the dead-end clamp 5, A wind power generator 30 provided on an outer surface of the dead end cover 6 and operated by wind to generate electricity, a wind power generator 30 for storing electricity of the wind power generator 30, A control unit 50 that is operated by using electricity stored in the rechargeable battery 40 as a power source; a wireless output unit 60 connected to the control unit 50; And a terminal (70) carried by an operator who maintains the high-voltage line (1) and the like, the control means (50) receiving the signal of the current measuring means (20) When the high voltage line (1) is in a live wire state where power is applied, The wireless terminal 60 outputs a warning signal to the terminal 70 so that the renewal call is transmitted to the terminal 70 via the wireless output means 60. When the warning signal output from the wireless output means 60 is received And outputting an alarm indicating that power is applied to the high-voltage line (1).

According to the polymer insulator insulation structure according to the present invention, after the dead end cover 6 is coupled to the outside of the dead end clamp 5, the flange portion 4b at the most rear side of the polymer insulator 4 The tip of the auxiliary insulation cover 10 covers the outside of the flange portion 4b of the polymer insulator 4 and the auxiliary insulation cover 10 10 cover the outside of the distal end portion of the dead end cover 6.

The auxiliary insulating cover 10 is fixed to the polymer insulator 4 so that the rear end of the auxiliary insulating cover 10 is connected to the connecting portion of the polymer insulator 4, The connection portion of the polymer insulator 4 is exposed to the outside, thereby preventing an electric shock or a power failure from occurring.

1 is a cross-sectional side view showing a conventional polymer insulator insulation structure,
2 is a front sectional view showing a conventional polymer insulator insulation structure,
3 is a side sectional view showing a polymer insulator insulation structure according to the present invention,
4 is an exploded perspective view showing a supplementary insulation cover according to a polymer insulator insulation structure according to the present invention,
FIG. 5 is a side view showing a secondary insulation cover according to the polymer insulator insulation structure according to the present invention,
FIG. 6 is a rear view showing an auxiliary insulation cover according to the polymer insulator insulation structure according to the present invention. FIG.
7 is a side sectional view showing a second embodiment of the polymer insulator insulation structure according to the present invention,
FIG. 8 is a side cross-sectional view showing the auxiliary insulation cover according to the second embodiment of the polymer insulator insulation structure according to the present invention,
9 is a rear cross-sectional view illustrating a cushioning rib of an auxiliary insulation cover according to a second embodiment of the polymer insulator insulation structure according to the present invention,
10 is a side sectional view showing a third embodiment of the polymer insulator insulation structure according to the present invention,
11 is a rear cross-sectional view showing a third embodiment of the polymer insulator insulation structure according to the present invention,
12 is a circuit diagram showing a third embodiment of the polymer insulator insulation structure according to the present invention.

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

3 to 6 illustrate a polymer insulator insulation structure according to the present invention. The polymer insulator insulation structure of the present invention comprises a wire 3 provided in a telephone pole, a polymer insulator 4 connected to the wire 3, A dead end clamp 5 connected to the high-voltage line 1 and capable of fixing the high-voltage line 1, and a dead-end cover 6 coupled to the outside of the dead-end clamp 5 are provided.

The polymer insulator 4 has an insulating portion 4a having a plurality of flange portions 4b formed at an intermediate portion thereof and a connecting bar 4c and supporting bars 4d provided at both ends of the insulating portion 4a, .

The connection bar 4c and the support bar 4d are made of a metal material having high strength.

The dead end cover 6 is formed in a cylindrical shape made of an insulating synthetic resin material and has a through hole 6a through which the jump line 2 passes, (6) are fitted to each other on both sides of the dead end clamp (5) to be assembled so as to surround the outside of the dead end clamp (5).

According to the present invention, an auxiliary insulating cover 10 made of a synthetic resin is coupled to the outside of the connection portion between the polymer insulator 4 and the dead end cover 6 so that even if the dead end cover 6 moves, 4) is not exposed to the outside.

As shown in FIGS. 4 to 6, the auxiliary insulation cover 10 is formed in a cylindrical shape extending in the front-rear direction, and the front surface of the auxiliary insulation cover 10 is covered with a coupling hole And a rear end of the dead end cover 6 is formed with an opening 12 into which a front end portion of the dead end cover 6 is inserted and is divided into two sides and fixed ribs 13 are provided at upper and lower ends, And the auxiliary insulating cover 10 can be assembled using the insulating cover 13.

An insertion groove 14 is formed in the inner circumferential surface of the front end of the auxiliary insulation cover 10 so that the peripheral portion of the flange portion 4b is inserted and fixed.

The auxiliary insulating cover 10 is provided with a projecting piece 15 protruding inward from the inner circumferential surface of the front end of the auxiliary insulating cover 10, 15)

The front end of the auxiliary insulation cover 10 is constituted by a small diameter portion 16 whose diameter is slightly larger than the diameter of the flange portion 4b of the polymer insulator 4 and the rear end portion of the auxiliary insulation cover 10 Diameter portion 17 is larger than the front end portion of the dead end cover 6. The opening portion 12 is formed to be sufficiently large at the rear end portion of the large diameter portion 17, So that the front end portion of the dead end cover 6 can be sufficiently inserted into the auxiliary insulating cover 10. [

On the other hand, the auxiliary insulation cover 10 is integrally formed by injection molding synthetic resin having appropriate elasticity and strength.

3, the dead end cover 6 is coupled to the outer side of the dead end clamp 5, and the dead end cover 6 is disposed at the rear of the polymer insulator 4 When the auxiliary insulating cover 10 is coupled to the flange portion 4b such that the insertion groove 14 is engaged with the flange portion 4b of the flange 4b of the flange portion 4b of the polymer insulator 4, And the rear end portion of the auxiliary insulation cover 10 covers and covers the outer side of the front end portion of the dead end cover 6.

The auxiliary insulating cover 10 is fixed to the polymer insulator 4 so that the rear end of the auxiliary insulating cover 10 is connected to the connecting portion of the polymer insulator 4, The connection portion of the polymer insulator 4 is exposed to the outside, thereby preventing an electric shock or a power failure from occurring.

Particularly, the inner surface of the front end of the auxiliary insulation cover 10 is formed with an insertion groove 14 into which the flange portion 4b of the polymer insulator 4 is inserted and fixed, The auxiliary insulating cover 10 is fixed to the polymer insulator 4 by inserting the auxiliary insulating cover 10 such that the insulating cover 4b is inserted.

Therefore, even if the dead end cover 6 flows, the auxiliary insulation cover 10 is fixed to the polymer insulator 4 and can be fixed so as not to move and effectively prevent the connection portion of the polymer insulator 4 from being exposed to the outside There is an advantage.

That is, the auxiliary insulating cover 10 may be configured to be fixed to the dead end cover 6. In this case, when the dead end cover 6 flows, the auxiliary insulating cover 10 also flows, Can not be effectively shielded.

However, in the case of the present invention, the auxiliary insulator cover 10 is firmly fixed to the polymer insulator 4 using the insertion groove 14 so as to cover the outside of the connection of the polymer insulator 4, It is possible to more effectively prevent the connection portion of the battery pack 20 from being exposed to the outside.

7 to 9 illustrate a second embodiment according to the present invention in which the inner peripheral portion of the auxiliary insulation cover 10 extends inward and has an inner end which is in contact with the peripheral edge of the front end portion of the dead end cover 6 A plurality of buffer ribs 18 are provided.

The buffer ribs 18 are integrally formed when the auxiliary insulation cover 10 is manufactured and are formed to be thinner than other portions of the auxiliary insulation cover 10 so that the buffer ribs 18 can be bent become.

At this time, a plurality of the buffer ribs 18 are formed on the inner circumferential surface of the auxiliary insulation cover 10 so as to be spaced apart from each other by a predetermined angle.

7, when the auxiliary insulating cover 10 is coupled after the dead end cover 6 is coupled, the inner end of the cushioning rib 18 is engaged with the front end of the dead end cover 6 So that the rear end of the auxiliary insulation cover 10 is appropriately spaced from the periphery of the front end of the dead end cover 6. [

According to the thus constituted polymer insulator insulating structure, the rear end of the auxiliary insulation cover 10 is appropriately spaced from the periphery of the front end of the dead end cover 6 by the buffer ribs 18, It is possible to prevent the dead end cover 6 and the auxiliary insulating cover 10 from colliding with each other and being damaged when the dead end cover 6 or the auxiliary insulating cover 10 flows.

That is, the dead end cover 6 is manufactured to have different sizes of tip portions according to manufacturers or specifications, so that the opening portion 12 of the auxiliary insulating cover 10 is inserted into the dead end cover 6 of various sizes Should be large enough to be inserted.

In this case, a gap is formed between the opening 12 and the tip end of the dead end cover 6, so that when the dead end cover 6 or the auxiliary insulation cover 10 is caused to flow by wind or the like, The cover 6 and the auxiliary insulation cover 10 may collide with each other and be damaged or the dead end cover 6 or the auxiliary insulation cover 10 may be disassembled on both sides.

However, in the case of the present invention, since the rear end portion of the auxiliary insulating cover 10 is supported by the buffer ribs 18, the dead end cover 6 and the auxiliary insulating cover 10 are prevented from colliding with each other, There is an advantage that it can be prevented.

10 to 12 illustrate a third embodiment according to the present invention in which the dead end cover 6 is provided so as to be located at the periphery of the high voltage line 1 fixed to the dead end clamp 5 A wind power generator 30 provided on the outer surface of the dead end cover 6 and operated by the wind to generate electricity; A battery 40 for storing electricity of the wind power generator 30; a control unit 50 operated by using electric power stored in the rechargeable battery 40 as a power source; And a terminal 70 which is configured to be capable of communicating data with the radio output means 60 and carried by an operator who maintains the high-voltage line 1 and the like.

The current measuring means 20 uses a Rogowski coil disposed inside the dead end cover 6 so as to surround the periphery of the high voltage line 1 fixed to the dead end clamp 5.

The Rogowski coil is constituted by winding a coil composed of a conductive wire material so as to have a circular shape. The Rogowski coil is disposed so as to surround the circumference of the high-voltage line 1 to which power is applied, so that the electric current applied to the high- When the lower end of the dead end coil is opened, the lower end of the dead end coil is properly deformed. In this state, when the dead end coil is coupled to the outside of the dead end clamp 5, Is arranged so as to surround the periphery of the high-voltage line (1) coupled to the high-voltage line (5), so that the current applied to the high-voltage line (1) can be measured.

The current measuring means 20 using the Rogowski coil or the Rogowski coil is generally used as shown in a number of prior documents including the patent 10-0965818, and a detailed description thereof will be omitted .

Since the wind turbine generator 30 and the rechargeable battery 40 are general ones, detailed description is omitted.

The control means 50 receives a signal of the current measuring means 20 and outputs a warning signal to the radio output means 60 when the high voltage line 1 is in the live state, And is transmitted to the terminal (70) through the wireless output means (60).

That is, the control means 50 does not output a warning signal when the high-voltage line 1 receives a signal of the current means and is in a diagonal state in which power is not applied to the high-voltage line 1, In the active state, the control means (50) outputs a warning signal indicating the danger through the radio output means (60).

The radio output means 60 is configured to be capable of data communication with the terminal 70 and transmits the received warning signal to the terminal 70 via radio when the control means 50 receives the warning signal .

At this time, the wireless output means 60 can be configured to be capable of data communication with the terminal 70 through a local area communication method such as wifi.

The terminal 70 is configured to output an alarm indicating that the power is applied to the high voltage line 1 when the warning signal is output.

Preferably, the terminal 70 uses a general smart phone equipped with a dedicated application 71 capable of outputting an alarm, and a warning signal output from the wireless output means 60 is received by the terminal 70 The application 71 is configured to output an alarm indicating that power is being applied to the high voltage line 1 by voice to warn an operator who maintains the high voltage line 1. [

At this time, a power switch for turning on / off the control unit is provided at one side of the dead end case, and the control unit is turned on by operating the power switch only when the operator maintains the high voltage line 1, And is configured to prevent unnecessary consumption of stored electricity.

According to the polymer insulator insulation structure constructed as described above, when power is supplied to the high-voltage line 1 due to a power failure and a worker maintains the high-voltage line 1 during maintenance, An alarm is output to indicate that the power is applied to the high voltage line 1. [

Therefore, there is an advantage that an operator can be effectively prevented from accidentally causing an electric shock by touching the power cable 1 or the dead-end clamp 5 inadvertently applied with power.

3. Bonding 4. Polymer Insulator
5. Dead end clamp 6. Dead end cover
10. Auxiliary insulation cover

Claims (5)

(3) provided in a telephone pole,
A polymer insulator 4 having a connecting bar 4c and a supporting bar 4d made of a metallic material and having high strength are provided at both ends of an insulating portion 4a in which a plurality of flange portions 4b are formed at an intermediate portion, Wow,
A dead end clamp 5 having one end connected to the connecting bar 4c of the polymer insulator 4 and the other end with a high voltage line 1,
A dead end cover 6 coupled to cover the outside of the dead end clamp 5,
And an auxiliary insulating cover (10) of a synthetic resin material provided to cover the outside of the connection part between the polymer insulator (4) and the dead end cover (6)
The auxiliary insulation cover (10)
The end of the insulation part 4a of the polymer insulator 4 penetrates through the coupling hole 11 and the front end of the dead end cover 6 through the opening 12 of the other end And a protruding piece 15 protruding inward from the inner circumferential surface of the engaging hole 11 side so as to be assembled by the fixed rib 13 while being dividedly manufactured on both sides, The flange portion 4b formed at the rear most end of the polymer insulator 4 is inserted and fixed in the inner peripheral portion of the opening 12 where the dead end cover 6 is inserted, So that a plurality of buffer ribs (18) are formed so as to be in close contact with the circumferential surface of the dead end cover (6).
delete delete delete The method according to claim 1,
A current measuring means 20 disposed inside the dead end cover 6 and measuring a current applied to the high voltage line 1 at a periphery of the high voltage line 1 fixed to the dead end clamp 5, and,
A wind power generator 30 provided on an outer surface of the dead end cover 6 and operated by wind to generate electricity,
A rechargeable battery 40 for storing electricity of the wind power generator 30,
A control means (50) operated by using electricity stored in the rechargeable battery (40) as a power source,
A radio output means (60) connected to said control means (50)
And a terminal (70) configured to be capable of data communication with the radio output means (60) and carried by an operator who maintains the high voltage line (1)
The control means 50 receives a signal of the current measurement means 20 and outputs a warning signal to the radio output means 60 when the high voltage line 1 is in a live wire state, To be transmitted to the terminal (70) through the output means (60)
Wherein the terminal (70) is capable of outputting an alarm indicating that power is applied to the high voltage line (1) when the warning signal outputted from the wireless output means (60) is received.

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