KR100901876B1 - Tunnel for underground distribution line prevention - Google Patents

Abstract

A protective pipe for an underground distribution line is provided to prevent a lifetime reduction and an electric accident by preventing leakage of a concrete structure. A concrete structure is laid on an underground. A guide rail(200) is horizontally installed in a top part of the concrete structure. A shelf(300) is installed inside the concrete structure in order to support an underground line(C). A transfer device(400) includes a pinion(413), a bracket(410), and a driving motor(420). The pinion is engaged with a rack of the guide rail. The driving motor drives the pinion. The transfer device is moved into a width direction of the concrete structure according to the guide rail. A control unit controls an operation of the driving motor according to a control signal of a first input unit or a second input unit. The first input unit is installed in an inner wall of a right side of the concrete structure. The second input unit is installed in an inner wall of a left side of the concrete structure. The first input unit and the second input unit control the operation of the driving motor.

Description

Tunnel for Underground Distribution Line Prevention

The present invention relates to underground cable protection tube, and more particularly, to an underground cable protection tube that the shelf is installed to be movable.

In general, Korea's overhead cable undergrounding began in 1973 by relocating the underground cableway complexed from Hyo Auto to Gwanghwamun, relocating the main street along the main road to the back alley and supplying nearby customers from low-voltage cables using low voltage cables. It is a trend that continues to expand.

For reference, underground construction works can be divided into direct sales, pipeline, electric power and bridges.

Of these, the electric power old-fashioned is also called culvert or dynamic diagram, as shown in Figure 1, inside the concrete structure (100 ') made by connecting the concrete structure (100') of about 2 meters horizontally and vertically in the ground like a pipe The shelves 300 'are fixedly arranged perpendicularly to the bottom surface in close contact with the left and right sides of the walls, and underground wires C are installed on the shelves 300'. Meanwhile, a passage P is provided between the shelf 300 'and the shelf 300' to allow an operator to pass.

By the way, in such electric power old construction, since the shelf 300 'is simply fixed to form a layer on both side walls of the inside of the concrete structure 100, when the leakage occurs in the concrete structure 100', the shelf 300 is installed on both side walls. There was a problem that the water moves along ') to wet the underground wire (C), and if this situation is continuously repeated, there is a problem that the oxidation of the underground wire (C) is accelerated and the life is shortened. In addition, when the underground wire (C) is wet, it is not easy to dry due to its characteristics installed in an enclosed space in the basement, there was also a problem inconvenient work.

In addition, the oxidized underground wire (C) has a problem that the occurrence rate of electrical accidents such as power failure or electric shock is increased because the possibility that the current flowing through the oxidized portion is exposed.

In addition, conventionally, since the shelf 300 'is firmly fixed to both side walls of the concrete structure 100', when an earthquake or vibration occurs, the shelf 300 'is not only separated from the wall but also bent or cut. Breakage of 300 'was caused.

The present invention has been made to solve the above problems, an object of the present invention is to provide a underground wire protection tube for preventing the life of the underground wire due to leakage of concrete structures and electrical accidents in advance.

The present invention for solving the above problems, having a pair of seating grooves which are opposed to each other to face each other on the inner wall, forming a rectangular tubular shape, embedded in the ground; A guide rack having a rack with guide grooves formed at both ends thereof, and a hanger that is elastically installed at both ends of the guide handle Japanese body with a handle that is movably inserted into the guide groove of the guide cage and protrudes outward. A guide rail screwed to the handle of the hanger and having a fastening member for fixing the hanger to the guide leg body, both ends of the hanger being inserted into a seating groove formed in the concrete structure, and horizontally inclined in the width direction of the concrete structure; A shelf built in the concrete structure to support the underground wires; A pinion movably engaged with the rack, a bracket for movably fixing the pinion to the rack, and a drive motor mounted on the bracket to force the pinion to be driven, and the shelf is reciprocated along the guide rail in the width direction of the concrete structure. And a conveying device to make; A control unit which receives a control signal from the first input unit to the second input unit and controls the operation of the driving motor; A first input unit installed at a right inner wall of the concrete structure to control an operation of the driving motor; Installed on the left inner wall surface of the concrete structure, it is composed of a second input unit for controlling the operation of the drive motor.

The present invention is configured as described above, it is expected that the effect of optimizing the size of the concrete structure while reducing the shortening the service life of the underground wire even if the leak occurs in the concrete structure.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings.

Figure 2 is a partially exploded perspective view of the underground wire protection tube according to the present invention, Figure 3 is a view for explaining the operating state of the underground wire protection tube according to the present invention, Figure 4 is a drive motor, a control unit, As a block diagram of the first input unit and the second input unit, the underground wire protection tube according to the present invention, the concrete structure 100, the guide rail 200, the shelf 300, the transfer device 400, the control unit 500 , The first input unit 600 and the second input unit 700.

The concrete structure 100 is to protect the underground wire (C) buried in the ground, to form a rectangular tubular shape with a hollow formed in the longitudinal direction therein, a pair of seating grooves 110 on both inner walls They are installed to face each other at regular distances. On the other hand, the seating groove 110 of the concrete structure 100 is a place where the friction with the hanger 220, the high-strength reinforcing member 120, such as steel in the seating groove 110 to insert durability insert molding do. Here, the reinforcing member 120 is formed with a groove 121 on which the hanger 220 is seated, similarly to the mounting groove 110.

 On the other hand, if the guide rail 200 itself is insert-molded to be formed in a batch at a predetermined distance to the concrete structure 100, the guide rail 200 may be formed even in unnecessary positions. As an example, the guide rail 200 may be formed at a position where the manhole is formed, that is, below the manhole. In this case, the movement of the worker may be inconvenient, and the removal of the guide rail 200 may be required. . In addition, when a defect occurs in the guide rail 200, there is a problem that the entire concrete structure 100 must be replaced. Therefore, the guide rail 200 should be able to be properly installed or dismantled according to the site situation.

Therefore, the guide rail 200 according to the present invention is composed of a guide rail body 210, the hanger 220 and the fastening member 230 to be assembled in the field, the width direction in the upper portion of the concrete structure 100 It is fixed to be installed horizontally. Here, the guide leg body 210 is a rectangular bar shorter than the width of the concrete structure 100. In addition, the upper portion of the guide leg body 210 is formed with a predetermined portion of the rack 211 in both directions on the basis of the center, the insertion grooves 212 are formed in both ends of the guide leg body 210. The guide groove 213 extends to have a width smaller than the width of the insertion groove 212 below the insertion groove 212. On the other hand, the hanger 220 is provided with a handle 221 is formed to protrude to the outside and the thread formed, the movable groove 212 is inserted into the insertion groove 212 so that the handle 221 is projected and exposed in the guide groove 213. do. Accordingly, when the handle 221 is pulled to one side, one end of the hanger 220 is exposed to the outside of the insertion groove 212 so that the length of the guide rail 200 is extended, so that the length of the handle 221 is longer than the width of the concrete structure 100. Thus, the guide rail 200 may be fixed to the groove 121 of the reinforcing member 120 over the hanger 220. However, when vibration or the like occurs in such a state, the latch 220 is moved to the inside of the insertion groove 212, so that at some point, the length of the guide rail 200 may be shorter than the width of the concrete structure 100. There is this. Therefore, the guide rail 200 according to the present invention is provided with a fastening member 230 screwed to the handle 221 so that the guide rail 200 can be continuously maintained in a stretched state. ) Can be fixed. That is, when the hanger 220 protrudes, while the length of the guide rail 200 is extended, the hanger 220 is fitted into the groove 121 of the reinforcing member 120, so that the guide is mounted on the upper portion of the concrete structure 100. The rail 200 is fixed. On the other hand, the guide rail 200 is a reinforced structure that is insulated because it requires a certain strength and electrical safety to safely support the underground wire (C).

In addition, the shelf 300 is installed in the concrete structure 100, and is a conventional multilayer shelf supporting the underground wire (C), the pedestal 310, the panel 320 and the separation prevention member 330 It is configured, and reciprocated in the width direction of the concrete structure 100. Here, the pedestal 310 is fitted in the binding hole 414a so that the upper surface is a flat bar shape, it is arranged horizontally around the fixing bar 414. In addition, the panel 320 is a flat plank having a width at which the upper surface of one side of the pedestal 310 is fully covered with respect to the holder 414. The detachment preventing member 330 is a kind of bolt in which the head 331 is formed to be long, and the head 331 protrudes upward from the panel 320 while fixing the panel 320 and the pedestal 310. Even if this is moved, the underground wires C are arranged to protect the underground wires C from falling down. On the other hand, if the buffer material (not shown) of the rubber material is reinforced to the head 331, even when the underground wire (C) is shaken during the movement of the shelf 300 hit the head 331 to mitigate the impact of the underground wire (C) Breakage is prevented. On the other hand, the shelf 300 according to the present invention, a plurality of pedestal 310 and the panel 320 is provided to form a multi-layered structure formed horizontally around the fixing table 414.

The transfer device 400 according to the present invention includes a bracket 410 and a drive motor 420. In addition, the bracket 410 is composed of a mounting table 411, fastening table 412, pinion 413 and the fixing table 414. Here, the seating table 411 is bent in a '∪' shape, it is arranged in a form in which the guide rail 200 is seated in the bent portion. The fastening table 412 extends downward from the center of the seating table 411. The pinion 413 is rotatably fixed to the top of the seating plate 411 so that the rotation shaft 413a is movably fixed to the guide rail 200 by engaging the rack 211. In addition, the fixing bar 414 is a bar shape, a plurality of binding holes 414a are formed spaced apart from each other by a predetermined distance, the upper end is fixed to the fastening table 412 and the shelf 300 is fixed to the bottom of the installation do. The drive motor 420 is a known motor, is installed through the fixing member (a) to the bracket 410 to forcibly drive the pinion (413). In addition, the drive shaft 421 of the drive motor 420 is fixed to the rotation shaft 413a of the pinion 413, and the drive shaft 421 is rotated to force the pinion 413 in the rotational direction of the drive shaft 421. . Therefore, when the driving motor 420 is operated, the bracket 410 is moved to one side of the width direction of the concrete structure 100 along the guide rail 200, the shelf 300 is also moved in the same direction accordingly. .

Subsequently, the control unit 500, the first input unit 600, and the second input unit 700 will be described with reference to FIG. 4.

The control unit 500 is installed in the concrete structure 100, and receives a control signal from the first input unit 600 and the second input unit 700 to control the operation of the driving motor 420. In addition, the control unit 500 is a control signal is input from the first input unit 600 and the second input unit 700 at the same time, or the first push button switch 610 and the first of the first input unit 600 When the control signal is simultaneously input from the second push button switch 620 or the control signals are simultaneously input from the third push button switch 710 and the fourth push button switch 720 of the second input unit 700, the driving motor ( 420 is set to stop.

The first input unit 600 includes a first push button switch 610 and a second push button switch 620 which are ordinary push button switches, and are installed on the right inner wall of the concrete structure 100 and are on. While in the state, the control signal is output to the control unit 500. For example, when the first push button switch 610 is pressed in the on state, the control unit 500 outputs a control signal to the drive motor 420 to rotate in the forward direction until the on state is switched to the off state. do. When the second push button switch 620 is turned on, the control signal 500 outputs a control signal for rotating the drive motor 420 in the reverse direction until the second push button switch 620 is turned on. When the first push button switch 610 and the second push button switch 620 are switched from the on state to the off state, respectively, a control signal for stopping driving of the driving motor 420 is output.

The second input unit 700 includes a third push button switch 710 and a fourth push button switch 720 which are conventional push button switches, and is installed on the left inner wall of the concrete structure 100 and is turned on. While in the state, the control signal is output to the control unit 500. For example, when the third push button switch 710 is pressed in the on state, a control signal is output to the control unit 500 such that the driving motor 420 is rotated in the reverse direction until the third push button switch 710 is turned on. . When the fourth push button switch 720 is turned on, the control signal 500 outputs a control signal for rotating the driving motor 420 in the forward direction until the fourth push button switch 720 is turned on. When the third push button switch 710 and the fourth push button switch 720 are switched from the on state to the off state, respectively, a control signal for stopping driving of the driving motor 420 is output.

Hereinafter, the operation of the underground wire protective tube according to the present invention with reference to Figures 3, 5 and 6 are as follows.

As shown in FIG. 3, the guide rail 200 is disposed in the width direction of the concrete structure 100 in which the seating groove 110 is formed, and then the locking stand 220 is exposed to the outside of the guide rail body 210. By doing so, the guide rail 200 is fixed to the concrete structure 100.

At this time, the shelf 300 is installed to be movable in both directions from the center of the guide rail (200). That is, the first push button switch 610, the second push button switch 620, the third push button switch 710, and the fourth push button switch 720 are all in an off state.

As illustrated in FIG. 5, when the worker needs to work on the right side of the shelf 300, the first push button switch 610 is switched from the off state to the on state to guide the bracket 410 to the guide rail. Move to the left direction of 200. In addition, when the bracket 410 is moved to the left side of the guide rail 200 to the maximum and the shelf 300 is as close to the left wall of the concrete structure 100 as possible, the first push button switch 610 is turned off in an on state. Switch to to stop the driving of the drive motor 420. Then, a passage P, which is a space in which the worker can move, is formed to the right side of the shelf 300. When the operation is completed, the second push button switch 620 is switched from the off state to the on state, and the bracket 410 is moved in the right direction of the guide rail 200, while the shelf 300 is a concrete structure. When placed in the center of the (100), the shelf 300 is returned to its original position by switching from the on state to the off state.

As shown in FIG. 6, when a worker needs to work on the left side of the shelf 300, the third push button switch 710 is switched from an off state to an on state, and the right side of the guide rail 200. The bracket 410 is moved in the direction. In addition, when the bracket 410 is moved to the right of the guide rail 200 to the maximum, and the shelf 300 is as close to the right wall of the concrete structure 100 as possible, the third push button switch 710 is turned on. The drive mode is switched to stop the drive motor 420. Then, a passage P, which is a space in which the worker can move, is formed on the left side of the shelf 300. When the operation is completed, the fourth push button switch 720 is switched from the off state to the on state, and the bracket 410 is moved to the left side of the guide rail 200. The shelf 300 is a concrete structure. When placed in the center of the (100), the shelf 300 is returned to its original position by switching from the on state to the off state.

On the other hand, if a control signal is simultaneously input from the first input unit 600 and the second input unit 700 to the control unit 500, a safety problem may occur. For example, when the shelf 300 is disposed in the center of the concrete structure 100, two workers do not know that the other side is on the opposite side, one worker in the off state of the first push button switch 610 When the switch is turned on and the other operator switches the third pushbutton switch 710 from the off state to the on state at the same time or at a time difference, the driving signal of the driving motor 420 simultaneously controls the control unit 500. Is entered. Alternatively, one operator switches the first push button switch 610 from the off state to the on state, and the other operator switches the third push button switch 710 from the off state to the on state at the same time. In some cases, a control signal may be input to the unit 500. Alternatively, one operator switches the fourth push button switch 720 from the off state to the on state, and the other operator switches the second push button switch 620 from the off state to the on state at the same time. In some cases, a control signal may be input to the unit 500. When the control signals for driving the driving motor 420 in the forward and reverse directions are simultaneously input from the control unit 500, the driving motor 420 is set not to be driven, and control signals having different directions at different times are simultaneously If the input is set to stop the driving of the drive motor 420 it is preferable to ensure the safety of the operator.

Underground wire protective tube according to the present invention, the guide rail 200 and the concrete structure 100 is formed separately. Therefore, since the guide rail 200 can be installed in the concrete structure 100 according to the required position of the guide rail 200 in the field, there is an advantage that can be assembled at an appropriate position arbitrarily.

Underground wire protective tube according to the present invention, when a defect occurs in the guide rail 200, there is also an advantage that can easily replace the guide rail 200.

Underground wire protection tube according to the present invention, the handle 221 is formed on the guide rail 200, there is also an advantage that can be easily installed on the guide rail 200 in the concrete structure (100).

In the underground wire protection tube according to the present invention, the shelf 300 is spaced apart from both side walls of the concrete structure 100 is disposed in the center. Therefore, even if a leak occurs in the concrete structure 100, since the water flowing along the left and right side walls does not flow into the shelf 300, the underground wire C is protected from flooding, thereby extending the service life.

In addition, the underground wire protective tube according to the present invention, the shelf 300 is arranged to be rotatable in both directions from the center of the guide rail 200 to move the shelf 300 to the opposite side of the direction to work passage (P) ) Is formed, it is not necessary to secure a separate space for the passage (P), unnecessary space is omitted, so the utilization of the space is improved, there is also the effect of optimizing the size of the concrete structure (100).

In addition, the underground wire protection tube according to the present invention, the transfer device 400, the control unit 500, the first input unit 600 and the second input unit 700, the first input unit 600 And since the shelf 300 is moved to the left side or the right side of the guide rail 200 when the second input unit 700 is operated, there is an advantage in that the formation of the passage P is convenient.

Figure 1 schematically shows a conventional underground wire protective tube,

2 is a partially exploded perspective view of the underground wire protective tube according to the present invention,

Figure 3 schematically shows the operating state of the underground wire protective tube according to the present invention,

4 is a block diagram of a drive motor, a control unit, a first input unit and a second input unit according to the present invention;

5 and 6 schematically show the operating state of the underground wire protective tube according to the present invention.

Explanation of the main parts of the accompanying drawings

100,100 ': concrete structure, 110: seating groove, 120: reinforcing member,

121: home, 200: guide rail, 210: guided Japanese body, 211: rack,

212: insertion groove, 213: guide groove, 220: hook, 221: handle,

230: fastening member, 300: shelf, 310: support, 320: panel, 330: release prevention member,

331: head, 400: feeder, 410: bracket, 411: seating table, 412: fastening table,

413: pinion, 414: fixed base, 414a: binding hole, 500: control unit,

600: first input unit, 610: first push button switch, 620: second push button switch,

700: second input unit, 710: third push button switch, 720: fourth push button switch,

a: fixing member, C: underground wire.

Claims (1)

A concrete structure 100 having a pair of seating grooves 110 installed to face each other on both inner walls so as to face each other, having a rectangular tubular shape, and embedded in the ground; A guide 222 having a rack 211 and a guide groove 213 formed at both ends thereof, and a handle 221 movably inserted into the guide groove 213 of the guide ledge 210 to protrude outward. ) Is fastened to both ends of the guide retractor body 210 so as to be elastically installed, and is screwed to the handle 221 of the hanger 220, and the hanger 220 is guide-retained body 210. Equipped with a fastening member 230 fixed to), both ends of the hanger 220 is inserted into the seating groove 110 formed in the concrete structure 100, horizontally in the width direction thereof on the top of the concrete structure 100 A guide rail 200 which is internally installed; A shelf 300 installed in the concrete structure 100 and supporting the underground wire C; A pinion 413 movably engaged with the rack 211, and a bracket 410 and a bracket 410 for movably fixing the pinion 413 to the rack 211 to force the pinion 413. A conveying apparatus 400 having a driving motor 420 for driving and reciprocating the shelf 300 in the width direction of the concrete structure 100 along the guide rail 200; A control unit 500 which receives a control signal from the first input unit 600 to the second input unit 700 and controls the operation of the driving motor 420; A first input unit 600 installed on the right inner wall of the concrete structure 100 to control the operation of the driving motor 420; It is installed on the left inner wall surface of the concrete structure 100, underground wire protection tube, characterized in that made of a second input unit 700 for controlling the operation of the drive motor (420).

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