KR101794303B1 - Insulator Fixing Type Frame for Adjusting Tension of Distribution Line - Google Patents

Abstract

An insulator fixing-type crossarm for adjusting the tension of an overhead distribution line attenuates the tension by elasticity even if a transmission line is strongly shaken in an environment like bad weather by stably supporting a jumper line, thereby preventing the transmission line, an insulator, and the crossarm from being cut or broken. If the transmission line is fractured, the transmission line is fixed to prevent the transmission line from falling down on the ground or surrounding trees, thereby improving the safety of the transmission line, the insulator, and the crossarm configured to prevent a negligent accident and an electric shock accident due to an electric leakage.

Description

Insulator Fixing Type Frame for Adjustment Tension of Distribution Line for Adjusting the Tension of Machined Distribution Line

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an insulator fixing rigid body for adjusting the tension of a processing power distribution line in the field of power distribution technology. More particularly, the present invention relates to an insulator fixed rigid structure for stably supporting a jumper wire, If the transmission line is broken without break or breakage of the insulator and brass wire, the transmission line should be fixed so as not to fall on the ground or surrounding trees to prevent electric shock and safety accidents due to electric leakage. The present invention relates to an insulator fixed barrel for adjusting the tension of a processing distribution line.

The processing transmission line is a power facility for supplying power generated by a power plant to each region through a substation for power supply.

Transmission lines are supported by transmission towers, etc., and transmission towers are installed at regular intervals between the power plant and the substation so as to stably support the transmission lines.

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 power 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 And the distribution process to supply to each region.

Electricity produced or developed in the power plant is supplied to general consumers or factories such as end users through the transmission line and the transmission line through the process of boosting.

Since electric power that can give a danger is flowing in the power transmission line, it is generally made to be separated from the ground so as to be located at a relatively high position by fixing it to the insulator provided in the bare iron provided at the upper end of the pole.

The transmission line is installed in a high position and is managed relatively safely, but can be directly impacted on the transmission line due to carelessness when working with crane, excavator, ladder, etc.

When the above-mentioned strong impact is applied to the transmission line, the transmission line is disconnected from the insulation insulator and the transmission line, and the transmission line is broken, An accident may occur.

In addition, this problem may occur because the coupling between the insulator and the solid iron is released.

As a conventional technique for partially alleviating the impact applied to the insulator as described above, a number of such insulators have been disclosed as well, including an insulated-type insulator for a distribution cable, Korean Patent Registration No. 10-0873746 (December 12, 2008).

If there is a problem that the transmission line breaks in case of bad weather, if there is no structure that can catch the transmission line, if the broken transmission line falls down to surrounding trees, ground, water etc., There is no way to solve the problem.

Korean Registered Patent No. 10-0873746 (Registered on Dec. 05, 2008), entitled "Insulated Suspension for Distribution Line"

In order to solve the problems and necessities of the related art, the present invention has been made to solve the problems and necessity of the prior art, and it is an object of the present invention to provide a jumper wire which stably supports a jumper wire, In the case of breakage of the transmission line without breakage, the transmission line shall be fixed so as not to fall to the ground or surrounding trees, to prevent electric shock accidents and accidents caused by electric leakage, and to improve the safety of the transmission line, The object of the present invention is to provide an insulator fixed bar for tension control.

In order to achieve the above object, the present invention provides an insulator fixing rigid iron for adjusting tension of a processing distribution line,

A bobbin 10 fixed to the electric pole 10 and an insulator 20 fixed to the bobbin 11 and 12 and connecting the transmission line 22 in an insulated state. ,

The brass bar 12 has a columnar vertical column portion 101 vertically erected on the side wall and a razor-shaped fish portion 102 formed on the entire surface of the vertical column portion 101, A driving motor 105 coupled to the pinion gear portion 104 to provide a driving force to the pinion gear portion 104 and a driving motor 105 coupled to the pinion gear portion 104, And a locating member (100) comprising a pinion gear portion (104) and a movable housing (103) having a predetermined internal space portion for containing the drive motor (105)

The movable housing 103 is coupled to a plate 106 having a predetermined width and thickness on one side,

The transmission line 22 having passed through the insulator 20 has a hydraulic cylinder part 320 passing through the wire bracket 310 and coupled to the lower surface of the wire bracket 310, And a tension adjusting part 300 having a hydraulic cylinder part 320 composed of a connecting part 321 and a stopper 311 coupled to one end of the connecting part 321,

The tension regulator 300 is coupled to the upper portion of the plate 106 and the hydraulic cylinder 320 includes a cylindrical cylinder 323 having a chamber chamber 324 filled with working fluid,

The cylinder 323 includes a longitudinal connecting member 321, a cylindrical piston 322 coupled to the connecting member 321 and slidably inserted by the connecting member 321, The piston increase preventing portion 325 is disposed at a predetermined distance from the piston 322 and an elevating member 326 is installed on a surface of the piston increase preventing portion 325. The elevating member 326 has a predetermined depth A part of the lifting push spring 327 is inserted into the groove and the remaining portion of the lifting push spring 327 extends to the bottom surface of the cylinder 323,

When the pinion gear portion 104 is rotated by driving the driving motor 105, the moving housing 103 moves up and down along the rack size portion 102, Moved,

The transmission line 22 is connected to a tension adjusting unit 300 that connects the hydraulic cylinder 320 to the lower surface of the wire bracket 310 so that the transmission line 22 is not broken even if the transmission line 22 is strongly shaken by an external force. And the tension of the transmission line 22 is buffered.

According to the present invention having the above-described structure, even if the working transmission line is broken due to bad weather, it is prevented from touching the ground, water, or a tree branch, thereby preventing electric shock and safety accidents due to electric leakage.

The present invention is advantageous in that the transmission line is rigidly supported by a force that firmly supports and supports the transmission line while being pressed with frictional force, and the transmission line is fixed in a bent form so that the pressing space of the transmission line is pressed differently, have.

The present invention has the effect that the tension is attenuated by the elasticity even when the distribution line is vigorously shaken in an environment such as a bad weather, so that the transmission line, the wire and the insulator are not broken or broken.

1 is a perspective view showing the construction of an insulator fixed rigid body for adjusting the tension of a machined distribution line according to an embodiment of the present invention.
Fig. 2 is a side view showing the construction of an insulator fixed bar for adjusting the tension of a processing distribution line according to an embodiment of the present invention.
3 is a view showing a configuration of a hydraulic cylinder according to an embodiment of the present invention.
4 is a perspective view showing a configuration of a shock absorber according to an embodiment of the present invention
5 is a cross-sectional view illustrating the configuration of an elastic member according to an embodiment of the present invention.
And
6 is a cross-sectional view illustrating a gripping member according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise.

In the case of a conventional bad weather, if there is a problem that the transmission line breaks, there is no structure that can hold the transmission line. If the broken transmission line falls down to the surrounding trees, ground, water, etc., There is always a risk of breakage or breakage of the transmission line if the distribution line is shaken by strong winds or other environmental factors.

The present invention provides a jumper wire which stably supports a jumper wire so as to attenuate a tensile force by elasticity even when a distribution line is vigorously shaken in an environment such as a bad weather and breaks or breaks the transmission line, The present invention provides an insulator fixed bridge for adjusting the tension of a power distribution line, which is improved in safety of transmission lines, insulators, and brass wires, which is configured to prevent electric shock and safety accidents caused by electric leakage by fixing the bridge to the ground or surrounding trees.

FIG. 1 is a perspective view showing the construction of an insulator fixing rigid iron for adjusting the tension of a machined distribution line according to an embodiment of the present invention, FIG. 2 is a perspective view showing a configuration of an insulator fixed rigid iron for adjusting tension of a machining distribution line according to an embodiment of the present invention Fig.

The insulator fixing rigid iron for adjusting the tension of the processing power distribution line according to the embodiment of the present invention is characterized in that it has a pole 10, The position shifter 100, the shock absorber 200, the tension adjuster 300, and the gripping member 400, which bind the upper body 22 in an insulated state.

The insulator 20 is fixed to the brass bars 11 and 12 fixed to the electric pole 10.

The solid iron (12) forms a columnar vertical columnar section (101) vertically erected on the side wall.
The position shifter 100 includes a pinion gear portion 104 formed on the front surface of the vertical pillar portion 101 and coupled to the pillar gear portion 102 so as to be engaged with the pillar gear portion 102, A driving motor 105 coupled to the pinion gear portion 104 to provide a driving force to the pinion gear portion 104 and a driving motor 105 coupled to a portion of the vertical column portion 101 and the pinion gear portion 104, And a movable housing 103 having a hexahedron shape in which a predetermined internal space portion is formed to be included in the inside.

When the pinion gear portion 104 is rotated by driving the driving motor 105, the movable housing 103 is moved up and down along the rack size portion 102.

The movable housing 103 is coupled to a plate 106 having a predetermined width and thickness on one side. Therefore, the plate 106 moves together with the up and down movement of the movable housing 103.
The position shifting member 100 moves the plate 106 up and down in accordance with the upward and downward movement of the movable housing 103 to move the shock absorbing device 200, the tension adjusting portion 300, and the gripping member 400 up and down And adjusts the tension of the transmission line 22 by adjusting the tension.

A grasping member (400) for preventing the ground wire from dropping even if the transmission line (22) is broken is joined to one surface of the solid wire (12).

The power transmission line 22 having passed through the grip member 400 and the insulator 20 is provided with a hydraulic cylinder part 320 on the lower surface of the electric wire bracket 310 so as not to be broken even if the transmission line 22 is strongly shaken due to external force, So that the tension of the transmission line 22 is buffered.

The tension adjusting unit 300 is formed on one surface of the brass ball 12 for the sake of convenience of illustration but is not limited thereto and may be provided on one surface of the brass ball 11. [

The tension adjusting portion 300 is installed on the upper surface of the plate 106 coupled in the horizontal direction from the side surface of the wrought iron 12.

The transmission line 22 is in contact with the shock absorber 200 through the wire bracket 310.

The tension adjusting unit 300 according to the embodiment of the present invention includes a hydraulic cylinder 320 including a cylinder 323 and a connecting member 321 and a stopper 311 coupled to one end of the connecting member 321, And a wire bracket 310 formed on the upper surface of the cylinder 323.

Hereinafter, the configuration of the hydraulic cylinder 320 will be described in detail with reference to FIG.

3 is a view showing a configuration of a hydraulic cylinder according to an embodiment of the present invention.

The hydraulic cylinder portion 320 of the embodiment of the present invention includes a cylindrical cylinder 323 having a chamber chamber 324 filled with a working fluid.

The cylinder 323 has a longitudinal connecting member 321 and a cylindrical piston 322 coupled to the connecting member 321 and slidably inserted by the connecting member 321. The piston 322 And a piston increase prevention portion 325 disposed at a predetermined distance from the piston 322. [

A first gasket 329a and a second gasket 329b are formed between the outer circumferential surface of the cylindrical piston 322 and the inner circumferential surface of the cylinder 323.

The piston 322 has a first space portion 324a between the outer circumferential surface of the piston 322 and the inner circumferential surface of the cylinder 323 so as to be in fluid communication with the second space portion 324b inside the cylinder 323 The first fluid path 322a and the second fluid path 322b are formed.

The piston increase preventing portion 325 is spaced from the piston 322 by a predetermined distance and is slidable in the chamber 324 when the hydraulic pressure in the chamber chamber 324 is raised to a predetermined value or more, And a stopper groove 325a through which the working fluid is discharged.

An elevating member 326 is provided on one surface of the piston increase preventing portion 325 and a part of the elevating push spring 327 is inserted into a groove having a predetermined depth formed in the elevating member 326 in the cylinder 323 The remaining portion of the lifting push spring 327 extends to the bottom surface of the cylinder 323.

The lifting push spring 327 is provided as a coil spring type which can be wound in the sliding direction of the lifting member 326 and elastically deformed.

The pushing spring 327 for lifting and lowering can apply a repulsive force to push up the lifting member 326 upward.

When the elevating member 326 is pushed upward, the piston increase preventing portion 325 coupled to the elevating member 326 rises upward.

The stopper elastic member 325b is a return spring for elastically supporting the stopper 325a toward the cylinder 323. [

The piston 322 slides toward the chamber 324 of the cylinder 323 and the oil pressure in the chamber 324 of the cylinder 323 rises. Accordingly, the raised hydraulic pressure in the chamber 324 of the cylinder 323 acts on the piston increase preventing portion 325. [

Then, the piston increase preventing portion 325 overcomes the elastic force of the stopper elastic member 325b by the oil pressure and is slid toward the piston 322. [

The piston increase preventing portion 325 is moved toward the elevating member 326 by the hydraulic pressure in the chamber 324 of the cylinder 323 and the elevating member 326 is moved to the piston increase preventing portion 325, As shown in Fig.

The transmission line 22 extends in the left and right direction of the hydraulic cylinder 320 coupled to the wire bracket 310 according to the movement of the wire bracket 310 by an external force and reduces the impact to minimize damage.

Hereinafter, the configuration of the shock absorber 200 of the present invention will be described in detail with reference to FIG.

4 is a perspective view showing a configuration of a shock absorber according to an embodiment of the present invention.

The shock absorber 200 according to the embodiment of the present invention includes the first fixing table 201 and the second fixing table 202 spaced apart from each other by a predetermined distance and the first fixing table 201 and the second fixing table 202 And the ball screw 203 is coupled to the ball screw 203 in the horizontal direction at a midpoint between the first fixing table 201 and the second fixing table 202. [ (204). One end of the ball screw 203 passes through the first fixing table 201 and the second fixing table 202 and is coupled to the driving motor 206.

The ball screw 203 is coupled to a nut block portion 204 having a thread engaging with an outer circumferential screw thread.

A guide bar 205 is provided between the first fixing table 201 and the second fixing table 202 so as to extend through the nut block 204 in a direction parallel to the ball screw 203.

When the ball screw 203 is rotated by the drive motor 206, the nut block 204 moves in the horizontal direction along the ball screw 203.

An elastic member 210 is formed on the upper surface of the nut block 204 to adjust the tension level by tilting the transmission line 22 in the up and down direction according to the tension of the transmission line 22.

On the upper surface of the elastic member 210, a pair of roller supports 217 spaced from each other by a predetermined distance are erected vertically, and a roller 218 is coupled between the roller supports 217. The transmission line 22 is seated on the roller 218.

The transmission line 22 adjusts the minute tension by moving in the lateral direction of the nut block 204 and moving the elastic member 210 in the vertical direction.

Hereinafter, the configuration of the elastic member 210 of the present invention will be described in detail with reference to FIG.

5 is a cross-sectional view illustrating the configuration of an elastic member according to an embodiment of the present invention.

The elastic member 210 according to the embodiment of the present invention includes a first fixing support 211 coupled to a lower end of a roller support 217 and a second fixing support 211 which is spaced apart from the first fixing support 211 by a predetermined distance The second fixing support 212 and the second fixing support 212. When the first fixing support 211 and the second fixing support 212 are pressed together,

A first spring coupling base 211a is formed on one surface of the first fixed support base 211 and a second spring coupling base 212a is formed on one surface of the second fixed support base 212. [ And a coil spring 214 having the first spring coupling band 211a coupled to one side and the second spring coupling band 212a coupled to the other side.

A roller support 217 is formed on an upper portion of the elastic member 210 and a roller 218 on which the transmission line 22 is mounted is coupled to the roller support 217.

Hereinafter, the configuration of the holding member 400 will be described in detail with reference to FIG.

6 is a cross-sectional view illustrating a gripping member according to an embodiment of the present invention.

The gripping member 400 according to the embodiment of the present invention includes a case 401 forming a space into which the transmission line 22 is inserted and a case 401 extending downward from the inner side upper surface at the inner left end of the case 401 A first inner lower support portion 403 extending upward from the lower surface of the inner side, and a second inner lower support portion 403 extending downward from the inner side upper surface at the inner right side end of the case 401 A second inner upper support portion 430, and a second inner lower support portion 431 extending upward from the inner surface lower surface.

A first upper pushing support part 410 formed at an inner side of the case 401 and spaced apart from the first inner upper support part 402 by a predetermined distance and extending downward from an upper surface of the inner side surface, And a first lower pushing supporting portion 411 extending upward from the lower pushing supporting portion 411. The first upper pressing support part 410 is formed to be shorter than the first lower pressing support part 411.

A second upper pressing support portion 420 formed at an inner side of the case 401 at a predetermined distance from the second inner upper supporting portion 430 in the left direction and extending downward from the upper surface of the inner side surface, And a second lower pushing support portion 421 extending upward from the lower pushing support portion 421. The second upper pressing support portion 420 is formed to be shorter than the second lower pressing support portion 421.

A first upper spring support 404 is coupled to the inner side of the case 401 between the first inner upper support portion 402 and the first upper push support portion 410, A coil spring 405 is coupled to one side of the spring support 404 and a first lower spring support 406a is coupled to the coil spring 405. A roller 406 are coupled.

The roller 406 presses the transmission line 22 from the upper direction to the lower direction and supports the transmission line 22 by the elastic force of the coil spring 405 when the transmission line 22 is pushed upward.

The case 401 is formed on the inner side between the first upper pressing support portion 410 and the second upper pressing support portion 420 and is coupled to the inner bottom surface of the second lower spring support 412, A coil spring 413 is coupled to one side of the spring support 412 and a second upper spring support 414 is coupled to the coil spring 413 and a roller 415 are coupled.

The roller 415 pushes the transmission line 22 from the lower to the upper direction and supports the transmission line 22 by the elastic force of the coil spring 413 when the transmission line 22 is pushed downward.

A third upper spring support 422 is formed on the inner side of the case 401 between the second upper pressing support portion 420 and the second inner upper support portion 430 and on the front surface of the inner side ceiling, A coil spring 423 is coupled to one side of the spring support 422 and a third lower spring support 424 is coupled to the coil spring 423 and a roller 430 are combined.

The roller 430 presses the transmission line 22 from the upper direction to the lower direction and supports the transmission line 22 by the elastic force of the coil spring 423 when the transmission line 22 is pushed upward.

The transmission line 22 is passed through the space between the first inner upper support portion 402 and the first inner lower support portion 403 and is tightly supported and fixed while the ruler 406 is pushed downward, The first upper pressing support portion 420 and the second upper pressing support portion 420 are inserted into a space between the first upper pressing support portion 410 and the first lower pressing support portion 411 and are tightly supported and fixed while pressing the ruler 415 upward, The second inner lower support portion 430 and the second inner lower retainer portion 431 are inserted into a space between the first and second lower pushing and supporting portions 421 and 421 and are tightly supported and fixed while pressing the lower portion of the ruler 430, As shown in FIG.

The embodiments of the present invention described above are not implemented only by the apparatus and / or method, but may be implemented through a program for realizing functions corresponding to the configuration of the embodiment of the present invention, a recording medium on which the program is recorded And such an embodiment can be easily implemented by those skilled in the art from the description of the embodiments described above.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

10: Jeonju 11, 12: Wanchul
20: Insulator 22: Transmission line
100: position shifting member 200: shock absorbing device
300: tension adjusting portion 310: wire bracket
311: Stopper 320: Hydraulic cylinder part

Claims (1)

A bobbin 10 fixed to the electric pole 10 and an insulator 20 fixed to the bobbin 11 and 12 and connecting the transmission line 22 in an insulated state. ,
The brass bar 12 has a columnar vertical column portion 101 vertically erected on the side wall and a razor-shaped fish portion 102 formed on the entire surface of the vertical column portion 101, A driving motor 105 coupled to the pinion gear portion 104 to provide a driving force to the pinion gear portion 104 and a driving motor 105 coupled to the pinion gear portion 104, And a locating member (100) comprising a pinion gear portion (104) and a movable housing (103) having a predetermined internal space portion for containing the drive motor (105)
The movable housing 103 is coupled to a plate 106 having a predetermined width and thickness on one side,
The transmission line 22 having passed the insulator 20 has a cylinder 323, a cylinder 323 and a connecting member 321 which are connected to the lower surface of the electric wire bracket 310 through the electric wire bracket 310, And a tension adjusting part 300 having a hydraulic cylinder part 320 composed of a connecting member 321 and a stopper 311 coupled to one end of the connecting member 321,
The tension regulator 300 is coupled to the upper portion of the plate 106 and the hydraulic cylinder 320 includes a cylindrical cylinder 323 having a chamber chamber 324 filled with working fluid,
The cylinder 323 includes a longitudinal connecting member 321, a cylindrical piston 322 coupled to the connecting member 321 and slidably inserted by the connecting member 321, The piston increase preventing portion 325 is disposed at a predetermined distance from the piston 322 and an elevating member 326 is installed on a surface of the piston increase preventing portion 325. The elevating member 326 has a predetermined depth A part of the lifting push spring 327 is inserted into the groove and the remaining portion of the lifting push spring 327 extends to the bottom surface of the cylinder 323,
When the pinion gear portion 104 is rotated by driving the driving motor 105, the moving housing 103 moves up and down along the rack size portion 102, Moved,
The transmission line 22 is connected to a tension adjusting unit 300 that connects the hydraulic cylinder 320 to the lower surface of the wire bracket 310 so that the transmission line 22 is not broken even if the transmission line 22 is strongly shaken by an external force. And the tension of the transmission line (22) is adjusted so as to buffer the tension of the transmission line (22).

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