KR101809227B1 - Connection structure of an overhead electric power line - Google Patents

Abstract

The present invention relates to a connection structure of an electric pole connection type overhead line. More specifically, the present invention relates to a connection structure of an electric pole connection type overhead line which prevents disconnection due to a wind power while sufficiently supporting a jumper line, and smoothly performs return to an original state according to rotation of an insulator body due to the wind power, thereby easily responding to a force transmitted from outside through a stable posture. The connection structure of an electric pole connection type overhead line comprises: an arm body; a case; a rotation hole; the insulator body; a fixing apparatus; a buffering apparatus; a wire; a detecting sensor; a first control unit; and a wireless transmission unit.

Description

A connection structure of an electric connection line of a pole type is shown in FIG.

[0001] The present invention relates to a connection structure for a pole-connection type transmission line in the field of distribution technology, and more particularly to a connection structure for a pole-connection type transmission line, which is capable of sufficiently supporting a jumper wire while preventing disconnection by wind power, So that it can be easily handled by a force externally transmitted through a stable posture.

Generally, a large power generated in a power plant is transmitted to each substation with high-voltage power through a power transmission line such as a transmission tower, and then transformed at various stages in a substation, and a cable is used for use in a consumer of each home or building It is a well-known fact that they are subjected to a distribution process which is supplied to each region.

At this time, the electric power supply to the general customer is supplied through the electric pole installed at regular intervals, and the connection of the working electric wires in each electric pole is connected by using the jumper wire which is laid down below the full iron.

However, such conventional wire connection has a problem that frequent breakdown of the working wire occurs due to contact with the electric pole due to wind pressure.

In order to solve such a problem, insulators for fixing jumper wires are installed on the wire rods. However, when the insulators are installed, stress can concentrate on the jumper wires fixed to the insulator because the wind force can not be absorbed sufficiently. .

As a conventional technique which partially alleviates such a problem, Korean Patent Registration No. 10-0881443 (Feb.

However, since the insulator main body is rotated forward when the insulator main body is rotated by the wind force, the conventional wire connection structure of the electric pole connection type can not smoothly guide the rotation of the insulator main body, There is a problem that smooth return to the original state due to a decrease in elastic force of the spring is not achieved.

Korea Patent Registration No. 10-0881443 (Feb. Mar., 2009) 'Chonju Connection Type Line to the Service Line Connection Structure'

SUMMARY OF THE INVENTION The present invention has been devised to solve the problems described above, and it is an object of the present invention to provide a jumper wire which is capable of preventing disconnection by wind power while sufficiently supporting a jumper wire, So as to be able to easily cope with a force transmitted from the outside through a stable posture.

The problems to be solved by the present invention are not limited to those mentioned above, and other solutions not mentioned can be clearly understood by those skilled in the art from the following description.

In order to achieve the above-mentioned object, the present invention provides a flat iron main body (F) installed on a pole (P); A fixed plate 11 provided with a mounting hole h and a spring mounting portion 13 disposed in a lower portion of the fixed plate 11 in communication with the mounting hole h, (10); (20) having a touch portion (22) protruding sideways and rotatably seated in a seating hole (h) of the case (10); An insulator body 30 of an insulating material inserted into the spring mounting portion 13 of the case 10 and fixed to the pivotal rotary member 20; A fixing mechanism 40 provided at the lower end of the insulator main body 30 exposed to the outside of the case 10 and fixed in engagement with the jumper line J; And the other end is fixed to the insulator main body 30 via the spring fixing member K so that the insulator main body 30 and the fixing mechanism 40 fixed to the insulator main body 30 are fixed to the spring mounting portion 13 of the case 10 (50) consisting of at least three springs (S) elastically supporting the insulator main body (30) in four directions so that the insulator main body (30) is positively positioned. A wire 60 which is once fixed to the case 10 and whose other end is connected to the pivotal rotary tool 20; A sensing sensor 70 installed on the fixing plate 11 of the case 10 to sense the touch portion 22 of the pivot rotary member 20 when the touch portion 22 is contacted; A first control unit 80 for receiving a signal from the detection sensor 70 and outputting a danger signal; And a wireless transmission unit (90) operatively controlled by the first control unit (80) and wirelessly outputting a danger signal from the first control unit (80) to the outside, characterized in that: The insulator body 30 further includes a guide hole 31 penetrating through the insulator main body 30 so as to smoothly return to the original state in accordance with the rotation of the insulator main body 30 by pressurization from the insulator main body 30 A guide bar 110 having both ends thereof passed through the guide hole 31 and rotatably connected to both sides of the lower portion of the fixing plate 11 in the forward and backward directions; And a pair of weight weights 120 movably coupled to both sides of the guide bar 110 about the insulator main body 30. The guide bar 110 is fixed to the insulator main body 30 are rotated in both forward and backward directions together with the insulator main body 30 while the weight weight 120 is guided so as to be rotated in both lateral directions along the longitudinal direction, The insulator main body 300 is rotated together with the insulator main body 30 when the insulator main body 300 is rotated in both the lateral direction and the front and back direction by external pressure while maintaining contact with both sides of the main body 30, The insulator main body 30 is pressed to a position before the insulator main body 30 is rotated according to the disengagement so as to smoothly return to the original state.

According to the present invention, by providing a sufficient buffering force to the insulator main body and the fixing mechanism, it is possible to prevent disconnection of the jumper wire fixed to the fixing mechanism.

Further, since the return to the original state can be smoothly performed by the rotation of the main body of the insulator by the wind force, there is an effect that the force transmitted from outside through the stable posture can be easily coped with.

The effects of the present invention are not limited to those mentioned above, and other solutions not mentioned may be clearly understood by those skilled in the art from the following description.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a front view schematically showing a connection structure of a pole connection type line according to the present invention; FIG.
FIG. 2 is a plan view schematically showing a connection structure of a pole connection type working line according to the present invention.
FIG. 3 is a cross-sectional view illustrating a fixing mechanism of a wire connecting structure according to the present invention.
FIG. 4 is a cross-sectional view illustrating a connection structure of a pole connection type line according to the present invention.
5 is a cross-sectional view taken along the line AA of Fig.
FIG. 6 is a view illustrating a connection structure of a pole connection type work line according to the present invention.
7 to 9 are operation diagrams illustrating operation of a pole connection type line connecting structure according to the present invention.
And
10 is a partial cross-sectional view showing a state in which the return induction unit is provided in FIG.

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

It is to be understood that both the foregoing general description and the following detailed description of the present invention are exemplary and explanatory and are intended to provide further explanation of the invention as claimed. And should not be construed as limited to the embodiments described herein.

Since the embodiments according to the concept of the present invention can make various changes and have various forms, specific embodiments are illustrated in the drawings and described in detail herein.

It should be understood that the embodiments according to the concept of the present invention are not limited to the particular mode of disclosure but include all modifications, equivalents and alternatives falling within the spirit and scope of the present invention.

The present invention utilizes the same as that of the later-described Japanese Patent Publication No. 0881443, and therefore all of the features of the device configuration described below can be understood as the matters described in Japanese Patent Registration No. 0881443. [

However, the present invention further includes a structure for smoothly returning to the original state according to the rotation of the main body of the insulator by wind power among the structures disclosed in the above-mentioned Japanese Patent No. 0881443, Thereby achieving a constitutional characteristic.

Therefore, the device configuration, characteristics and operation relationship described below will be referred to as the contents of the above-mentioned Japanese Patent Application No. 0881443, and the configuration related to the main features of the present invention will be described in detail at the rear end.

The electric wire connection structure according to the present invention includes a wavy iron main body F provided on a pole P, a case 10 fixed to the wrought iron main body F, An insulator body 30 having one end fixed to the pivotal revolver 20; a fixing mechanism 40 provided at the lower end of the insulator body 30 to fix the jumper wire J; A cushioning mechanism 50 for holding the insulator main body 30 in a spontaneous state, a wire 60 having one end fixed to the case 10 and the other end connected to the pivot 20, A first control unit 80 for receiving a signal from the sensor 70 and the detection sensor 70 and outputting a dangerous signal, and a second control unit 80 for wirelessly transmitting the danger signal from the first control unit 80 to the outside Unit 90 as shown in FIG.

The solid iron main body F is fixed to the electric pole P by bolts or the like in the form of a rectangular case with a space formed therein.

The case 10 is provided at the lower end of the solid iron main body F via a fastening member B. [ At this time, the fastening member B is an elongated bolt, which passes through the full iron main body F and the case 10 and is screwed to each of the full iron main body F and the case 10, 10). The inside of the case 10 is partitioned into a rotary port exposed portion 12 and a spring mounting portion 13 by a fixing plate 11 formed in a horizontal direction and a wire fixing portion 14 is provided on the upper surface of the case 10. [ do.

On the other hand, the fixing plate 11 is formed with a seating hole h penetrating the center portion in the up and down direction.

When the lower surface of the pivot rotary tool 20 is inserted into the seating hole h, the pivot rotary tool 20 and the seating hole h are positioned at the maximum face So that the fixing plate 11 can stably support the pivotal rotary shaft 20.

The pivot rotary member 20 has a hemispherical lower portion and a through hole 21 penetrating the upper portion and the lower portion of the pivot rotary member 20 so that the lower surface of the pivot rotary member 20 is seated in the seating hole h of the case 10, (12), and rotates in all directions.

At this time, the through hole 21 is provided with a fastening portion 21a screwed to the upper end of the insulator body 30, and a wire fixing portion 21b communicated with the fastening portion 21a is fastened to the fastening portion 21a .

Here, a panel-shaped touch portion 22 is provided horizontally on the upper portion of the pivot rotary member 20.

The insulator body 30 is made of an insulating material. The pivotal revolving mouth 20 is fixed to the upper end of the insulator body 30, and the securing mechanism 40 is connected to the lower end thereof. At this time, the upper and lower ends of the insulator main body 30 are screwed to the pivotal rotary member 20 and the fixing mechanism 40, respectively.

The fixing mechanism 40 has a U-shaped support member 41 having a groove g on which a jumper wire J is seated and a support member 41 And a fixing member 42 fastened to the jumper wire J fastened to the groove g of the support member 41 and fixed to the lower end of the insulator body 30. [

At this time, the jumper wire J serves to connect the working wire L from the substation and the working wire L from the customer, which is fixed to the wire rods F through the separate insulator A , And downwardly of the solid iron main body (F).

The cushioning mechanism 50 is provided on the spring mounting portion 13 of the case 10 so that the insulator main body 30 is elastically deformed in the four directions so that the insulator main body 30 and the fixing mechanism 40 fixed thereto are correctly positioned. And at least three springs (S) supporting the spring (S).

Four springs (S) are provided along the surface of the spring mounting portion (13).

One end of each spring S is fixed to the lower portion of the spring mounting portion 13 of the case 10 and the other end is connected to the lower portion of the upper end of the insulator main body 30 via the spring fixing member K, And supports the insulator main body 30 elastically in the horizontal direction.

One end of the wire 60 is fixed to the wire fixing portion 14 of the case 10 and the other end is fixed to the wire fixing portion 21b of the pivot rotating tool 20. [

At this time, the length of the wire 60 is sufficiently ensured, so that it is not disturbed by the rotation of the pivotal rotary member 20.

The detection sensor 70 is installed on the fixing plate 11 of the case 10 and senses mechanical contact with the touch portion 22 of the pivot rotary 20 and outputs a signal indicating the mechanical contact to the first control unit 80 . At this time, four detection sensors 70 are provided so as to correspond to the first springs S.

The first control unit 80 is installed in the rotary port exposed portion 12 of the case 10 and receives a signal from the detection sensor 70 to output a danger signal.

The wireless transmitting unit 90 is installed in the rotary port exposed portion 12 of the case 10 and is operated and controlled by the first control unit 80 to transmit a danger signal from the first control unit 80 to the outside .

Meanwhile, a separate control room may include a second control unit 100 that receives a danger signal from the wireless transmission unit 90 and a display device 110 that is controlled to be operated by the second control unit 100.

The second control unit 100 receives the danger signal from the wireless transmission unit 90 and controls the display device 110 to operate.

The display device 110 is controlled by the second control unit 100 to output an excessive rotation of the pivot rotary 20 to the outside.

6 to 9, an operating state of the pole connection type line connecting structure according to the present invention will be described as follows.

First, when the wind force acts on the insulator main body 30 in the state as shown in Fig. 4, the insulator main body 30 rotates along the wind direction around the pivot revolving revolver 20, as shown in Fig. At this time, the spring S in the direction in which the wind is blown is stretched and the spring S on the opposite side is contracted, so that the respective springs S interact with each other to act on the insulator body 30 and the fixing mechanism 40 Wind power is canceled.

When the pivot rotary tool 20 is used for a long period of time, the rotation of the pivot rotary tool 20 causes wear of the pivot rotary tool 20 or the seating hole h of the case 10, ) May fall.

At this time, when the insulator main body 30 falls, the insulator main body 30 is fixed by the wire 30 as shown in Fig.

9, when the insulator main body 30 is severely shaken due to strong wind, the insulator main body 30 is shaken more than the reference, and the touch portion 22 of the pivot rotating member 20 is moved to the detection sensor 70 Contact.

The first control unit 80 receives a signal indicating that the touch portion 22 of the pivot rotary 20 is in contact with the detection sensor 70. The first control unit 80 outputs a danger signal, To the outside.

Subsequently, the second control unit 100 receiving the danger signal from the wireless transmission unit 90 indicates an excessive rotation of the pivotal rotary member 20 on the display device 110.

9, when the spring S of the cushioning mechanism 50 loses elasticity due to long-term use, the spring S can not sufficiently support the insulator main body 30, And the excessive rotation of the pivot 20 is shown on the display device 110 through the above process.

As described above, the electric wire connection structure according to the present invention includes a main body 30 and a fixing mechanism 40 via a buffering mechanism 50 while rotating the insulator main body 30 and the fixing mechanism 40, So that the stress is not concentrated on the jumper line J fixed to the fixing mechanism 40. As a result,

That is, it is possible to prevent the jumper wire J from being disconnected due to the stress concentration and to safely supply electric power to each customer while preventing the jumper wire J from contacting the electric pole P as much as possible.

The insulator main body 30 does not drop by the wire 60 even if the insulator main body 30 is exposed to the risk of falling due to the use of the pivot rotary member 20 for a long period of time, The safety of passengers can be ensured.

In addition, an administrator in a separate management room can immediately check the degree of shaking of the insulator main body 30 and the defects of the spring S through the display device 110.

In the present invention, as shown in FIG. 10, the return induction part 100 (see FIG. 10) for smoothly returning to the original state by the rotation of the insulator main body 30 by the wind pressure, ) Is further implemented.

The return induction portion 100 smoothly guides the rotation of the insulator main body 30 when the insulator main body 30 is rotated by the wind force and smoothly guides the rotation of the insulator main body 30 in a restrained manner due to a decrease in elastic force of at least one spring among the plurality of springs S So that it is possible to easily cope with a force transmitted from outside through a stable posture.

For this purpose, the insulator main body 30 is formed with guide holes 31 penetrating both sides thereof. Both ends of the return guide portion 100 pass through the guide holes 31 and are rotated in the forward and backward directions on both sides of the lower portion of the fixing plate 11 The insulator main body 30 is guided along the longitudinal direction while the insulator main body 30 is connected to the insulator main body 30 and the insulator main body 30 is rotated about the guide bar 110 and the insulator main body 30, And a pair of weight weights 120 movably coupled to both sides of the guide bar 110.

The guide hole 31 preferably has a curved shape protruding downward with reference to a horizontal state, and preferably has a turning radius around the pivot 20.

The guide bar 110 has a rotation radius about the pivot 20 so that the insulator body 30 can be rotated in both directions along the longitudinal direction, And is rotated in the forward and backward directions in accordance with the forward and backward rotation of the main body 30 of the insulator.

To this end, the fixing plate 11 may be provided with a pair of fixing bars 112 on both sides of which the end portions of the guide bars 110 are rotatably coupled by the hinge shafts 111.

It is preferable that the fixing bar 112 has a hollow 113 through which the hinge shaft 111 passes at both ends and the hollow 113 extends upward and downward from the diameter of the guide bar 110.

This is to allow the guide bar 110 to move up and down by a certain length while being rotated around the pivot rotary member 20 together with the insulator main body 30.

At this time, it is preferable that the insulator main body 30 is rotated in the forward and backward directions within a range in which both end portions of the guide bar 110 can be rotated in the forward and backward directions.

The weight 120 has a predetermined weight and is movably coupled to both sides of the guide bar 110 while forming a coupling hole 121 passing through both sides.

The insulator main body 30 maintains a vertical state without being rotated when the pressurization from the outside is not applied or when the pressurization is released. The pair of the weights 120 are arranged such that the insulator main body 30 is vertical And keeps contact with both sides of the insulator main body 30 in the state of being formed.

When the insulator main body 30 is rotated in both the forward and backward directions according to the external pressure, the load of the weight 120 is transmitted to the insulator main body 30 and the spring S So that the recovery to the original state can be smoothly performed.

In addition, the weight 120 can smoothly return to the original state when the insulator main body 30 is stronger than pressurization from the outside in a state where the insulator main body 30 is rotated in the both side directions or the back and forth direction. Needless to say, at this time, the elastic force of the spring S is added, so that it can be stronger than the pressure from the outside.

That is, when the insulator main body 30 is rotated in the front-rear direction, the load of the pair of weights 120 is transferred to the insulator main body 30, Can be smoothly returned.

In addition, since the load of the pair of weights 120 is transmitted to the insulator main body 30, the insulator main body 30 can be rotated when the insulator main body 30 has a constant wind force or more, It can cope effectively with strong winds.

In the case where the insulator main body 30 is rotated in one direction, since the weights in the direction in which the insulator main body 30 is rotated are pressed and rotated in the upward direction, the return to the original state It can be smoothly performed.

Accordingly, since the pressurization from the outside can be rotated in both directions when the pressurization from the outside is equal to or higher than the predetermined wind force, the wind can maintain a stable posture against the breeze and can cope with strong wind effectively.

The return induction unit 100 may further include a pair of springs 130 coupled to the outside of both ends of the guide bar 110.

The spring 130 is contracted by the contact with the weight 120 in accordance with the upward and downward rotation of the insulator main body 30 in the direction of one side of the insulator main body 30. On the other hand, 30) is pressed downward so that return to the original state can be smoothly performed.

When the insulator main body 30 is rotated in both lateral directions, the spring 130 stops rotating before the insulator main body 30 is collided against the lower portion of the spring mounting portion 13, So that the rotation can be performed at a predetermined angle.

In addition, it is possible to easily cope with the release of the spring S and the reduction of the elastic force due to the pressure from the outside.

10: Case 20: Pivot rotary
30: insulator body 31: guide ball
40: Fixing mechanism 50: Buffering mechanism
60: wire 70: detection sensor
80: first control unit 90: wireless transmission unit
100: return induction unit 110: guide bar
111: Hinge shaft 120: Weight
121: engaging hole 130: spring

Claims (1)

A solid iron main body F provided on the electric pole P;
A fixed plate 11 provided with a mounting hole h and a spring mounting portion 13 disposed in a lower portion of the fixed plate 11 in communication with the mounting hole h, (10);
(20) having a touch portion (22) protruding sideways and rotatably seated in a seating hole (h) of the case (10);
An insulator body 30 of an insulating material inserted into the spring mounting portion 13 of the case 10 and fixed to the pivotal rotary member 20;
A fixing mechanism 40 provided at the lower end of the insulator main body 30 exposed to the outside of the case 10 and fixed in engagement with the jumper line J;
And the other end is fixed to the insulator main body 30 via the spring fixing member K so that the insulator main body 30 and the fixing mechanism 40 fixed to the insulator main body 30 are fixed to the spring mounting portion 13 of the case 10 (50) consisting of at least three springs (S) elastically supporting the insulator main body (30) in four directions so that the insulator main body (30) is positively positioned.
A wire 60 which is once fixed to the case 10 and whose other end is connected to the pivotal rotary tool 20;
A sensing sensor 70 installed on the fixing plate 11 of the case 10 to sense the touch portion 22 of the pivot rotary member 20 when the touch portion 22 is contacted;
A first control unit 80 for receiving a signal from the detection sensor 70 and outputting a danger signal; And
And a wireless transmission unit (90) operatively controlled by the first control unit (80) and wirelessly outputting a danger signal from the first control unit (80) to the outside,
Further comprising a return inducing part (100) for smooth returning to the original state in accordance with rotation of the insulator main body (30) by external pressure,
The insulator main body (30)
A guide hole 31 penetrating both sides is formed,
The return induction unit (100)
A guide bar 110 having both ends thereof passed through the guide hole 31 and rotatably connected to both lower sides of the fixed plate 11 in the forward and backward directions; And
And a pair of weight weights 120 movably coupled to both sides of the guide bar 110 about the insulator main body 30,
The guide bar (110)
The insulator main body 30 is rotated in the front-rear direction together with the insulator main body 30 while being guided so as to be rotated in both lateral directions along the longitudinal direction by external pressure,
The weight 120,
When the insulator main body 300 is rotated in the both side directions or the back and forth direction by external pressure while maintaining the state where the insulator main body 30 is in contact with both sides of the insulator main body 30 on the basis of the vertical state, (30) is rotated together with the main body (30) in a state before the rotation of the main body (30) in accordance with the releasing of pressure from the outside so as to smoothly return to the original state. .

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