KR101271746B1 - Bracket of connecting for electric power cable in underground - Google Patents

Abstract

PURPOSE: A distribution-use underground wire connection bracket is provided to prevent electricity leakage by automatically maintaining constant height differences regarding a water level such as rain water. CONSTITUTION: A ball screw (220) is connected to a driving shaft of a driving motor (210). A rail is arranged by specific length in the driving motor. The upper part of an elevating block (230) is movably installed. The lower part of the elevating block is screw-engaged with the ball screw. A controller (400) is arranged on one side of the driving motor.

Description

Underground cable connecting bracket for power distribution {Bracket of connecting for electric power cable in underground}

The present invention relates to a underground cable connection bracket for distribution, and more particularly, the plate supporting the underground cable is automatically elevated according to the water level change of water flowing into the underground tunnel, so that the underground cable is always spaced apart from the water surface at a certain height. The present invention relates to underground cable connection brackets for power distribution, which can be safely maintained and managed more stably by removing corrosive components caused by contact with water.

In general, power plants such as thermal power plants, hydro power plants, and nuclear power plants generate about 20,000 V of electricity, which is then boosted to super high voltage (154 KV or 345 KV) suitable for power transmission to the primary substation through an ultra high voltage line. do.

The primary substation drops the distributed high voltage electricity to 22.9 KV, which is a special high voltage, and transmits or distributes it to general consumers along a secondary substation or distribution line located near a large capacity consumer.

Electricity distributed from the primary substation or secondary substation is transmitted or distributed to the receiving facility of each customer through the transmission and distribution system consisting of overhead distribution line and underground distribution line. It is used for industrial, home use, etc.

Transmission and distribution generally use the method of using the ground and the ground. Among these, the transmission and distribution method using the underground is a method of installing underground pipes underground so that underground cables for transmitting or distributing special high pressure are arranged in underground pipes.

The underground pipe is installed in a basement of a certain depth, and when a plurality of underground pipes are installed, the underground pipes are kept at a constant distance from other adjacent underground pipes.

On the other hand, in the underground method, concrete tunnels are embedded in the ground to allow underground cables to pass through, while the shelves are installed inside the tunnel to allow the underground cables to be fixed to the shelves and concrete or synthetic resin protection pipes. There is a way to bury underground cables to pass through the inside of the protection tube.

Although all of these methods allow underground cables to be separated and protected from external contact, a large amount of water may be introduced at the same time in case of heavy rainfall or flooding.

Sudden inflow of water into the interior, if the quantity is too large, the underground wire is in contact with the water, and in severe cases there is a risk of leakage in the submerged water.

To this end, various technologies such as Patent Registration No. 1039358 (2011.05.31.name: underground cable connection bracket for power distribution) have been used to secure the underground cable more safely and cope with the water level change.

However, the patent of the prior art only raises the plate as the water level rises, so the spring cannot be returned to its original position because it is not contracted by itself, so it must be forcedly lowered by the worker. It is not easy to descend the operation, which leads to difficult maintenance.

In addition, the lower end of the spring with the support for supporting the plate is always submerged in water, so there is a problem that the service life of the spring is reduced while being exposed to corrosion and shortening the service life.

Patent Document Patent Registration No. 1039358 (2011.05.31.) Name: Underground Cable Connection Bracket for Power Distribution

Accordingly, the present invention is to solve the above problems, the present invention is to ensure that the ground wire is fixed to the ground wire in accordance with the level of flowing water flowing into the underground tunnel so as to move up and down at a constant height from the water surface at all times Its main purpose is to provide underground cable connection brackets for power distribution to enable safe and convenient management of underground cables.

In addition, the present invention is to provide a underground cable connection bracket for distribution to minimize the maintenance costs, such as repair and replacement by excluding the configuration that can be corroded in contact with the water flowing into the underground tunnel. have.

The present invention for achieving the above object, the drive motor is installed in the middle width position from the upper surface of the underground tunnel; A ball screw connected to the drive shaft of the drive motor and provided downward to a predetermined height; The upper end is movable to correspond to each other in a direction corresponding to each other along the rail provided with a predetermined length to both sides of the drive motor, the lower end is rotatably fixed to the mutually corresponding outer peripheral surface of the lifting block screwed to the ball screw Lifting drive unit consisting of a pair of links,

Plates that are fixed to the upper and lower circumferential surface of each of the elevating block is fixed to the lower end of the fixed shaft is fixed to both sides to be moved up and down by driving the elevating drive unit; A buoyancy body provided with a lifting shaft which is vertically penetrated through the center of the plate and a buoyancy hole fixed to a lower end of the lifting shaft; A limit switch installed at an upper side and a lower side with a predetermined height difference from the plate to one side of the lifting shaft to drive the driving motor by contact with an operation formed on an outer circumferential surface of the lifting shaft; Lifting table is provided as a fixed body consisting of a fixed tube which is fixed on the plate to penetrate the underground wire, a buffer spring is installed on the inner surface of the fixed tube, the gripper is fixed to the end of the buffer spring to surround the outer peripheral surface of the underground wire ,

A controller provided at one side of the driving motor to control the driving of the driving motor in response to an operation signal of the upper and lower limit switches;

It includes a configuration.

The underground cable connection bracket of the present invention according to the above configuration is to maintain a constant height difference with the flow water while the plate that automatically secures the underground wire according to the flow height of rainwater flowing into the underground tunnel, etc. While the wire is safely protected from running water, there is an effect of preventing the occurrence of a short circuit and at the same time providing a convenience that can be more easily and efficiently maintained.

1 is a side view showing a preferred embodiment of the underground cable connecting bracket for distribution according to the present invention,
Figure 2 is an enlarged cross-sectional perspective view of the main portion illustrating a configuration in which a link is connected to the rail of the underground cable connection bracket for power distribution according to the present invention;
Figure 3 is an enlarged cross-sectional perspective view of the main portion illustrating a configuration in which the link is coupled to the lifting block of the underground cable connection bracket for distribution according to the present invention,
4 to 7 is an operation diagram showing the operation of the underground cable connection bracket for power distribution according to the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment according to the present invention.

Before describing the present invention, the following specific structural or functional descriptions are merely illustrative for the purpose of describing an embodiment according to the concept of the present invention, and embodiments according to the concept of the present invention may be embodied in various forms, And should not be construed as limited to the embodiments described herein.

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

However, it should be understood that the embodiments according to the concept of the present invention are not intended to limit the present invention to specific modes of operation, but include all modifications, equivalents and alternatives falling within the spirit and scope of the present invention.

1 is a side view showing a preferred embodiment of the underground cable connecting bracket for distribution according to the present invention.

As shown, the underground cable connection bracket for power distribution according to the present invention comprises a lifting drive unit 200, a lifting platform 300, and a controller 400.

The lift driving unit 200 is configured as a drive motor 210, a ball screw 220, a lift block 230, and a link 240 again.

The drive motor 210 is configured to be fixed at a width middle position on the upper surface of the underground tunnel 100.

The drive motor 210 is preferably such that the drive shaft (not shown) is installed downward, to use a reverse rotation servo motor, the outside is covered by the case 211 so as to be protected from moisture.

The ball screw 220 is connected to the drive shaft of the drive motor 210 in a coaxial line to penetrate the case 211 is a configuration that is provided with a vertical length downward.

Therefore, the ball screw 220 is provided to rotate in conjunction with the drive of the drive motor 210.

Lifting block 230 is a screw is coupled to the ball screw 220 is a configuration that is provided to be able to lift a certain height during the rotation of the ball screw 220.

The lifting block 230 is provided with a link 240 to prevent the ball screw 220 from rotating at the same time.

The link 240 is configured to be symmetrical to each other on both sides of the ball screw 220, the upper end of the link 240 to be fixed to the upper surface of the underground tunnel 100 on both sides of the drive motor 210. It is inserted into the rail 241 provided as a predetermined length is connected to be movable in the longitudinal direction.

To this end, it is more preferable to allow the roller 242 to be rotatably fixed to the upper end of the link 240 so that the rolling movement is possible while preventing the departure from the rail 241 as shown in FIG. 2.

In addition, the lower end of the link 240, as shown in Figure 3 so as to be rotatably fixed in the vertical direction on both sides corresponding to each other of the lifting block 230 coupled to the ball screw 220.

And the lifting platform 300 of the present invention is configured to be provided as a plate 310, buoyancy body 320, limit switch 330 and the fixed body 340 again.

The plate 310 is fixed to the lower end of the fixed portion of the link 240 is fixed to the lifting block 230, respectively, the lower end is supported by a fixed shaft 311 to be fixed to both sides of the plate 310, respectively Configuration.

Since the plate 310 is integrally connected to the elevating block 230 by the fixed shaft 311 of both sides, when the elevating block 230 ascends, the plate 310 is also interlocked at the same time to elevate a certain height.

The buoyancy body 320 is a configuration consisting of the lifting shaft 321 and the buoyancy sphere 322 again, the lifting shaft 321 is a configuration that is provided to be elevated while vertically penetrating the center of the plate 310, the upper main surface There is an operation section 3210 to protrude to one side.

The operation section 3210 may be formed in a shape protruding from the lifting shaft 321, but may also be formed in a ring shape that is tightly inserted into the operation section 3210.

The buoyancy sphere 322 is a spherical configuration that is coupled to the lower end of the lifting shaft 321, the inside of the buoyancy sphere 322 is to be formed in the empty space so that it can float on the surface by buoyancy.

Therefore, the buoyancy sphere 322 is to lift the lifting shaft 321 fixedly coupled to the upper end in accordance with the change in the water level.

The limit switch 330 is configured to have a predetermined height difference from the plate 310 on one side of the lifting shaft 321, and for this purpose, the bracket 310 is installed at a predetermined height on the plate 310. Make sure that each of the lower end and the upper end of the fixed mounting.

The limit switch 330 is positioned between the upper limit switch 331 and the lower limit switch 332 between the operation of the lifting shaft 321, the direction 3110 is switched by the contact between the operation between the operation 3210 By intermittently driving the drive motor 210.

That is, the limit switch 330 operates the drive motor 210 to operate the upper limit switch 331 to raise the plate 310 to a predetermined height, and the lower limit switch 332 to operate the driving motor ( 210 is lowered to a certain height.

The fixed body 340 is again provided as a fixed tube 341, the buffer spring 342 and the gripper 343, and is a means for fixing the underground wire 350.

Fixing tube 341 is provided on the upper surface of the plate 310 is fixedly installed on the upper side in both directions.

The shock absorbing spring 342 is configured to be radially installed at regular intervals along the inner surface of the fixing pipe 341, and is a shape of surrounding the outer circumferential surface of the underground wire 350 while being fixed to the inner end of the shock absorbing spring 342. 343).

Therefore, the gripper 343 may be provided in a shape that is attached to each of the shock absorbing springs 342 installed in the fixed tube 341, so that the gripper 343 is provided in an arc shape of a predetermined radius that is simultaneously attached to two or more shock absorbing springs 342. You may.

On the other hand, the controller 400 of the present invention is a control unit which receives the signal of the limit switch 330, the driving of the driving motor 210, that is, driving in the forward and reverse direction immediately after driving for a predetermined time to stop the driving.

The controller 400 is accommodated in the case 211 together with the drive motor 210 while being attached to the upper surface of the underground tunnel 100 on one side of the drive motor 210 to the external force from the outside. To be protected.

With reference to the accompanying drawings for the action using the underground cable connection bracket for distribution of the present invention according to the above configuration will be described in more detail.

4 to 7 is an operation diagram showing the operation of the underground cable connection bracket for power distribution according to the present invention.

In the present invention, the underground wire 350 is fixed by the fixing body 340 provided on the upper portion of the plate 310.

After opening the upper part of the fixed tube 341 in the fixed body 340 in both directions to allow the underground wire 350 to be seated on the grabper 343, and then close the opened upper part to be coupled using a coupling means (not shown). do.

At this time, each gripper (343) is provided with a buffer spring 342 between the fixed tube 341, so that even if an external force is applied to the underground wire 350 to be buffered by the buffer spring 342, a more stable coupling state Is maintained.

In the underground tunnel 100, the buoyancy opening 322 of the buoyancy body 320 is placed on the bottom surface, and when water flows into the underground tunnel 100, the buoyancy opening 322 according to the water level as shown in FIG. Will rise.

When the rising height of the buoyancy sphere 332 is greater than or equal to the change of the water level, the lifting shaft 321 connected to the buoyancy sphere 332 rises, and the operation period 3210 formed on the lifting shaft 321 rises.

The operation 3210 moves up and down according to the water level change between the upper and lower limit switches 331 and 332.

When the water level is changed by a predetermined height or more and the operation 3210 operates the limit switch 330, the controller 400 recognizes this and drives the driving motor 210.

When the ball screw 220 is rotated by the driving motor 210, the lifting block 230 which is axially coupled to the ball screw 220 is raised or lowered according to the rotation direction of the ball screw 220.

The link 240 at both sides of the lifting block 230 ascends the upper end portion in the longitudinal direction along the rail 241 to support the lifting block 230 to safely lift along the ball screw 220.

In this case, since the plate 310 is fixedly connected by the fixed shaft 311 at the lower portion of the elevating block 230, the elevating block 230 also simultaneously interlocks with the elevating block 230.

The lifting height caused by the operation of the limit switch 330 is such that the driving of the drive motor 210 is stopped at such a level that it does not contact the opposite limit switches 331 and 332.

Therefore, the water is introduced into the underground tunnel 100, the water level is increased and the predetermined height is increased by the operation of the upper limit switch 331, but when the water level is continuously increased, the upper limit switch 331 is operated on several times As shown in FIG. 5, the plate 310 is raised several times.

Even if the water level is reduced, as shown in FIGS. 6 and 7, the operating period 3210 of the lifting shaft 321 lowers the plate 310 to a predetermined height while operating the lower limit switch 332. If the lower limit switch 332 is also lowered several times while the lower limit switch 332 is also turned on several times.

As such, the plate 310 is raised to a certain height, and the water level does not rise any more. The state is maintained in that state. When the water level is lowered while the water level is lowered, the plate 310 is automatically lowered along the water level. It is possible to provide convenience that the administrator does not have to participate in the lifting operation of the plate 310.

In particular, the present invention is to omit the configuration to be immersed in or in contact with the water to prevent the corrosion of the configuration due to contact with water in advance to enable economical maintenance.

100: underground tunnel 200: elevating drive unit
210: drive motor 220: ball screw
230: lifting block 240: link
300: platform 310: plate
320: buoyant body 330: limit switch
340: fixed body 350: underground wire
400: controller

Claims (1)

A drive motor 210 installed at an intermediate width position on the upper surface of the underground tunnel 100; A ball screw 220 connected to the drive shaft of the drive motor 210 and provided downward to a predetermined height; The lifting block 230 is screwed to the ball screw 220, the upper end is installed to be movable in the direction corresponding to each other along the rail 241 provided to both sides of the drive motor 210 in a predetermined length. Lifting drive unit 200, consisting of a pair of links 240 are rotatably fixed to the mutually corresponding outer peripheral surface of the,

A plate 310 fixed to the upper and lower circumferential surfaces of the elevating block 230 so that upper and lower ends thereof are fixed to both sides of the fixed shaft 311 so as to be movable upward and downward by driving of the elevating drive unit 200; A buoyancy body provided with a lifting shaft 321 provided to be vertically penetrating through the center of the plate 310 and a buoyancy hole 322 fixed to a lower end of the lifting shaft 321; The drive motor is installed on the plate 310 by the contact between the operation 3210 formed on the outer circumferential surface of the elevating shaft 321 is installed on the upper and lower with a predetermined height difference to one side of the elevating shaft 321 A limit switch 330 for driving 210; It is fixed to the end of the fixing spring 341 and the buffer spring 342 is installed on the inner surface of the fixing tube 341 and the fixed tube 341 is fixed on the plate 310 so that the underground wire 350 is penetrated Platform 300, which is provided as a fixed body 340 consisting of a gripper 343 surrounding the outer circumferential surface of the underground wire 350,

A controller 400 provided at one side of the driving motor 210 to control the driving of the driving motor 210 by receiving the operation signals of the upper and lower limit switches 331 and 332;
Underground wiring connection bracket made of a configuration comprising a.

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