KR102547233B1 - Protection mechanism for distribution lines in buildings - Google Patents

Abstract

The present invention relates to a power distribution line protection apparatus of a building which is made of a wire tray (100), a variable wire support unit (200), and a vibration detection unit (300) to not only easily and conveniently install power distribution lines (L), but also separately install the power distribution lines (L), which reinforces an adjacent variable wire support unit (200) by using a movable variable wire support unit (200) to stably support power distribution lines (L) combined in a bundle type, and which pressurizes and fixes the power distribution lines (L) when a vibration such as an earthquake occurs to prevent falling or the like of the power distribution lines (L).

Description

Protection mechanism for distribution lines in buildings}

The present invention relates to a power distribution line protection device for a building.

In general, in tunnels, factories, offshore structures, etc., cables (wires) of large and small diameters are arranged along ceilings and floors or walls to supply power or fluids.

In order to protect the cables (wires) arranged in this way from external force, a cable tray, which is a general wire and organizing device, is used, and the cable tray is installed on the ceiling as if suspended via a computerized bolt.

Such a cable tray is generally composed of a pair of side rails having a constant length and positioned on the left and right sides, and rungs coupled at regular intervals between the side rails.

The conventional cable tray, that is, the wire protection device as described above has no other function other than the purpose of supporting the wire being installed in a state where it is simply installed on the ceiling. As a result, there were often problems such as disconnection of wires due to sagging as well as wire breakaway.

1. Republic of Korea Patent No. 10-1987729

In the present invention, it is possible to hypothesize the distribution lines separately or without dividing the distribution lines, and the variable type support unit installed on the side rail can be freely moved and fixed, as well as the adjacent deformable type using the movable deformable wire support unit. By reinforcing the wire support unit, distribution wires bundled in a bundle can be stably supported, and in case of vibration such as an earthquake, the distribution line is pressurized and fixed to prevent the fall of the distribution line in advance. It has a purpose.

The present invention for achieving the above object,

A side rail having a clip insertion part formed at regular intervals along the length direction, spaced side by side, and having a 'c' shape when viewed from the front;

A rung disposed at the inner upper and lower parts of the side rail, and both ends facing the inner surface of the side rail and fixed to the side rail through a fastening means;

A guide bar having a 'U' shape when viewed from the plane installed on the inner surface of the side rail to be disposed between the rungs,

Both ends of a wire pressurizer coupled to the guide bar so as to be able to move up and down and disposed between the rungs;

A first spring installed between the rung and the wire pressurizing part to support the wire pressurizing part downward;

Wire tray consisting of an elastic pad installed on the underside of the wire presser:

Disposed between the side rails, both inner ends are open toward the side rails, and the outer circumferential surface is provided with a storage unit concavely recessed in an arc shape, and a support bar provided with a standing unit recessed in a direction orthogonal to the storage unit,

A cover fastened to both ends of the support bar;

A clip part detachably inserted into the clip insertion part, a connecting bar extending from the clip part and inserted through the cover, a pusher installed at the end of the connecting bar and accommodated in the support bar, extending downward from the clip part and clipping the clip part A rail connector consisting of a handle that separates from the part;

A second spring accommodated inside the support bar and elastically supporting the pusher toward the side rail;

A post that is inserted through the support bar and rotates around an elevation and vertical axis, an arc bar that is rotatably coupled to the upper end of the post and accommodated and stored in the receiving part or inserted into the standing part and supported, and is coupled to the lower end of the post and provides A variable type wire support unit consisting of a stopper that limits departure and a wire splitter consisting of a third spring coupled to the support bar to be disposed between the support bar and the stopper and elastically supporting the stopper downward:

A vibration sensor installed on the side rail to detect vibration;

A solenoid installed on the side rail to fix and release the wire presser;

and a vibration sensing unit composed of a control unit that receives a vibration sensing signal from the vibration sensing sensor and controls the operation of the solenoid so that the electric wire pressurizer can be dropped.

According to the present invention, distribution wires can be installed easily and conveniently, and distribution wires can be installed separately, and the distribution wires bundled in a bundle are stably supported by reinforcing an adjacent variable wire support unit using a movable variable wire support unit. In addition, there is an advantage in preventing the fall of the distribution line in advance by pressurizing and fixing the distribution line when vibrations such as earthquakes occur.

1 is a combined perspective view of a distribution line protection mechanism of a building according to the present invention.
Figure 2 is an exploded perspective view of Figure 1;
Figure 3 is an exploded perspective view showing a variable wire support unit separately extracted from the distribution line protection mechanism of the building according to the present invention.
Figure 4 is a cross-sectional view A - A of Figure 1;
5 is a B-B cross-sectional view of FIG. 1;
Figure 6 is a view for explaining the use state of the distribution line protection mechanism of the building according to the present invention.
7 is a view for explaining the operational effect of the distribution line protection mechanism of a building according to the present invention.

Hereinafter, it will be described in detail based on the accompanying drawings.

1 is a combined perspective view of a distribution line protection device of a building according to the present invention, FIG. 2 is an exploded perspective view of FIG. 1, and FIG. It is a perspective view, FIG. 4 is a cross-sectional view A-A of FIG. 1, and FIG. 5 is a cross-sectional view B-B of FIG.

1 to 5, the distribution line protection mechanism of a building according to the present invention is composed of a wire tray 100, a variable wire support unit 200, and a vibration sensing unit 300, and according to this, the distribution line L It can be installed easily and conveniently, and the distribution lines (L) can be separated and installed, and the distribution wires bundled in a bundle form by reinforcing the adjacent variable type wire support unit (200) using the movable variable type wire support unit (200). (L) can also be stably supported, and there is a technical feature that can prevent the fall of the distribution line (L) in advance by pressurizing and fixing the distribution line (L) when vibrations such as earthquakes occur.

1, 2, and 5, the wire tray 100 includes a side rail 110, a rung 120, a guide bar 130, a wire presser 140, a first spring 150, and As composed of an elastic pad 160, in the case of the present embodiment, it is suspended from the ceiling of a building to provide a space in which the distribution line (L) can be installed.

The side rails 110 form a 'c' shape when viewed from the front, and are spaced side by side. The lower flange (see FIGS. 1 and 2) of the side rail 110 is integrally formed with clip inserts 111 (square grooves) at regular intervals along the length direction, and the clip inserts 111 have a variable type The clip portion 231 of the wire support unit 200 is inserted and detachably coupled.

The rungs 120 are respectively disposed at upper and lower ends inside the side rail 110 . In the upper rung 120 arranged in this way, the upper surface of both ends is in close contact with the lower surface of the upper flange (see FIG. 1) of the side rail 110, and the lower surface of the lower rung 120 is in close contact with the lower flange of the side rail 110. (See Fig. 1) is in close contact with the lower surface. In addition, both ends of the upper rung 120 and the lower rung 120 are fixed to the side rail 110 via fastening means (screw bolts) while facing the inner surface of the side rail 110. Accordingly, a pair The side rail 110 and the pair of rungs 120 form an integral structure.

The guide bar 130 is a member that has a 'c' shape when viewed from above, and is installed on the inner surface of the side rail 110 to face each other so as to be disposed between the upper rung 120 and the lower rung 120. It serves to guide the elevation of the electric wire pressing sphere 140.

The electric wire pressing device 140 is a plate having a predetermined width and thickness, and is disposed between the upper rung 120 and the lower rung 120 so as to be able to move up and down. Both ends of the electric wire pressing sphere 140 are movably inserted into the guide bar 130 .

The first spring 150 is a normal coil spring, and is installed between the upper rung 120 and the wire presser 140, and serves to push the wire presser 140 toward the lower rung 120. Protrusions 121 and 141 are formed on the lower surface of the upper rung 120 and the upper surface of the wire presser 140 so that the first spring 150 can be stably installed between the upper rung 120 and the wire presser 140. It is integrally provided, and both ends of the first spring 150 are fitted and fixed to the outer circumferential surfaces of the protrusions 121 and 141, respectively.

The elastic pad 160 is a member installed on the lower surface of the wire presser 140, and serves to pressurize and fix the distribution line L by descending together with the wire presser 140. The elastic pad 160 is preferably made of rubber or silicon, which does not damage the distribution line L when the distribution line L is pressurized.

1 to 4, the variable wire support unit 200 is composed of a support bar 210, a cover 220, a rail connector 230, a second spring 240, and a wire splitter 250. As such, in the case of the present embodiment, it is detachably installed on the side rail 110 to support the distribution line (L), and serves to separate and install the distribution line (L).

The support bar 210 is a circular bar, and is disposed between the side rails 110 in the present embodiment. Both ends of the support bar 210 are open toward the side rails 110, and threads are formed on the inner circumferential surface to be screwed with the cover 220. In addition, the outer circumferential surface of the support bar 210 is integrally formed with a storage unit 211 concavely recessed along the circumferential surface so that the arc bar 252 can be inserted and accommodated, and is orthogonal to the storage unit 211. The standing portion 212 recessed concavely in the direction is integrally formed, and the arc bar 252 is inserted into the standing portion 212 to stand upright.

The cover 220 is fastened to both ends of the support bar 210 to be opened and closed.

The rail connector 230 is composed of a clip portion 231, a connecting bar 232, a pusher 233, and a handle 234, and in the present embodiment, mutually interacts with the support bar 210 via the cover 220. It is connected and is detachably coupled to the clip insert 111 to serve to interconnect the support bar 210 and the side rail 110.

The clip part 231 is a ‘c’-shaped member and is disposed on one side of the cover 220 and is detachably coupled to the clip insertion part 111 of the side rail 110.

The connection bar 232 horizontally extends from the clip part 231 toward the support bar 210 and is inserted through the center of the cover 220 to be movably installed on the cover 220 . In particular, the connection bar 232 is preferably made in a polygonal shape, which is to limit the rotation of the support bar 210.

The pusher 233 is disposed on one side with respect to the cover 220 and forms an integrated structure with the connecting bar 232 through a conventional coupling method such as thermal fusion. The pusher 233 is accommodated inside the support bar 210 and moves by the connection bar 232 when the clip portion 231 is separated from the clip insertion portion 111 and presses or controls the second spring 240. While being pushed by the restoring force of the second spring 240, the clip part 231 is pushed toward the side rail 110 via the connecting bar 232.

The handle 234 is a rod extending downward from the clip portion 231 and is used for separating the clip portion 231 from the clip insertion portion 111 .

The second spring 240 is a normal coil spring, and is accommodated inside both ends of the support bar 210, respectively, and serves to push the pusher 233 toward the side rail 110.

The wire splitter 250 is composed of a holding 251, an arc bar 252, a stopper 253, and a third spring 254, and in the case of this embodiment, it is installed in the support bar 210 so as to be able to move up and down and rotate It serves to separate and install the distribution line (L).

The post 251 is a rod, and is fitted through a portion where the receiving portion 211 and the standing portion 212 of the support bar 210 intersect. In this inserted state, the support 251 rotates about the elevation and vertical axis.

The arc bar 252 is rotatably fitted into the upper end of the support 251 . For example, when both ends of the arc bar 252 are accommodated in the receiving unit 211 in a state in which the arc bar 252 is rotated downward, the distribution line L can be constructed without the need to distinguish, and both ends of the arc bar 252 are accommodated. When inserted into the standing part 212 in a state of being rotated upward, the upper space of the support bar 210 is naturally partitioned, so that the distribution lines L can be separated and installed, so that they can be appropriately tailored to the site conditions. There are advantages to being selective.

The stopper 253 is fastened to the lower end of the post 251 and serves to limit the separation of the third spring 254 while limiting the separation of the post 251 from the support bar 210 .

The third spring 254 is a normal coil spring and is coupled to the support 251 to be disposed between the support bar 210 and the stopper 253 to hold the support 251 downward through the stopper 253. It serves to pull, and accordingly, it is possible to limit the arc bar 252 from being separated from the receiving part 211 or the standing part 212 without permission.

1, 2, and 5, the vibration sensing unit 300 is composed of a vibration sensor 310, a solenoid 320, and a controller 330, and in the case of the present embodiment, the wire tray 100 It is installed so that the wire pressurizing sphere 140 pressurizes and fixes the specific position where the distribution line L is installed when vibrations such as earthquakes occur, thereby minimizing disconnection due to disorganization and sagging of the distribution line L.

The vibration sensor 310 is installed on the side rail 110 to sense vibration such as an earthquake and outputs it to the controller 330 .

The solenoid 320 is installed to face each other on the outer surface of the side rail 110 with the wire presser 140 interposed therebetween, and serves to regulate the fall of the wire presser 140. The operation of the solenoid 320 is controlled by an operation signal of the control unit 330. For example, when the operation is controlled by the control unit 330, the rod 321 is drawn into the solenoid 320, and the wire presser 140 caught in the rod 321 is released from the jammed state. While being pushed downward by the restoring force of the spring 150, the elastic pad 160 installed on the lower surface of the wire pressing sphere 140 presses and fixes the distribution line L.

The controller 330 serves to control the operation of the solenoid 320 by receiving a vibration detection signal from the vibration detection sensor 310 .

6 is a view for explaining the use state of the distribution line protection device of a building according to the present invention, and will be described with reference to this.

As shown in FIG. 1, the variable wire support unit 200 is installed on the side rail 110 at regular intervals, and then the distribution line L is constructed.

On the other hand, when the distribution wires (L) are installed in a bundle, as the load of the distribution wires (L) is concentrated on the variable wire support unit 200, it is necessary to distribute the load applied to the variable wire support unit 200.

Therefore, as shown in FIG. 6, the above problem is solved by separating the variable wire support unit 200 from the side rail 110 and installing it adjacent to the variable wire support unit 200 requiring load distribution. You will be able to do it.

In addition, when the distribution line L is to be installed separately, the arc bar 252 of the wire splitter 250 is drawn out from the receiving part 211 (see FIG. 3), and then the standing part 212 (see FIG. 3) It is installed in, and the distribution line (L) to be divided into the installed arc bar 252 is inserted and installed.

7 is a view for explaining the operation and effect of the distribution line protection mechanism of a building according to the present invention, and will be described with reference to this.

When an earthquake occurs in the installed state as shown in FIG. 6, the vibration sensor 310 of the vibration sensing unit 300 detects vibration and outputs the detected vibration to the controller 330, which controls the vibration sensor 310. The vibration detection signal is received from the solenoid 320 to control the operation.

As shown in FIG. 7, the solenoid 320 operated by the control unit 330 pulls the drawn-out rod 321 to the inside of the solenoid 320, and The wire pressing sphere 140 is pushed downward by the restoring force of the first spring 150 as the jammed state is released, and at this time, the elastic pad 160 installed on the lower surface of the wire pressing sphere 140 also moves downward together will do

The elastic pad 160 moved downward together with the electric wire pressing sphere 140 presses and fixes the distribution line L seated on the lower rung 120, thereby limiting the movement of the distribution line L.

As such, even when vibrations such as earthquakes are applied, the distribution line L is stably pressed and fixed by the wire pressing sphere 140, the first spring 150, and the elastic pad 160. There is an advantage in being able to minimize disconnection due to disorder and sagging.

Although the present invention has been described in detail only for the specific embodiments described, it is natural for those skilled in the art that various changes and modifications can be made within the scope of the technical idea of the present invention, and it is natural that such changes and modifications fall within the scope of the appended claims.

100: wire tray 110: side rail 111: clip insertion part
120: rung 121: protrusion 130: guide bar
140: wire pressure sphere 150: first spring 160: elastic pad
200: variable wire support unit 210: support bar
211: storage unit 212: standing unit 220: cover
230: rail connector 231: clip part 232: connecting bar
233: pusher 240: second spring 250: wire splitter
251: support 252: arc bar 253: stopper
254: third spring 300: vibration detection unit 310: vibration detection sensor
320: solenoid 321: rod 330: control unit

Claims (1)

Side rails 110 having clip inserts 111 formed at regular intervals along the longitudinal direction and spaced side by side and having a 'c' shape when viewed from the front,
A rung 120 disposed at the inner upper and lower ends of the side rail 110 and fixed to the side rail 110 via a fastening means by facing the inner surface of the side rail 110 at both ends;
A guide bar 130 having a 'c' shape when viewed from the plane and installed on the inner surface of the side rail 110 to be disposed between the rungs 120,
Both ends of the wire presser 140 coupled to the guide bar 130 so as to be able to move up and down and disposed between the rungs 120;
A first spring 150 installed between the rung 120 and the wire presser 140 to support the wire presser 140 downward,
Wire tray 100 composed of an elastic pad 160 installed on the lower surface of the wire pressing sphere 140:
Disposed between the side rails 110, both inner ends are open toward the side rails 110, and the outer circumferential surface is concavely recessed in an arc shape, and the storage portion 211 is concave in a direction perpendicular to the storage portion 211. A support bar 210 provided with a standing portion 212 recessed to the right;
A cover 220 fastened to both ends of the support bar 210,
A clip portion 231 detachably inserted into the clip insertion portion 231, a connecting bar 232 extending from the clip portion 231 and inserted through the cover 220, and installed at the end of the connecting bar 232 Rail connector 230 composed of a pusher 233 accommodated in the support bar 210 and a handle 234 extending downward from the clip portion 231 to separate the clip portion 231 from the clip insertion portion 231 and,
A second spring 240 accommodated inside the support bar 210 and elastically supporting the pusher 233 toward the side rail 110;
A post 251 that is inserted through the support bar 210 and rotates around an elevating and vertical axis, is rotatably coupled to the upper end of the post 251 and is accommodated in the storage part 211 and stored or stored in the standing part 212 An arc bar 252 inserted and supported, a stopper 253 coupled to the lower end of the support bar 251 to limit departure from the support bar 210, and a support bar disposed between the support bar 210 and the stopper 253 A variable type wire support unit 200 composed of a wire splitter 250 made of a third spring 254 coupled to the 210 and elastically supporting the stopper 253 downward:
A vibration sensor 310 installed on the side rail 110 to detect vibration;
A solenoid 320 installed on the side rail 110 to fix and release the wire pressure sphere 140;
A vibration sensing unit 300 composed of a control unit 330 that receives a vibration sensing signal from the vibration sensor 310 and controls the operation of the solenoid 320 so that the wire presser 140 can fall Distribution line protection device of a building to be

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