KR101787437B1 - Testing device for lateral vibration of cable - Google Patents

Abstract

A cable lateral vibration testing apparatus is disclosed. According to an aspect of the present invention, A driving cylinder mounted on the body frame; A first driving bar which is fastened to the body frame through a first coaxial shaft and has an upper end coupled to the driving cylinder and formed with a first slot hole along the longitudinal direction; A second driving bar coupled to the body frame through a second rotating shaft formed on a lower side of the first coaxial shaft and having a first coupling pin to be slidably engaged with the first slot hole at an upper end thereof; And a cable frame disposed at a lower portion of the body frame to reciprocate the cable in a lateral direction so that both ends are supported by a pair of pivotal bars and the intermediate portion is fastened to the lower end of the second drive bar, And a vibration bar provided on the vibration bar.

Description

TECHNICAL FIELD [0001] The present invention relates to a cable lateral vibration testing apparatus,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cable lateral vibration testing apparatus, and more particularly, to a cable lateral vibration testing apparatus that reciprocates a cable in a lateral direction.

Generally, in order to support a power cable, a bare iron is installed on a pole, various metal brackets for fixing a power cable to a bare iron, and insulators for insulation are mounted. In addition, to connect the power cable to the next pole, a jumper cable is installed to make the cable and the pole insulated, and the power cable is connected to the cable. Although a method of using a jumper cable as described above is used as a method for inserting a metal cable connected to a pole and connecting a power cable, there is a problem that a jammer cable may be damaged and a power failure may occur.

That is, the cable connection method using the jumper cable may cause a power failure or the like due to a phenomenon in which a wire is loosened at the end of the jumper cable or a jumper cable is short-circuited. Especially, in the region where the wind speed is strong due to the windy seaside area or the local terrain, the above jumper cable damage is frequently occurred.

The damage of the jumper cable is thought to be caused by the lateral vibration of the jumper cable due to wind load. That is, it is understood that the jumper cable can be periodically vibrated in the lateral direction by the wind load, which causes plastic deformation in the jumper cable or short-circuiting of the jumper cable.

However, in the conventional wind tunnel equipment for testing durability and deformation of cables, it is only possible to simulate the case where continuous wind load is applied in one direction, and it is impossible to simulate the case where the direction of wind load changes periodically and the cable periodically oscillates in the lateral direction There was a limit. That is, the damage of the jumper cable can be more seriously generated when the jumper cable is periodically oscillated in the lateral direction. The conventional wind tunnel device is for simply applying a wind load like a wind to the cable, , There was a limit in simulating the periodic lateral vibration of the cable as described above.

It is an object of the present invention to provide a cable lateral vibration testing apparatus capable of periodically transversely reciprocating a cable to easily test and measure changes in characteristics of a cable in a lateral vibration .

According to an aspect of the present invention, A driving cylinder mounted on the body frame; A first driving bar which is fastened to the body frame through a first coaxial shaft, has an upper end fastened to the driving cylinder and has a first slot hole formed along a longitudinal direction thereof; A second driving bar coupled to the body frame through a second pivot shaft formed on a lower side of the first pivot shaft and having a first coupling pin that is slidably coupled to the first slot hole at an upper end thereof; And a cable disposed at a lower portion of the body frame to reciprocate the cable in a transverse direction so that both ends thereof are supported by a pair of pivotal bars and an intermediate portion is fastened to a lower end portion of the second driving bar, A vibration transverse vibration testing device including a vibration bar having a fastening hole can be provided.

At this time, the body frame may be provided with a pair of cable fixing portions for fixing both ends of the cable.

The cable transverse vibration testing apparatus may further include a load cell provided on one side of the vibrating bar and measuring a reaction force of the cable when the vibrating bar reciprocates.

According to another aspect of the present invention, there is provided a body frame comprising: a body frame; A driving motor mounted on the body frame; A circular plate coupled to the body frame via a rotary shaft connected to the driving motor and having a second coupling pin at a position spaced apart from the rotary shaft by a predetermined distance in the radial direction; A third driving bar coupled to the body frame through a third coaxial shaft and having a second slotted hole formed along a longitudinal direction thereof and the second coupling pin coupled to the second slotted hole so as to be slidable; And a cable disposed at a lower portion of the body frame to reciprocate the cable in a transverse direction so that both ends thereof are supported by a pair of pivotal bars and an intermediate portion is fastened to a lower end portion of the third driving bar, A vibration transverse vibration testing device including a vibration bar having a fastening hole can be provided.

At this time, the body frame may be provided with a pair of cable fixing portions for fixing both ends of the cable.

The cable transverse vibration testing apparatus may further include a load cell provided on one side of the vibrating bar and measuring a reaction force of the cable when the vibrating bar reciprocates.

The embodiments of the present invention can easily test and evaluate the change of the reaction force of the cable by the lateral reciprocating motion by reciprocating the cable in the lateral direction. Therefore, the embodiments of the present invention can easily analyze and evaluate the durability change or the damage degree of the cable against the periodic lateral vibration generated by the wind load or the like.

1 is a front view of a cable lateral vibration testing apparatus according to a first embodiment of the present invention.
2 is a side view of the cable lateral vibration testing apparatus shown in Fig.
3 is a plan view of the cable lateral vibration testing apparatus shown in Fig.
4 is an operational state diagram of the cable lateral vibration testing apparatus shown in Fig.
5 is a front view of a cable lateral vibration testing apparatus according to a second embodiment of the present invention.
6 is a side view of the cable lateral vibration testing apparatus shown in Fig.
7 is a plan view of the cable lateral vibration testing apparatus shown in Fig.
8 is an operational state diagram of the cable lateral vibration testing apparatus shown in Fig.

Hereinafter, the configuration of the cable lateral vibration testing apparatus 100 according to the first embodiment of the present invention will be described with reference to the drawings.

1 is a front view of a cable lateral vibration testing apparatus 100 according to a first embodiment of the present invention. 2 is a side view of the cable lateral vibration testing apparatus 100 shown in Fig. 3 is a plan view of the cable lateral vibration testing apparatus 100 shown in Fig.

1 to 3, the cable lateral vibration testing apparatus 100 according to the present embodiment includes a body frame 110, a driving cylinder 120, a first driving bar 130, a second driving bar 140, A vibrating bar 150, and a load cell 160.

The body frame 110 forms the overall contour of the cable lateral vibration testing apparatus 100 and becomes a basic skeleton in which the driving cylinder 120, the first driving bar 130, the second driving bar 140, . A cable fixing part 111 for fixing the cable C may be formed on the body frame 110. The cable fixing portion 111 is for fixing both ends of the cable C, and may be formed as a pair.

The drive cylinder 120 provides a driving force for a lateral reciprocating motion of the vibrating bar 150 and the like. The driving cylinder 120 may be mounted on the body frame 110. Specifically, the driving cylinder 120 may be horizontally mounted on the upper side of the body frame 110. The driving cylinder 120 may be a hydraulic cylinder, a hydraulic actuator, a pneumatic cylinder, a pneumatic actuator, or the like.

The first driving bar 130 transmits the driving force of the driving cylinder 120 to the vibrating bar 150. At this time, the first driving bar 130 can be coupled to the body frame 110 so as to be rotatable through the first turning shaft 131. The first driving bar 130 may be disposed on the upper side of the body frame 110 so as to be adjacent to the driving cylinder 120. The first driving bar 130 may be disposed on the body frame 110 by the first pivot 131, And can be formed to be rotatable about the first coaxial shaft 131.

The upper end of the first driving bar 130 may be coupled to the driving cylinder 120. That is, the first driving bar 130 may be formed so that the upper end thereof is coupled to the driving cylinder 120, and the first driving bar 130 is rotated around the first rotating shaft 131 as the driving cylinder 120 is driven forward and backward.

Also, the first driving bar 130 may have a first slot hole 132 formed therein. The first slot hole 132 is for fastening the second driving bar 140 and may be formed to be long along the longitudinal direction of the first driving bar 130.

The second driving bar 140 transmits the driving force of the driving cylinder to the vibrating bar 150 together with the first driving bar 130 and may be disposed on the lower side of the first driving bar 130 . At this time, the second driving bar 140 can be coupled to the body frame 110 so as to be rotatable through the second pivot 141 formed on the lower side of the first pivot shaft 131. That is, the second driving bar 140 may be formed so that the intermediate portion is coupled to the body frame 110 by the second rotating shaft 141, and is rotatable around the second rotating shaft 141.

The upper end of the second driving bar 140 may be fastened to the first slot hole 132 formed in the first driving bar 130. Also, the upper end of the second driving bar 140 may be fastened so as to be slidable along the first slot hole 132. The first coupling pin 142 may be formed at an upper end of the second driving bar 140. The first coupling pin 142 may be coupled to the first slot hole 132, And may be formed to be slidable along the hole 132.

The vibrating bar 150 is for causing the cable C to reciprocate in the transverse direction and may be disposed on the lower side of the second driving bar 140. In addition, the oscillating bar 150 can be fastened to the lower end of the second driving bar 140 in the middle portion. At this time, the vibrating bar 150 can be fastened so that the intermediate portion and the lower end of the second driving bar 140 can rotate by a predetermined degree through hinge coupling or the like.

Both ends of the vibration bar 150 can be supported by the pair of support bars 151. [ The support bar 151 is used to suspend the vibrating bar 150 on the body frame 110. One end of the support bar 151 is coupled to the body frame 110 to be rotatable by hinge coupling or the like, Hinged or the like. In addition, the support bars 151 may be formed as a pair in order to support both ends of the vibration bar 150, respectively.

Meanwhile, the vibration bar 150 may be formed with a cable coupling hole 152 for coupling the cable C. A cable (C) can be inserted into and fastened to the cable fastening hole (152). At this time, a plurality of cable coupling holes 152 may be formed in the vibrating bar 150. When a plurality of cable fastening holes 152 are formed, each cable C can be fastened to each cable fastening hole 152. Therefore, a plurality of cables (C) can be simultaneously mounted and tested and measured.

Meanwhile, the load cell 160 may be mounted on one side of the vibration bar 150. Specifically, the load cell 160 is disposed adjacent to the cable clamping hole 152 to which the cable C is fastened, and can be connected to the cable C. At this time, the load cell 160 can measure the reaction force of the cable C when the cable C reciprocates in the lateral direction. That is, when the cable C is fixed to the vibration bar 150 and reciprocated in the lateral direction, a reaction force against the reciprocating motion as described above can be generated due to the rigidity of the cable C. The reaction force of the cable C becomes weak gradually as the reciprocating motion is continued due to the disconnection of the wire of the cable C. [ The load cell 160 is connected to the cable C so as to measure the reaction force as described above so as to evaluate the durability and the like of the cable C with respect to the lateral reciprocating motion.

Hereinafter, the operation of the cable lateral vibration testing apparatus 100 according to the first embodiment of the present invention will be described with reference to the drawings.

4 is an operational state diagram of the cable lateral vibration testing apparatus 100 shown in Fig.

Referring to FIG. 4, the tester first mounts the cable C to the cable lateral vibration testing apparatus 100. That is, the tester fixes both ends of the cable C to the cable fixing portion 111 provided in the body frame 110, respectively. The tester inserts the cable C into the cable fastening hole 152 provided in the vibrating bar 150 so that the intermediate portion of the cable C can be fixed to the vibrating bar 150. At this time, if necessary, a plurality of cable coupling holes 152 may be formed in the vibrating bar 150. In this case, a plurality of cables C may be mounted and tested and measured at the same time. That is, in order to compare and analyze the difference of the reaction force according to the type and the standard of the cable C, the tester installs a plurality of cables C having different types or specifications to the cable lateral vibration testing apparatus 100 at the same time Tests and measurements may also be performed.

Meanwhile, when the cable C is mounted on the cable lateral vibration testing apparatus 100 as described above, the tester drives the driving cylinder 120 to reciprocate the vibrating bar 150 in the lateral direction. Specifically, when the tester drives the driving cylinder 120, the piston of the driving cylinder 120 reciprocates in the left and right direction in Fig. By the reciprocating drive of the driving cylinder 120, the first driving bar 130 is rotated left and right around the first turning shaft. The second driving bar 140 coupled with the first slot hole 132 is rotated left and right about the second rotating shaft 141 in conjunction with the first driving bar 130. At this time, the first engaging pin 142 provided at the upper end of the second driving bar 140 is repeatedly moved along the first slot hole 132.

The vibrating bar 150 coupled to the lower end of the second driving bar 140 is reciprocally moved in the lateral direction in conjunction with the second driving bar 140. That is, the second driving bar 140 is rotated left and right about the second turning shaft 141, thereby reciprocating the vibrating bar 150 in the left-right direction. The vibrating bar 150 is laterally reciprocated to the left and right in Fig. 4 in a state in which both ends are supported by the supporting bar 151, whereby the cable C fastened to the vibrating bar 150 is also moved in the transverse direction Reciprocating motion.

If the transverse reciprocating motion as described above is continued, loosening of wire, wiring or the like may occur in the cable (C), and the tester can evaluate the durability and the like of the cable (C) through the test result as described above. In addition, the load cell 160 can measure the reaction force of the cable C with respect to the lateral reciprocating motion as described above. Therefore, the tester can also evaluate the durability and rigidity of the cable C in the lateral directional movement through the measured value of the load cell 160.

Hereinafter, the configuration of the cable lateral vibration testing apparatus 200 according to the second embodiment of the present invention will be described with reference to the drawings. Hereinafter, for the sake of convenience of description, the same components as those in the above-described embodiments will not be described in detail, and the differences will be mainly described.

5 is a front view of a cable lateral vibration testing apparatus 200 according to a second embodiment of the present invention. 6 is a side view of the cable lateral vibration testing apparatus 200 shown in Fig. Fig. 7 is a plan view of the cable lateral vibration testing apparatus 200 shown in Fig.

5 to 7, the cable lateral vibration testing apparatus 200 according to the present embodiment includes a body frame 210, a driving motor 220, a circular plate 230, a third driving bar 240, Vibrating bar 250 and load cell 260. [

The present embodiment differs from the above-described embodiments in the construction of the drive motor 220, the circular plate 230 and the third drive bar 240 that reciprocate the vibrating bar 250, The vibration bar 250 and the load cell 260 are similar to the body frame 110, the vibrating bar 150 and the load cell 160 of the above-described embodiment, and a detailed description thereof will be omitted.

The driving motor 220 may be mounted on one side of the body frame 210 to provide a driving force for reciprocating movement of the vibration bar 250.

The circular plate 230 is rotatably connected to the driving motor 220 and mounted on the body frame 210 so as to be adjacent to the driving motor 220. At this time, the circular plate 230 can be rotatably coupled to the body frame 210 through the rotation shaft 221. The rotating shaft 231 may be connected to the driving motor 220 and rotated according to the operation of the driving motor 220. For example, the rotation shaft 231 may be connected to the drive motor 220 by a connection belt 221, and the rotation shaft 231 and the circular plate 230 may be rotated as the drive motor 220 is operated .

In addition, the circular plate 230 may be provided with a second engagement pin 232 for fastening the third drive bar 240. At this time, the second engagement pin 232 may be formed at a position spaced apart from the rotation axis 231, which is the rotation center of the circular plate 230, in the radial direction.

The third driving bar 240 is disposed on the lower side of the circular plate 230 and can be pivotably connected to the body frame 210 through the third rotating shaft 241. In addition, a second slot 242 may be formed in the third driving bar 240 along the longitudinal direction. The second slot hole 242 may be coupled to the second coupling pin 232 of the circular plate 230 and the second coupling pin 232 may be coupled to the second slot hole 242, And can be formed to be slidable along the slot hole 242.

The lower end of the third driving bar 240 may be fastened to the intermediate portion of the vibrating bar 250 through a hinge coupling or the like.

Hereinafter, the operation of the cable lateral vibration testing apparatus 200 according to the second embodiment of the present invention will be described with reference to the drawings.

7 is an operational state diagram of the cable lateral vibration testing apparatus shown in Fig.

Referring to FIG. 7, the tester firstly mounts the cable C to the cable lateral vibration testing apparatus 200. This has been described in the above-mentioned embodiment, and a detailed description thereof will be omitted.

When the cable C is mounted on the cable lateral vibration testing apparatus 200, the tester drives the driving motor 220. When the driving motor 220 is operated, the driving force is transmitted to the rotating shaft 231 through the connecting belt 221, thereby rotating the rotating shaft 231 and the circular plate 230. When the circular plate 230 is rotated, the second engagement pin 232 provided on the circular plate 230 forms a circular movement path having a predetermined radius.

The third driving bar 240 slides along the second slot 242 of the third driving bar 240 so that the third driving bar 240 rotates about the third rotating shaft 241 In the left-right direction. The vibrating bar 250 fastened to the lower end of the third driving bar 240 is reciprocated right and left in conjunction with the third driving bar 240 as described above.

As described above, in the cable lateral vibration testing apparatuses 100 and 200 according to the embodiments of the present invention, the cable C reciprocates in the transverse direction, ) Can be easily tested and evaluated. Accordingly, the cable lateral vibration testing apparatuses 100 and 200 according to the embodiments of the present invention can easily analyze and evaluate the durability change or the degree of damage of the cable C with respect to periodic lateral vibration generated by wind load or the like.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, many modifications and changes may be made by those skilled in the art without departing from the spirit and scope of the invention as defined in the appended claims. The present invention can be variously modified and changed by those skilled in the art, and it is also within the scope of the present invention.

100, 200: Cable lateral vibration testing device
110: Body frame 210: Body frame
120: drive cylinder 220: drive motor
130: first drive bar 230: circular plate
140: second driving bar 240: third driving bar
150: vibrating bar 250: vibrating bar
160: load cell 260: load cell

Claims (6)

Body frame;
A driving cylinder mounted on the body frame;
A first driving bar which is fastened to the body frame through a first coaxial shaft, has an upper end fastened to the driving cylinder and has a first slot hole formed along a longitudinal direction thereof;
A second driving bar coupled to the body frame through a second pivot shaft formed on a lower side of the first pivot shaft and having a first coupling pin that is slidably coupled to the first slot hole at an upper end thereof; And
And the cable is transversely reciprocated by being disposed at a lower portion of the body frame so that both ends are supported by a pair of pivotal bars and an intermediate portion is fastened to the lower end of the second driving bar, And a vibration bar having a hole.
The method according to claim 1,
Wherein the body frame is formed with a pair of cable fixing portions for fixing both ends of the cable.
The method according to claim 1,
And a load cell provided at one side of the vibration bar for measuring a reaction force of the cable when the vibration bar is reciprocated.
Body frame;
A driving motor mounted on the body frame;
A circular plate coupled to the body frame via a rotary shaft connected to the driving motor and having a second coupling pin at a position spaced apart from the rotary shaft by a predetermined distance in the radial direction;
A third driving bar coupled to the body frame through a third coaxial shaft and having a second slotted hole formed along a longitudinal direction thereof and the second coupling pin coupled to the second slotted hole so as to be slidable; And
And the cable is transversely reciprocated by being disposed at a lower portion of the body frame so that both ends are supported by a pair of pivotal bars and an intermediate portion is fastened to the lower end of the third driving bar, And a vibration bar having a hole.
The method of claim 4,
Wherein the body frame is formed with a pair of cable fixing portions for fixing both ends of the cable.
The method of claim 4,
And a load cell provided at one side of the vibration bar for measuring a reaction force of the cable when the vibration bar is reciprocated.

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