KR101939248B1 - Power transmission and distribution cable support apparatus - Google Patents

Abstract

The present invention relates to an earthquake-proof power transmission/distribution cable support device which can accommodate and support a power transmission/distribution cable. The earthquake-proof power transmission/distribution cable support device includes: a bottom plate; a base plate mounted on an upper portion of the bottom plate and slidable to the bottom plate; a height adjusting rod provided to be able to freely rotate on a base plate; a raising/lowering plate screwed to the height adjusting rod to be raised or lowered; a support band formed in a circular ring shape to receive and support a power transmission/distribution cable; a micro-length adjusting body extending downward from the support band and having a circular tube portion formed on a lower portion thereof; a holding rod formed on the circular tube portion of the micro-length adjusting body to protrude in the direction in which the outer diameter thereof is extended; a lower support tube having the circular tube portion of the micro-length adjusting body inserted thereinto to be supported thereby; a micro-length adjusting nut adjusting a support position for the holding rod while being raised or lowered with respect to the lower support tube; a vertical vibration damping spring coupled between a bottom portion of the cable support device and a bottom portion of the lower support tube; a first sub-bracket extending horizontally in the direction from the outer circumferential surface of the lower support tube towards the height adjusting rod; and a first horizontal vibration damping portion coupled between the first sub-bracket and a threaded portion of the raising/lowering plate to attenuate vibrations transmitted from the outside. According to such a vibration-proof power transmission/distribution cable support device, a support position for the power transmission/distribution cable can be easily adjusted, and vibrations due to an earthquake or the like can be efficiently attenuated.

Description

Technical Field [0001] The present invention relates to a power transmission and distribution cable support apparatus,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0002] The present invention relates to a transmission / distribution cable supporting device for a vibration type transmission, and more particularly, to a transmission / distribution cable supporting device capable of efficiently damping vibrations applied from the outside.

Generally, transmission and distribution cables are installed in a way that is buried in the ground in recent years in consideration of the urban beauty and the movement obstacle of people or vehicles.

A device for supporting a transmission / distribution cable installed in the ground is proposed variously, such as a domestic registration number 10-1359561.

On the other hand, a structure of a transmission and distribution cable supporting device for relieving vibration and providing a stable supporting force for a transmission cable, which is frequently encountered in recent earthquakes and excavations, has been proposed in Korean Patent No. 10-1823311.

However, the above-mentioned transmission / distribution cable support apparatus has a disadvantage in that the spring force of the spring coupled to the base plate is changed when adjusting the height of the cable fixture, thereby changing the elastic force.

In addition, there is a disadvantage in that it is not possible to independently adjust the height of each of the cable fasteners arrayed in pairs.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a transmission and distribution cable supporting apparatus which is easy to adjust the supporting position of a transmission and distribution cable and can improve vibration attenuation efficiency applied from the outside.

In order to accomplish the above object, a transmission and distribution cable supporting apparatus according to the present invention is a transmission and distribution cable supporting apparatus capable of receiving and supporting a transmission and distribution cable, comprising: a bottom plate; A base plate disposed above the bottom plate; First and second sliding guide members spaced apart from each other on an upper surface of the bottom plate, the first and second sliding guide members extending inwardly from the mutually facing surfaces and extending along the first direction; First and second sliders inserted into the sliding guide grooves and coupled to be slidable along the first direction on the upper surfaces of the first and second sliding guide members and slidably seated on the upper surface of the base plate; A first connecting rod extending from a side surface of the first slider toward the second slider; A second connecting rod extending from the side surface of the second slider toward the first slider and having a receiving groove slidably receiving the first connecting rod; An auxiliary spring installed in the receiving groove of the second connecting rod to apply an elastic force in a direction in which the first connecting rod moves away from the second connecting rod; A height adjusting rod extending perpendicularly from a center of the base plate, the height adjusting rod being freely rotatable with respect to the base plate and having threads on an outer circumferential surface thereof; The height adjusting rod is disposed at the center so that the height adjusting rod is screwed with the height adjusting rod outside the height adjusting rod, and the upwardly extending threaded portion is extended from the bottom of the height adjusting rod, Up plate having a bottom portion extending in the direction of the arrow; A guide rod extending upward from the base plate through a guide hole formed in a bottom portion of the lifting plate; A support band formed in a circular ring shape to receive and support the transmission / distribution cable; A micro-length adjusting body extending downward from the supporting band and having a circular tube portion at a lower portion thereof; An engaging rod protruding in a direction of expanding an outer diameter of the circular tube portion of the micro-length adjusting body; A recessed groove extending downward to a predetermined length from the upper end of the retaining rod so as to allow the upper end of the retaining groove to enter the upper end of the retaining rod, A lower support tube having a thread on the outer circumferential surface thereof; A fine length adjusting mechanism which is screwed through an outer circumferential surface of the lower gripper tube to support the engaging rod at a lower portion of the engaging rod and is moved up and down with respect to the lower support tube by rotation to adjust a supporting position of the engaging rod in the constraining groove, A nut; A vertical vibration damping spring coupled between the bottom portion of the lower branch pipe and the bottom portion; A first sub bracket extending horizontally in a direction from the outer circumferential surface of the lower gripper tube toward the height adjusting rod; And a first horizontal vibration damping part coupled between the first sub bracket and the threaded part of the rising / falling support plate to attenuate vibration transmitted from the outside, the first horizontal vibration damping part comprising: A horizontal rod coupled to the coupling portion and extending in the horizontal direction and having threads on the outer peripheral surface; A first dustproof portion installed in the horizontal rod and elastically deforming in a horizontal direction by a vibration applied from the outside to perform a dustproof function; A second dustproof portion provided on the horizontal rod adjacent to the first dustproof portion along the direction toward the bottom paper tube and elastically deforming in a horizontal direction due to external vibration; A contact plate supported through the horizontal rod and configured to flow between the first anti-vibration unit and the second anti-vibration unit; and a second anti-vibration unit extending from both ends of the contact plate in a direction toward the first sub- And a horizontal support body rotatably hinged to the first sub bracket, wherein the first vibration preventing portion is formed in a disk shape having a through hole through which the horizontal rod passes, A first damping ring provided outside the contact plate and flowing along the horizontal rod and made of a rubber material and a first stopper coupled to the horizontal rod at a position spaced apart from the first damping ring in a direction toward the threaded portion, And a first buffer spring installed to surround the horizontal rod and buffering vibrations applied from the outside and formed in the form of a coil spring A second damping ring formed in the shape of a circular plate having a through hole through which the horizontal rod penetrates and formed inside the contact plate of the horizontal support body and flowing along the horizontal rod and made of a rubber material; And a second stopper which is coupled to the horizontal rod at a position spaced apart from the second damper ring in a direction toward the lower branch pipe. The second stopper is installed to surround the horizontal rod, And a buffer spring.

A sub-support body extending in a direction from the edge of the contact plate of the horizontal support body toward the threaded portion to receive the first anti-vibration portion; A plurality of first dustproof sheets installed in the horizontal support body so as to enter between the gaps of the second buffer springs and formed in a sheet form by a vibration proof material; And a plurality of second vibration-proof sheets installed on the sub-support body so as to enter between the gaps of the first buffer springs and formed in the form of a sheet of a vibration-proof material.

A first piezoelectric element coupled to the second vibration damping sheet and generating electrical energy by contact when the first buffer spring contracts; A second piezoelectric element coupled to the first vibration damping sheet and generating electrical energy by the contact of the second buffer spring during shrinkage; A first rectifying section for rectifying power generated in the first piezoelectric elements; A second rectifying unit for rectifying power generated in the second piezoelectric elements; A charging unit charging the power generated by the first rectifying unit and the second rectifying unit; And a recording processor for recording the first voltage fluctuation information generated by the first rectifying part and the second voltage fluctuation information generated by the second rectifying part in the recording part, which is operated by the electric power charged by the charging part, desirable.

Further preferably, the outer side surface of the lower support tube is formed with an engaging groove which is spaced apart from the restricting groove in the longitudinal direction and which is drawn inward, and is hinged to the bottom surface of the length adjusting nut, And a latch formed to be inserted into or removed from the groove.

INDUSTRIAL APPLICABILITY According to the transmission and distribution cable supporting apparatus of the present invention, it is easy to adjust the support position of the transmission and distribution cable, and it is possible to efficiently attenuate vibration caused by an earthquake or the like.

1 is a cross-sectional view of a transmission and distribution cable supporting apparatus according to an embodiment of the present invention,
Fig. 2 is an enlarged view of the first horizontal vibration damping portion of Fig. 1,
Fig. 3 is an exploded perspective view illustrating the micro-length adjusting element of Fig. 1,
4 is an exploded perspective view of the micro-length adjusting element according to another embodiment of the present invention,
FIG. 5 is an assembled cross-sectional view of FIG. 4,
FIG. 6 is a block diagram showing a power processing unit for processing power generated in the piezoelectric element of FIG. 2,
7 is a cross-sectional view illustrating a support band according to another embodiment of the present invention,
8 is a cross-sectional view of a portion of a transmission and distribution cable support apparatus according to another embodiment of the present invention.

Hereinafter, a transmission / distribution cable support apparatus according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is an enlarged view of the first horizontal vibration damping unit of Fig. 1, Fig. 3 is an enlarged view of the first horizontal vibration damping unit of Fig. 1, and Fig. 3 is a cross- Fig.

1 to 3, a transmission and distribution cable supporting apparatus 100 according to the present invention includes a bottom plate 10, first and second sliding guide members 21 and 22, first and second sliders 31 The first and second connecting rods 41 and 42, the auxiliary spring 45 and the base vibration damping sheet 47, the base plate 110, the height adjusting rod 120, the lifting plate 130, The guide rod 151, the support band 160, the fine-length adjusting body 170, the engaging rod 175, the lower support pipe 177, the fine-length adjusting nut 178, the vertical vibration damping spring 181, 1 sub bracket 183, and a first horizontal vibration damping unit 200a.

The bottom plate 10 is formed in a plate shape to be supported on the ground.

The first and second sliding guide members 21 and 22 are spaced apart from each other on the upper surface of the bottom plate 10 and extend in the first direction and extend in the first direction, Grooves 21a and 22a are formed so as to face each other.

The first and second sliding guide members 21 and 22 are fixed to the bottom plate 10 with fixing bolts.

The first and second sliders 31 and 32 are inserted into the sliding guide grooves 21a and 22a so that they can slide along the first direction on the upper surfaces of the first and second sliding guide members 21 and 22 And the base plate 110 is slidably seated on the upper surface.

The first and second sliders 31 and 32 are formed in a 'C' shape so as to be inserted into the sliding guide grooves 21a and 22a.

The first connecting rod 41 extends from the side surface of the first slider 31 toward the second slider 32.

The second connecting rod 42 extends from the side surface of the second slider 32 toward the first slider 31 and has a receiving groove 42a slidably receiving the first connecting rod 41 therein.

The auxiliary spring 45 is installed in the receiving groove 42a so that the first connecting rod 41 applies an elastic force in a direction away from the second connecting rod 42. [

The auxiliary spring 45 is a coil spring.

The base vibration damping sheet 47 is formed in a sheet form of a vibration-proof material so as to enter between the gaps of the auxiliary springs 45 in the receiving grooves 42a of the second connecting rod 42.

The base antivibration sheet 47 may be formed of a rubber material.

The base vibration insulating sheet 47 functions to attenuate the vibration.

According to this structure, when vibration such as an earthquake occurs, sliding is allowed in the first direction of the first and second sliders 31 and 32 with respect to the bottom plate 10, and in the second direction orthogonal to the first direction The first and second sliders 31 and 32 can be relaxed and contracted via the auxiliary spring 45 to minimize the transmission of vibration to the upper base plate 110. [

The base plate 110 is formed in a plate shape.

The height adjusting rod 120 extends vertically from the center of the base plate 110 in a cylindrical shape and is freely rotatable with respect to the base plate 110.

A screw thread is formed on the outer circumferential surface of the height adjusting rod 120 so as to engage with a lifting plate 130 described later and support up and down movement.

The upper end of the height adjusting rod 120 is formed with a handle portion whose outer diameter is enlarged so as to be used as a handle.

The ascending and descending plate 130 includes a threaded portion 131 that is screwed with the height adjusting rod 120 and extends upward from the height adjusting rod 120 so that the height adjusting rod 120 is disposed at the center, And a bottom portion 132 extending in a direction in which the outer diameter of the threaded portion 131 extends in a horizontal plane at a lower portion of the threaded portion 131.

The guide rod 151 is inserted into the guide hole 134 formed in the bottom portion 132 of the lifting plate 130 from the base plate 110 at a position corresponding to the edge of the position away from the height adjusting rod 120 of the bottom portion 132 To guide the lifting and lowering plate 130 up and down to a restrained state.

The support band 160 is formed in a circular ring shape to receive and support the transmission / distribution cable 50.

The micro-length adjusting body 170 has a structure in which a circular tube portion 171 is formed at a lower portion extending downward from the support band 160.

The micro-length adjusting body 170 is composed of a coupling plate 172 inserted and coupled to the support band 160 and a coupling plate 173 joined in a plate form between the coupling plate 172 and the circular tube portion 171 have.

The circular tube portion 171 is formed with a plurality of insertion holes 171a spaced apart from each other in the vertical direction so as to insert the latching rods 175, which will be described later, at a desired height.

The engaging rod 175 is provided on the circular tube portion 171 of the fine-length adjusting body 170 so as to protrude in a direction in which the outer diameter of the engaging rod 175 extends through the insertion hole 171a.

The bottom guide tube 177 is formed with a receiving groove 177a having an open top so that the circular tube portion 171 of the fine length adjusting member 170 can be inserted and supported, A restraining groove 177b extending downward to a predetermined length so as to enter the restricting state is formed and a screw thread 177c is formed on the outer circumferential surface.

The fine length adjusting nut 178 is screwed through the outer peripheral surface of the lower holding tube 177 to support the engaging rod 175 at the lower portion of the engaging rod 175 and is raised and lowered with respect to the lower supporting tube 177 by rotation The support position of the retaining rod 175 in the restraining groove 177b can be adjusted.

According to this structure, the height of the lifting plate 130 can be adjusted by the height adjusting rod 120 and the height of the lifting plate 130 can be adjusted by rotating the fine length adjusting nut 178 on the lifting plate 130 The entering depth of the circular tube portion 171 to be inserted is adjusted so that the separation distance from the lifting plate 130 to the support band 160 can be finely adjusted independently.

4 and 5 show a structure capable of suppressing the rotation of the fine length adjusting nut 178 after the fine length adjusting nut 178 is adjusted to a desired height. The same reference numerals denote the same elements as those in the drawings.

As shown in FIGS. 4 and 5, on the outer surface of the lower support pipe 177, a lead-in groove 179, which is spaced apart from the restraining groove 177b and spaced apart from each other in the longitudinal direction, And an engaging groove 179a repeatedly formed in a sawtooth shape along the longitudinal direction is formed in the lead-in groove 179. As shown in FIG.

In addition, a latch 176 hinged to the bottom surface of the fine-length adjusting nut 178 and formed to be inserted into or detached from the latching groove 179a is provided.

In this case, while the latch 176 is disengaged from the lower support tube 177 while the fine length adjusting nut 178 is rotated to the desired height of the support band 160, The latch 176 may be rotated so as to enter the latching groove 179a and the rotation of the fine length adjusting nut 178 may be suppressed.

The vertical vibration damping spring 181 is coupled between the bottom portion of the lower holding tube 177 and the bottom portion 132 to attenuate the vertical vibration.

The first sub-bracket 183 is horizontally extended from the outer circumferential surface of the lower holding tube 177 toward the height adjusting rod 120 and is hinged to a later-described horizontal supporting body 210.

The first horizontal vibration damping portion 200a is coupled between the first sub bracket 183 and the threaded portion 131 of the elevating and lowering support plate 130 to attenuate vibration transmitted from the outside.

The first horizontal vibration damping unit 200a includes a horizontal support body 210, a horizontal rod 221, a first anti-vibration unit 230, and a second anti-vibration unit 250.

The horizontal support body 210 includes a contact plate 212 supported through the horizontal rod 221 and configured to flow between the first anti-vibration unit 230 and the second anti-vibration unit 250, And the second vibration preventing portion 250 can be received by the extension plate 213 extending from both ends in the direction toward the first sub bracket 183.

The horizontal support body 210 is rotatably hinged to the first sub bracket 183.

The sub support body 215 is formed to extend from the edge of the contact plate 212 of the horizontal support body 210 in the direction toward the threaded portion 131 to receive the first anti-vibration portion 230.

The horizontal rod 221 is coupled to the threaded portion 131 and extends in the horizontal direction, and a thread is formed on the outer peripheral surface.

The horizontal rod 221 is fixed to the threaded portion 131 by fixing nuts.

The first anti-vibration unit 230 is installed on the horizontal rod 221 and is elastically deformed in the horizontal direction by vibration externally applied to the anti-vibration unit 230.

The first anti-vibration portion 230 includes a first damping ring 231, a first stopper 233, and a first buffer spring 232.

The first damping ring 231 is formed in the shape of a circular plate having a through hole through which the horizontal rod 221 passes and is installed outside the contact plate 212 of the horizontal support body 210 and flows along the horizontal rod 221, .

The first stopper 233 is coupled to the horizontal rod 221 at a position spaced apart from the first damping ring 231 in the direction toward the threaded portion 131 to suppress the disengagement of the first cushion spring 232 .

A nut was applied to the first stopper 233.

The first cushion spring 232 is installed between the first damping ring 231 and the first stopper 233 so as to surround the horizontal rod 221 and absorbs external vibrations.

The second vibration preventing part 250 is installed on the horizontal rod 221 adjacent to the first vibration preventing part 230 along the direction from the first vibration preventing part 230 toward the lower holding paper pipe 177, And is elastically deformed in the horizontal direction to perform a vibration-proof function.

The second vibration preventing portion 250 includes a second damping ring 251, a second stopper 253, and a second cushioning spring 252.

The second damping ring 251 is formed in the shape of a disk having a through hole through which the horizontal rod 221 passes and is installed inside the contact plate 212 of the horizontal support body 210 and flows along the horizontal rod 221, .

The second stopper 253 is coupled to the horizontal rod 221 at a position spaced apart from the second damper ring 251 in the direction toward the lower branch pipe 177 to suppress the disengagement of the second buffer spring 252 .

The second stopper 253 has a nut.

The second cushioning spring 252 is installed between the second damping ring 251 and the second stopper 253 so as to surround the horizontal rod 221 and absorbs vibrations applied from the outside to form a coil spring.

The first vibration damping sheet 261 is installed on the horizontal support body 210 so as to enter between the gaps of the second damping springs 252, and a plurality of the vibration damping sheets 261 are formed in a sheet form.

The first dustproof sheet 261 may be formed of a rubber material.

The first piezoelectric element 265 is coupled to the first vibration damping sheet 261 and generates electrical energy by the contact of the second cushioning spring 252 during shrinkage.

The second vibration damping sheet 262 is installed on the sub support body 215 so as to enter between the gaps between the first damping springs 232 and is formed in a sheet form as a vibration damping material.

The second dustproof sheet 262 may be formed of a rubber material.

The second piezoelectric element 266 is coupled to the second vibration damping sheet 262 to generate electrical energy by contracting the first buffer spring 232 when it contracts.

A vibration history recording unit for recording external vibration generation history information using the power generated by the first and second piezoelectric elements 265 and 266 will be described with reference to FIG.

The vibration history recording unit 280 includes first and second rectifying units 281 and 282, a charging unit 285, a recording processing unit 287, and a recording unit 288.

The first rectifying part 281 rectifies the electric power generated by the first piezoelectric elements 265 and supplies the rectified electric power to the charging part 285.

The output voltage information of the first rectifying unit 281 is provided to the recording processing unit 287. [

The second rectifying unit 282 rectifies the electric power generated by the second piezoelectric elements 266 and supplies the rectified electric power to the charging unit 285.

The output voltage information of the second rectifying unit 282 is provided to the recording processing unit 287. [

The charging unit 285 charges the electric power generated by the first rectifying unit 281 and the second rectifying unit 282.

The electric power charged by the charging unit 285 is supplied as the driving electric power of the recording processing unit 287.

The recording processing unit 287 is operated by the electric power charged by the charging unit 285 and outputs the first voltage fluctuation information generated in the first rectifying unit 281 and the second voltage fluctuation information generated in the second rectifying unit 282, (288).

That is, the first cushion spring 232 or the second cushion spring 252 can not move the first or second piezoelectric element 265 or 266 from the first rectifying section 281 or the second rectifying section 282 A voltage signal corresponding to the generated electric power is outputted, and when this voltage signal is recorded, it can be used as history information on vibration occurrence.

The recording unit 288 applies a memory capable of holding recording information even when no power is supplied.

The supporting band 160 may be divided into four regions to accommodate the transmission / distribution cable, and an example thereof will be described with reference to FIG.

Referring to FIG. 7, the support band 260 has a structure including a lower band portion 261, an upper band portion 263, and first and second rotating partition walls 267 and 268.

The lower band portion 261 has an engaging portion 261a whose lower end extends downward to be engaged with the upper portion of the microstructure adjusting body 170 and a lower receiving portion 261a formed in a semicircular shape at the upper end of the engaging portion 261a 261b.

The lower receiving portion 261a has a structure in which the upper portion is open and the first and second lower divided accommodation spaces 262a and 262b are divided by the vertical partition 262 so as to extend upward in the center.

It is preferable that the vertical partition wall 262 extends to a height of the lower receiving portion 261a.

The upper band portion 263 is coupled by a hinge 264 at one side of the lower band portion 261 to rotate the first and second lower split accommodation spaces 262a and 262b of the lower band portion 261 And is formed into a semicircle so as to be opened and closed.

The upper band portion 263 may be fixedly coupled to the other side of the lower band portion 261 by various methods such as a screw coupling method.

The first and second rotating partition walls 267 and 268 extend upward from the vertical partition wall 262 so as to face each other and are rotatably coupled to the vertical partition wall 262 by a hinge.

The first and second rotating partition walls 267 and 268 are connected to each other in such a manner that the mutually opposing surfaces of the first and second rotating partition walls 267 and 268 are inserted into the arc shape so as to be able to receive the transmission / And the seat back portions 267a and 268a are formed.

The first and second rotatable partition walls 267 and 268 are rotatable in a vertical plane so that protrusions are formed on one side and protrusion insertion grooves are formed on the other side so that the first and second rotatable partition walls 267 and 268 can be mutually fitted and supported when they are in close contact with each other.

Reference numerals 265a and 265b denote mounting seats which are configured to support the first and second rotating partition walls 267 and 268 so as to be seated when the first and second rotating partition walls 267 and 268 are rotated in a horizontal state .

On the other hand, a second horizontal vibration damping portion may be formed on the opposite side of the first horizontal vibration damping portion 200a with respect to the lower support pipe 177, and an example thereof will be described with reference to Fig.

8, a side extension portion 133 extending upward from the bottom portion 132 is formed on the lifting plate 130 so as to face the threaded portion 131. As shown in FIG.

Further, a second sub bracket 383 extending in the vertical direction in the direction from the outer peripheral surface of the lower gripper tube 177 toward the side extending portion 133 is formed.

The second horizontal vibration damping part 200b is coupled between the side extension part 133 and the second sub bracket 383 to attenuate vibration transmitted from the outside.

The detailed structure of the second horizontal vibration damping part 200b may be the same as that of the first horizontal vibration damping part 200a.

According to the above-described transmission / distribution cable support apparatus, it is easy to adjust the support position of the transmission / distribution cable, and the vibration due to an earthquake or the like can be efficiently attenuated.

110: base plate 120: height adjustment rod
130: lifting plate 151 guide rod
160: support band 170: fine length adjustment
200a: a first horizontal vibration damping portion

Claims (6)

delete A transmission and distribution cable support apparatus capable of receiving and supporting a transmission and distribution cable,
A bottom plate;
A base plate disposed above the bottom plate;
First and second sliding guide members spaced apart from each other on an upper surface of the bottom plate, the first and second sliding guide members extending inwardly from the mutually facing surfaces and extending along the first direction;
First and second sliders inserted into the sliding guide grooves and coupled to be slidable along the first direction on the upper surfaces of the first and second sliding guide members and slidably seated on the upper surface of the base plate;
A first connecting rod extending from a side surface of the first slider toward the second slider;
A second connecting rod extending from the side surface of the second slider toward the first slider and having a receiving groove slidably receiving the first connecting rod;
An auxiliary spring installed in the receiving groove of the second connecting rod to apply an elastic force in a direction in which the first connecting rod moves away from the second connecting rod;
A height adjusting rod extending perpendicularly from a center of the base plate, the height adjusting rod being freely rotatable with respect to the base plate and having threads on an outer circumferential surface thereof;
The height adjusting rod is disposed at the center so that the height adjusting rod is screwed with the height adjusting rod outside the height adjusting rod, and the upwardly extending threaded portion is extended from the bottom of the height adjusting rod, Up plate having a bottom portion extending in the direction of the arrow;
A guide rod extending upward from the base plate through a guide hole formed in a bottom portion of the lifting plate;
A support band formed in a circular ring shape to receive and support the transmission / distribution cable;
A micro-length adjusting body extending downward from the supporting band and having a circular tube portion at a lower portion thereof;
An engaging rod protruding in a direction of expanding an outer diameter of the circular tube portion of the micro-length adjusting body;
A recessed groove extending downward to a predetermined length from the upper end of the retaining rod so as to allow the upper end of the retaining groove to enter the upper end of the retaining rod, A lower support tube having a thread on the outer circumferential surface thereof;
A fine length adjusting mechanism which is screwed through an outer circumferential surface of the lower gripper tube to support the engaging rod at a lower portion of the engaging rod and is moved up and down with respect to the lower supporting tube by rotation to adjust a supporting position of the engaging rod in the constraining groove, A nut;
A vertical vibration damping spring coupled between the bottom portion of the lower branch pipe and the bottom portion;
A first sub bracket extending horizontally in a direction from the outer circumferential surface of the lower gripper tube toward the height adjusting rod;
And a first horizontal vibration damping part coupled between the first sub bracket and the screw engagement part of the elevating and lowering plate to attenuate vibration transmitted from the outside,
The first horizontal vibration damping unit
A horizontal rod coupled to the threaded portion and extending in the horizontal direction and having threads on an outer peripheral surface;
A first dustproof portion installed in the horizontal rod and elastically deforming in a horizontal direction by a vibration applied from the outside to perform a dustproof function;
A second dustproof portion provided on the horizontal rod adjacent to the first dustproof portion along the direction toward the bottom paper tube and elastically deforming in a horizontal direction due to external vibration;
A contact plate supported through the horizontal rod and configured to flow between the first anti-vibration unit and the second anti-vibration unit; and a second anti-vibration unit extending from both ends of the contact plate in a direction toward the first sub- And a horizontal support body rotatably hinged to the first sub bracket,
The first anti-
A first damping ring formed of a rubber material which is formed in the form of a disk having a through hole through which the horizontal rod penetrates and which is installed outside the contact plate of the horizontal supporting body and flows along the horizontal rod; And a first buffer spring installed to surround the horizontal rod between the first stopper coupled to the horizontal rod at a position spaced apart from the coupling portion in a direction away from the horizontal rod,
The second anti-
A second damping ring formed in the shape of a circular plate having a through hole through which the horizontal rod penetrates and formed of a rubber material installed inside the contact plate of the horizontal supporting body and flowing along the horizontal rod, And a second buffer spring which is installed to surround the horizontal rod between the second stopper coupled to the horizontal rod at a position spaced apart from the branch pipe in a direction away from the branch pipe,
A sub-support body extending in a direction from the contact plate edge of the horizontal support body toward the threaded portion to receive the first anti-vibration portion;
A plurality of first dustproof sheets installed in the horizontal support body so as to enter between the gaps of the second buffer springs and formed in a sheet form by a vibration proof material;
And a plurality of second vibration-proof seats installed on the sub-supporting body so as to enter between the gaps of the first buffer springs and formed in a sheet form of a vibration-proof material. [3] The apparatus of claim 2, further comprising: a first piezoelectric element coupled to the second vibration damping sheet and generating electrical energy by contact of the first buffer spring during shrinkage;
A second piezoelectric element coupled to the first vibration damping sheet and generating electrical energy by the contact of the second buffer spring during shrinkage;
A first rectifying section for rectifying power generated in the first piezoelectric elements;
A second rectifying unit for rectifying power generated in the second piezoelectric elements;
A charging unit charging the power generated by the first rectifying unit and the second rectifying unit;
And a recording processor for recording the first voltage fluctuation information generated by the first rectifying unit and the second voltage fluctuation information generated by the second rectifying unit in a recording unit, which is operated by the electric power charged by the charging unit, Characterized in that the transmission and distribution cable support device. [5] The apparatus as claimed in claim 3, wherein an outer side surface of the lower support tube is formed with an engagement groove which is spaced apart from the restraint groove in the longitudinal direction at a position spaced apart from the restraint groove and hinged to the bottom of the length adjustment nut, And a latch formed to be inserted or removed in the latching groove. 5. The method of claim 4, wherein the support band
A lower band portion coupled to an upper portion of the micro-length adjusting body and having first and second lower divided accommodation spaces divided by vertical barriers which are open at an upper portion and extend upward at a central portion;
An upper band portion hinged to one side of the lower band portion and capable of opening and closing the first and second lower split accommodation spaces of the lower band portion by pivoting;
The upper surface of the lower band portion and the upper surface of the lower band portion are connected to each other so as to be able to receive the transmission / And a first and a second rotating partition wall formed with a raised arc-shaped portion. 6. The connector according to claim 5, further comprising: a side extending portion extending upward from the bottom portion so as to face the threaded portion;
A second sub bracket extending horizontally in a direction from the outer peripheral surface of the lower gripper tube toward the side extension portion;
And a second horizontal vibration damping part coupled between the side extension part and the second sub bracket to attenuate vibration transmitted from the outside.

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