KR100865763B1 - Insulation-type support insulator of the power distribution line - Google Patents

Abstract

An insulation-type support insulator of a power transmission line is provided to prevent disconnection of a jumper line by giving a sufficient buffering force to the insulator body and a fixing device. A pivot rotator(20) is rotatably received at a receiving hole of a case(10). An insulator body(30) made of an insulator material is inserted into a first spring installation unit(13) of the case and is fixed at the pivot rotator. A fixing unit is positioned at a lower part of the insulator body exposed to the outside of the case and is fixedly geared with a jumper wire. A buffering device(50) is installed at the first spring installation unit of the case and is composed of at least three spring or more to support elastically the insulator body so that the insulator body and the fixing unit fixed at the insulator body are positioned rightly. A drop preventing device(60) with a touch unit made of elastic material is composed of a drum(61) rotatably installed inside a drum installation unit of the case, a torsion spring(62) elastically supporting the drum clockwise or counterclockwise, and a wire(63) whose one side is wound around the drum and other side is fixed at the pivot rotator. A sensor(70) senses the contact with the touch unit of the drum. A first control unit(80) receives a signal from the sensor and outputs a danger signal. A wireless transmission unit(90) is controlled by the first control unit and outputs the danger signal from the first control unit to the outside by wireless.

Description

Insulation-type support insulator of the power distribution line}

The present invention relates to an insulated support insulator of a transmission line.

In general, the large power generated in the power plant is transmitted to each substation with high voltage power through transmission lines such as power transmission towers, and then the cable is used for use in each home or building through a multi-stage transformation process at the substation. It is a well known fact that the distribution process that is supplied to each region is used.

At this time, the power supply to the general customer is supplied through the poles installed at regular intervals, and the connection of the overhead wires in each pole is connected by using jumper wires stretched downwards.

The conventional overhead wire connection frequently causes breakdown of the overhead wire due to contact with the pole due to wind pressure.

Therefore, in order to solve this problem, an insulator for fixing the jumper wire was installed in the steel

However, if the insulator for fixing the jumper wire to the complete iron is installed, the wind is not absorbed sufficiently when the wind occurs, the stress is concentrated on the jumper wire fixed to the insulator, the jumper wire is disconnected.

The present invention has been invented to solve the above problems, and an object thereof is to provide an insulated support insulator of a transmission line that sufficiently supports a jumper wire and prevents disconnection by wind power.

The present invention for solving the above problems, the mounting plate having a seating hole partitioning the drum mounting portion and the first spring mounting portion, the drum mounting portion is in communication with the seating hole disposed on the top of the fixed plate, and the seating hole communicating A case fixed to the wrought iron by having a first spring installation portion disposed below the fixed plate; A pivot rotator rotatably seated in a seating hole of the case; An insulator body of an insulating material inserted into the first spring installation part of the case and fixed to the pivot rotating hole; A fixing mechanism provided at a lower end of the insulator body exposed to the outside of the case and engaged with the jumper wire; A shock absorbing mechanism provided at the first spring mounting portion of the case, the buffer mechanism comprising at least three first springs to support the insulator body in all directions so that the insulator body and the fixing mechanism fixed thereto are in position; A drum rotatably housed in the drum mounting portion of the case with an elastic touch part, a torsion spring for supporting the drum in a clockwise or counterclockwise direction, and one end wound on the drum and the other end fixed to the pivot rotating hole. An anti-drop mechanism composed of a wire; A detection sensor detecting a touch part of the drum when the touch part is in contact with the drum; A first control unit which receives a signal from the detection sensor and outputs a danger signal; A wireless transmission unit which is operated and controlled by the first control unit to wirelessly output the danger signal from the first control unit to the outside; Characterized in that it comprises a.

According to the present invention as described above, by providing a sufficient buffering force to the agile body and the fixing mechanism, there is an effect of preventing the disconnection of the jumper wire fixed to the fixing mechanism.

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

1 is a front view schematically showing an insulated support insulator of a transmission line according to the present invention, Figure 2 is a plan view schematically showing an insulated support insulator of a transmission line according to the present invention, Figure 3 is an insulation of a transmission line according to the present invention 4 is a cross-sectional view illustrating an insulating support insulator of a transmission line according to the present invention, FIG. 5 is a cross-sectional view taken along line AA of FIG. 4, and FIG. 6 is according to the present invention. As a configuration diagram for showing an insulated support insulator of a transmission line, the insulated support insulator of the power transmission line according to the present invention will be described with reference to FIGS. 1 to 6.

Insulated support insulator of the transmission line according to the present invention, the case 10 is fixed to the wrought iron (F), the pivot rotation hole 20 is installed on the case 10 in a spherical shape, and one end pivot pivot (20) Insulator body 30 of the insulating material fixed to the), the fixing mechanism 40 is provided at the lower end of the insulator body 30 to fix the jumper wire (J), and the shock absorbing mechanism for supporting the insulator body 30 in a carbure 50 and a danger signal by receiving a signal from the drop prevention mechanism 60 installed in the case 10, the detection sensor 70 installed in the drop prevention mechanism 60, and the detection sensor 70; A first control unit (80) 0 for outputting the signal and a wireless transmission unit (90) for wirelessly outputting a danger signal from the first control unit (80) 0 to the outside.

Here, the wrought iron F has a rectangular case shape having a space formed therein and is fixed to the pole P by a bolt or the like.

The case 10 is installed at the lower end of the wrought iron F via the fastening member B. At this time, the fastening member (B) is a long bolt, penetrates through the wrought iron (F) and the case 10, by screwing each of the wrought iron (F) and the case 10, thereby connecting the wrought iron (F) and the case (10) Secure to each other. Here, the inside of the case 10 is partitioned into the drum mounting portion 12 and the first spring mounting portion 13 by the fixing plate 11 formed in the horizontal direction.

On the other hand, the fixing plate 11 has a mounting hole (h) penetrated vertically in the center. At this time, the seating hole (h) is rounded toward the inside, which is the bottom surface of the pivoting hole (20) is inserted into the seating hole (h), the pivoting hole (20) and the seating hole (h) is the maximum surface This is for making the fixed plate 11 support the pivoting rotation hole 20 stably by making contact.

The pivot rotating hole 20 has a spherical shape, and has a through hole 21 penetrated up and down, the lower surface is seated in the seating hole (h) of the case 10, the upper surface to the drum mounting portion 12. It is exposed and rotates in all directions.

At this time, the through hole 21, the fastening portion 21a which is screwed with the upper end of the insulator body 30 is provided at the bottom, the wire fixing portion 21b in communication with the fastening portion 21a is fastening portion ( It is disposed above 21a).

The insulator body 30 is made of an insulating material, the pivot rotating hole 20 is screwed to the top, the fixing mechanism 40 is screwed to the bottom.

The fixing mechanism 40 has a 'c' shaped support member 41 having a groove g on which a jumper wire J is seated on the bottom surface, and a support member 41 via a separate fastening member. It is fastened to the lower end of the insulator body 30 is composed of a fixing member 42 which is fastened and tightly fixed to the jumper wire (J) seated in the groove (g) of the support member (41).

At this time, the jumper wire (J) serves to connect the overhead wire (L) from the substation and the overhead wire (L) from the consumer, which is fixed to the wrought iron (F) via a separate insulator (A), It hangs below the fully iron F.

The shock absorbing mechanism 50 is installed in the first spring mounting portion 13 of the case 10, so that the insulator body 30 and the fixing mechanism 40 fixed thereto are in place, all around the insulator body 30. It is composed of at least three or more first spring (S) to support the shot.

In the present embodiment, four first springs S are installed along the surface of the first spring installation unit 13. At this time, one end of each first spring (S) is fixed to the lower portion of the first spring installation portion 13 of the case 10, the other end is connected to the lower end of the insulator body 30, the insulator body 30 Support the ball in the horizontal direction.

The anti-drop mechanism 60 is a drum 61 rotatably installed in the drum mounting portion 12 of the case 10, and the torsion spring 62 to support the drum 61 in a clockwise or counterclockwise direction. And, one end is wound on the drum (61) and the other end is composed of a wire (63) is fixed to the pivot rotating hole (20).

At this time, the drum 61 is provided on the outer surface of the touch portion (61a) protruding to the side, is built in the drum mounting portion 12 of the case 10 via the rotation axis (T), pivot pivot 20 ) Is placed on top.

The touch unit 61a is an elastic material and is installed on one surface of the drum 61 to rotate in conjunction with the drum 61.

The torsion spring 62 has one end fixed to the drum 61 and the other end fixed to the rotation shaft T to support the drum 61 in one direction.

One end of the wire 63 is fixed to the drum 61, and the other end of the wire 63 is fixed to the wire fixing part 21b of the pivot rotating hole 20.

The detection sensor 70 is installed on the drum installation unit 12 of the case 20, and detects when the touch unit 61a of the drop prevention mechanism 60 is in contact, the first signal to indicate this It sends out to the control unit 80. At this time, four sensor 70 is installed to correspond to the spring (S).

The first control unit 80 is installed in the drum mounting unit 12 of the case 20, and receives a signal from the sensor 70 to output a danger signal.

The wireless transmission unit 90 is installed in the drum mounting portion 12 of the case 20, and is operated and controlled by the first control unit 80 to externally output a danger signal from the first control unit 80. Wireless output.

On the other hand, the separate management room may be provided with a second control unit 100 for receiving a danger signal from the wireless transmission unit 90, and a display device 110 that is operationally controlled by the second control unit 100.

The second control unit 100 receives a danger signal of the wireless transmission unit 90 to control the operation of the display apparatus 110.

The display apparatus 110 is operated and controlled by the second control unit 100 to output the falling state of the insulator body 30 to the outside.

7 to 9 is an operation showing the operation of the insulated support insulator of the transmission line according to the present invention, with reference to FIGS. 7 to 9 will be described the operating state of the insulated support insulator of the transmission line according to the present invention. same.

First, in the state as shown in FIG. 4, when the wind acts on the insulator body 30, the insulator body 30 rotates in the wind direction with respect to the pivot rotation hole 20, as shown in FIG. 7. At this time, while the first spring (S) in the wind blowing direction is tensioned and the first spring (S) on the opposite side is contracted, each of the first spring (S) interacts, the insulator body 30 and the fixing mechanism The wind acting on 40 is offset.

On the other hand, if the pivot rotor 20 is used for a long time, the wear occurs in the seating hole (h) of the pivot rotor (20) or case 10 by the rotation of the pivot rotor (20) insulator body 30 ) May fall.

At this time, when the insulator body 30 falls, the wire 61 is pulled downward as shown in FIG. 7 while the drum 61 is rotated by the wire 63 and the touch unit 61a interlocks with the drum 61. ) Contacts the sensing sensor 70.

Thereafter, the first control unit 80 that receives the signal that the touch unit 61a of the drop prevention mechanism 60 has been contacted by the detection sensor 70 outputs a danger signal, and the wireless transmission unit 90 sends a danger signal. Wireless output to the outside.

Subsequently, the second control unit 100 receiving the danger signal from the wireless transmitting unit 90 shows the falling state of the insulator body 30 on the display apparatus 110.

At this time, when the drum 61 is rotated and the wire 63 is released, the insulator body 30 is fixed to the drum 61 by the wire 63 and does not fall.

As described above, the insulated support insulator of the transmission line according to the present invention, while rotating the insulator body 30 and the fixing mechanism 40, the insulator body 30 and the fixing mechanism 40 through the buffer mechanism 50 A sufficient buffering force is provided so that the stress is not concentrated on the jumper wire J fixed to the fixing mechanism 40.

That is, while preventing the jumper wire (J) from contacting the electric pole (P) as much as possible, it is possible to prevent the disconnection of the jumper wire (J) by stress concentration, so that power is safely supplied to each customer.

In addition, even if the insulator body 30 is exposed to the danger of falling due to the long-term use of the pivoting rotating tool 20, the insulator body 30 does not fall by the anti-drop mechanism 60, so that the vicinity of the pole P Passengers passing through the can be secured, the manager in a separate management room can immediately check the fall of the insulator body 30 through the display device 110.

1 is a front view schematically showing an insulated support insulator of a transmission line according to the present invention,

2 is a plan view schematically showing an insulated support insulator of a transmission line according to the present invention;

3 is a cross-sectional view showing a fixing mechanism of the insulating support insulator of the transmission line according to the present invention,

4 is a cross-sectional view showing an insulating support insulator of a transmission line according to the present invention,

5 is a cross-sectional view taken along line A-A of FIG.

6 to 8 are views showing the operation of the insulated support insulator of the transmission line.

Explanation of terms for main parts of attached drawings

10; Case 20; Pivot rotor

30; Aza-body 40; Fixture

50; Shock absorber 60; wire

70; Detection sensor 80; First control unit

90; Wireless Transmission Unit

Claims (1)

A fixing plate 11 having a seating hole h for partitioning the drum mounting portion 12 and the first spring mounting portion 13, and a drum mounting in communication with the mounting hole h and disposed on the fixing plate 11 above. A case 10 having a first spring mounting portion 13 which is in communication with the portion 12 and the mounting hole h and is disposed below the fixing plate 11 and fixed to the wrought iron F; A pivot rotation hole 20 rotatably seated in the seating hole h of the case 10; An insulator body 30 made of an insulating material inserted into the first spring installation part 13 of the case 10 and fixed to the pivot rotation hole 20; A fixing mechanism 40 provided at a lower end of the insulator body 30 exposed to the outside of the case 10 and engaged with the jumper wire J to be fixed; At least three installed on the first spring mounting portion 13 of the case 10 to support the insulator body 30 in all directions so that the insulator body 30 and the fixing mechanism 40 fixed thereto are in place. A shock absorbing mechanism 50 composed of the first springs S; A torsion supporting the drum 61 in a clockwise or counterclockwise direction, and a drum 61 which is internally rotatably installed in the drum mounting part 12 of the case 10 with an elastic touch part 61a. A drop prevention mechanism (60) composed of a spring (62) and a wire (63), one end of which is wound on the drum (61) and the other end of which is fixed to the pivot rotating hole (20); A detection sensor 70 for detecting the touch unit 61a of the drum 61 when the touch unit 61a is in contact with the drum 61; A first control unit 80 which receives a signal from the detection sensor 70 and outputs a danger signal; A wireless transmission unit 90 which is operationally controlled by the first control unit 80 to wirelessly output the danger signal from the first control unit 80 to the outside; Insulated support insulator of a power transmission line comprising a.

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