KR101106670B1 - Power cable damage prevention switch of lift for construction - Google Patents

Abstract

The present invention relates to a power cable breakage prevention switch of a construction lift, comprising: a hollow tube made of silicon material coupled to a circumference of a power cable drawn out of the lift; First and second caps coupled to both ends of the tube; A pair of connection terminals coupled to the second cap, one end of which is located inside the tube, the other end of which is located outside the tube, and the other end of which is connected to the drive of the lift; It is provided to flow freely according to gravity in the inside of the tube, and the power cable is made up of a plurality of connecting terminals connecting the two connecting terminals to block the lifting power of the lift when the tube is inverted by the descending lift.

Therefore, since the plurality of connection terminals are moved while moving according to the position of the tube, the overall configuration is very simple and thus very easy to manufacture, and the manufacturing cost is greatly reduced and easy to maintain.

Power Cable, Cable Guide, Breakage Prevention Switch, Tube, Connection Terminal, Connection Terminal

Description

Power cable damage prevention switch of lift for construction

The present invention relates to a power cable breakage prevention switch of a construction lift, and more particularly, to a power cable breakage prevention switch of a construction lift in which the entire configuration is very simple and two connection terminals are reliably connected when a power cable is broken. will be.

On the construction site of a building such as an apartment, a lift 3 is installed to transport a manpower or construction material as shown in Figs. In order to install this lift 3, the mast 1 is fixed to one side of a building, and the mast 1 is provided so that the lift 3 may raise and lower.

The lift 3 is provided with a driving device (not shown) such that the lift 3 is elevated along the mast 1, and a power cable 5 is connected to the driving device to supply power. One end of the power cable 5 is connected to a power supply source, and the other end is connected to a driving device of the lift 3. The cable wheel 6 is connected to the middle portion of the power cable 5 so that the power cable 5 is wound and the middle portion of the power cable 5 is elevated along the lift 3 when the lift 3 is lifted. .

On the other hand, the mast 1 is provided with a cable guide (2) to guide the power cable (5) connected to the lift (3). Therefore, the power cable 5 connected to the lift 3 is lowered and then lifted together with the lift 3 in a state located inside the cable guide 2. The cable guide (2) is a guide body (2a) of the C-shaped metal material, one end is fixed to one end of the guide body (2a) and the other end is located at the other end of the guide body (2a) guide body (2a) It consists of a rubber pad (2b) provided between both ends of the. Therefore, the cable protection pipe 4 is moved up and down while pushing the rubber pad 2b of the cable guide 2 in the state where the power cable 5 is located inside the cable guide 2 when the lift 3 is lifted.

On the other hand, when the power cable 5 is shaken severely due to external factors such as rain or the like, it often occurs when the inner side of the cable guide 2 as shown in FIG. In this state, when the lift 3 descends, the power cable 5 deviates out of the cable guide 2, while the cable protection tube 4 connects the power cable 5 to the inside of the cable guide 2. Try to pull down. Therefore, as shown in FIG. 3, the power cable 5 is severely bent.

Even though the power cable 5 is bent as described above, when the lift 3 continues to descend and drags the power cable 5 downward, the load is broken and an excessive load acts on the bent portion.

An object of the present invention for solving the above problems, the construction of the lift to stop the lowering of the lift immediately when a break occurs in a portion of the power cable as the lift is lowered in the state that the power cable is separated from the cable guide To provide a power cable breakage prevention switch.

Another object of the present invention is to provide a power cable breakage prevention switch of a construction lift in which the overall configuration is very simple.

It is still another object of the present invention to provide a power cable breakage prevention switch of a construction lift such that two connection terminals are reliably connected when a power cable is bent.

Power cable breakage prevention switch of the construction lift of the present invention for achieving the above object, the hollow tube of silicon material coupled to the periphery of the power cable drawn out from the lift; A first cap coupled to one open end of the tube; A second cap coupled to the other open end of the tube; A pair of connection terminals coupled to the second cap, one end of which is located inside the tube, the other end of which is located outside the tube, and the other end of which is connected to the drive of the lift; It is provided to flow freely according to gravity in the interior of the tube, when the power cable is bent by the lift to be lowered when the tube is turned over a plurality of connecting terminals connecting the two connecting terminals to block the lifting power of the lift; It features.

Another characteristic of the power cable breakage prevention switch of the construction lift of the present invention is that the connection terminals are formed such that the cross section is formed to have the same area and the pair of ends located inside the tube are separated from each other toward the end side thereof. Are guided between a pair of connection terminals.

Another characteristic of the power cable breakage preventing device of the construction lift of the present invention is that the connecting terminals have a diameter larger than the cross section of the connecting terminal at the pair of ends located inside the tube so that the connection area with the connecting terminals is expanded. Hemispherical connections are formed.

Another characteristic of the power cable breakage preventing device of the construction lift of the present invention is that the connection terminal includes a pair of connecting parts, one end of which is located inside the tube and the other of which is located outside the tube, connected to an electric wire, It is formed integrally with the connecting parts, and the corresponding two ends are formed to gradually open toward the end side so that the connecting terminals are guided between the two connecting terminals. It consists of a pair of connecting portions formed.

Another feature of the power cable breakage prevention switch of the construction lift of the present invention, the connection terminal is made of a spherical shape with a minimum of frictional resistance so as to move smoothly inside the tube according to the position of the tube.

In the present invention as described above, when the lift is lowered in the state in which the power cable is separated from the cable guide, when a part of the power cable is bent, the switch of the present invention is turned over, whereby the connection terminals fall, so that the two connections The terminals are connected, and when the two terminals are connected, the lifting movement of the lift is stopped. Therefore, when the power cable is bent, the descending operation of the lift is stopped immediately, so that the power cable is no longer dragged downward, and thus the power cable is prevented from being broken by preventing an excessive load on the bent portion.

The present invention comprises a tube made of silicon, a first cap and a second cap at both ends of the tube, two connection terminals, and connection terminals connecting the connection terminals. The present invention is a structure that is operated while moving the plurality of connection terminals according to the position of the tube, the overall configuration is very very simple and accordingly very easy to manufacture, manufacturing cost is greatly reduced and easy to maintain.

In addition, the present invention is formed so that both ends of the two connecting terminals are separated from each other toward the end. Therefore, when the tube is inverted, the falling connection terminals are brought into contact with the ends of the two connecting terminals and then gathered inside the two connecting terminals along the inclined surface thereof. Therefore, since the connecting terminals are concentrated at the inner center side of the connecting terminals, the connection state between the two connecting terminals becomes more secure, and the lift is thus reliably braked.

Specific features and advantages of the present invention will become more apparent from the following description taken in conjunction with the accompanying drawings.

1 is a partial cross-sectional side view showing a state in which a conventional construction lift is installed on a mast, and FIG. 2 is a schematic perspective view showing a state in which a power cable connected to the lift is separated from a cable guide, and FIG. 3 is a cable guide of a power cable. This is a schematic partial perspective view showing the state in which the power cable is bent with the lift lowered from the lifted state. Figure 4 is a schematic partial side view showing a state in which the construction lift of the present invention is installed on the mast, Figure 5 is a schematic perspective view showing a state in which the power cable connected to the lift is separated from the cable guide, Figure 6 is a power cable is bent A schematic partial perspective view showing a state where the breakage preventing switch of the present invention is operated. Figure 7 is an exploded perspective view of the breakage prevention switch of the present invention, Figure 8 and Figure 9 is an exploded cross-sectional view of Figure 7 and the combined cross-sectional view of Figure 8, Figure 10 is a breakage prevention switch is reversed as the power cable is bent. It is a schematic cross-sectional view showing the state in which the connection terminals are connected to the connection terminals.

As shown in FIG. 4, the construction lift 13 is provided with a driving device (not shown) to lift the lift 13 along the mast 11, and the power cable 15 is provided to supply power to the driving device. It is connected. One end of the power cable 15 is connected to a power supply source, and the other end is connected to a driving device of the lift 13. The cable wheel 16 is connected to the middle portion of the power cable 15 so that the power cable 15 is wound and the middle portion of the power cable 15 is elevated along the lift 13 when the lift 13 is lifted. . The power cable 15 via the cable wheel 16 is connected to the drive of the lift 13 via a cable sheath 14.

The mast 11 is provided with a cable guide 12 to guide the power cable 15 connected to the lift 13. The power cable 15 connected to the lift 13 is lowered and then lifted together with the lift 13 in a state located inside the cable guide 12. The cable guide 12 is a C-shaped metal guide body 12a, one end is fixed to one end of the guide body 12a and the other end is located at the other end of the guide body 12a, the guide body 12a It consists of a rubber pad (12b) provided between both ends of the). In the state where the power cable 15 is positioned inside the cable guide 12 when the lift 13 is lifted, the cable protection pipe 14 is lifted while pushing the rubber pad 12b of the cable guide 12 up and down.

The power cable 15 under the cable protection pipe 14 is provided with a breakage prevention switch 20 which is a feature of the present invention.

The breakage prevention switch 20 includes a tube 21, a first cap 22 and a second cap 23, connection terminals 24, and connection terminals 26. The tube 21 is coupled to the periphery of the power cable 15 drawn out from the lift 13 and made of silicon, and has a hollow shape with both ends open. Since the tube 21 is made of a silicone material, there is an advantage that the tube 21 is elastically deformed and restored even when an external impact or bending occurs.

The first cap and the second cap 23 are respectively coupled to both ends of the tube 21 to seal both ends of the tube 21. The joint portion of the tube 21, the first cap 22, and the second cap 23 is coated with silicon to maintain watertightness. In addition, the circumference of the tube 21, the first cap 22, and the second cap 23 is wound with a tape 27 together with the circumference of the power cable 15 to more securely maintain the watertight inside the tube 21. , The breakage prevention switch 20 is fixed to the periphery of the power cable (15).

The connection terminals 24 are coupled to the second cap 23, one end of which is located inside the tube 21, and the other end of which is located outside the tube 21. Wires 25 are connected to the other ends of the connection terminals 24 so as to be connected to the driving device of the lift 13. While the two connecting terminals 24 are separated, the lift 13 is lowered while power is continuously supplied to the driving device of the lift 13, but when the two connecting terminals 24 are connected to each other, the driving device of the lift 13 is powered. As a result, the lowering operation of the lift 13 is stopped.

The connection terminals 26 are provided to flow freely in the interior of the tube 21 according to gravity, and when the tube 21 is inverted while the power cable 15 is bent by the lift 13 which is lowered, the lift 13 is provided. The two connection terminals 24 are connected to block the lift power of the vehicle.

These connection terminals 26 are made of any one material of gold, silver, copper, and copper having excellent electrical conductivity. The connection terminals 26 are formed in a cylindrical shape, and when the breakage prevention switch 20 is inverted and the connection terminals 26 are transferred to the connection terminals 24, the connection terminals 26 are in contact with the connection terminals 24 to connect the two connection terminals 24. Energize.

The breakage prevention switch 20 of the present invention is fixed with a tape 27 around the power cable 15 under the cable protection tube 14.

In this state, if the power cable 15 is severely shaken due to external factors such as rain or the like, it is often caused to deviate from the inside of the cable guide 12 as shown in FIG. 5. When the lift 13 is lowered in this state, the power cable 15 is out of the cable guide 12, while the cable protection tube 14 moves the power cable 15 to the inside of the cable guide 12. Try to pull down. Thus, as shown in FIG. 6, the power cable 15 is severely bent.

When the power cable 15 is bent in this way, the breakage prevention switch 20 of the present invention mounted on the bent portion is turned upside down. When the breakage prevention switch 20 is turned over as shown in FIG. 10, the connection terminals 26 are connected to the connection terminals 24 while falling toward the connection terminals 24. Since four connection terminals 26 are provided in the tube 21, the two connection terminals 24 are energized while being connected by four connection terminals 26. When the two connection terminals 24 are connected to each other, the power supply to the driving device of the lift 13 is cut off, and thus the lowering of the lift 13 is stopped. Therefore, the power cable 15 in a bent state is no longer broken because it is no longer subjected to pressure.

The power cable breakage prevention switch of the construction lift of the present invention has the following advantages.

First, when a break occurs in a part of the power cable 15 as the lift 13 descends while the power cable 15 is separated from the cable guide 12, the breakage prevention switch 20 of the present invention is turned over. As a result, the connection terminals 26 fall, thereby connecting the two connection terminals 24. When the two connection terminals 24 are connected, the lifting movement of the lift 13 is stopped.

Therefore, when the power cable 15 is bent, the lowering operation of the lift 13 is stopped immediately, so that the bent power cable 15 is no longer dragged downward, and thus the power cable is prevented from applying excessive load to the bent part. The problem that 15 is broken is prevented.

Secondly, the present invention provides a tube 21 made of silicon, a first cap 22 and a second cap 23 at both ends of the tube 21, two connection terminals 24, and connection terminals 24. It consists of connecting terminals 26 for connection.

The present invention is a structure that is operated while moving according to the position of the plurality of connection terminals 26, the overall configuration is very simple and thus very easy to manufacture as well as greatly reduced manufacturing cost and maintenance Is simple.

Third, the tube 21 of the present invention is made of a silicon material. As such, since the tube 21 is made of a silicon material, there is an advantage that the tube 21 is elastically deformed and restored even when an external impact or bending occurs.

Fig. 11 is a schematic perspective view showing another embodiment of the connection terminals 34, wherein the connection terminals 34 are formed so that the cross section has the same area and the pair of ends located inside the tube 21 are toward the end side thereof. It is formed so as to be separated from each other gradually. Therefore, when the breakage prevention switch 20 is turned over and the connection terminals 26 fall, the damage prevention switch 20 is guided along the inclined surfaces of the connection terminals 34 and guided between the pair of connection terminals 34.

Therefore, since the connection terminals 26 are concentrated at the inner center side of the connection terminals 34, the connection state of the two connection terminals 34 becomes more secure, and the lift 13 is thus reliably braked.

12 is a schematic perspective view showing another embodiment of the connection terminals 44, wherein the connection terminals 44 are a pair of pairs located inside the tube 21 so that the connection area with the connection terminals 26 is expanded. The hemispherical connection part 44a of diameter larger than the cross section of the connection terminal 44 is formed in the end part.

The connection terminals 44 of the present invention are maximized by the hemispherical connection portion 44a formed at the end thereof, and thus connection with the connection terminals 26 is more secured.

FIG. 13 is a schematic perspective view showing another embodiment of the connection terminals 54, which are composed of a connection portion 54a and a connection portion 54b. The connecting portion 54a has one end located inside the tube 21 and the other end located outside the tube 21 so as to be connected to the wire 25. The connecting portion 54b is formed integrally with the connecting portions 54a inside the tube 21 and formed so that the corresponding two ends gradually open toward the ends so that the connecting terminals 26 are guided between the two connecting terminals 54. And the outer peripheral surface of the connecting terminal 26 of the cylindrical form is formed in a plate shape so that the two parts are in line contact along the longitudinal direction.

Since the connection terminal 54 of the present invention is formed such that a pair of ends of the connection portion 54b open toward each other toward the end side thereof, the damage prevention switch 20 is turned upside down so that the connection terminals 26 fall, and the connection terminal 54 falls. The guides are guided between the pair of connection terminals 54 while being guided along the inclined surfaces of the terminals. Therefore, since the connection terminals 26 are concentrated at the inner center side of the connection terminals 54, the connection state of the two connection terminals 54 is more secure.

In addition, since the connection portion 54b of the connection terminal 54 is formed in a plate shape, the cylindrical connection terminals 26 are formed in a plate shape when the connection terminals 26 of the cylindrical shape fall in any direction and fall between the two connection portions 54b. It is placed in parallel along the two connections 54b while striking the surface of the connections 54b on the top. Therefore, in the cylindrical connecting terminal 26, two portions on both sides are in line contact with the connecting portion 54b.

Therefore, since the two parts of the connection terminal 26 are in line contact with the connection terminal 54, the connection state is assured, and the lift 13 is reliably braked accordingly.

FIG. 14 is a schematic cross-sectional view showing another embodiment of the connection terminals 66. The connection terminals 66 have a frictional resistance minimized to smoothly move inside the tube 21 according to the position of the tube 21. As shown in FIG. It is made of a shape.

The spherical connection terminals 66 roll better than the cylindrical connection terminals 66 and minimize the frictional resistance. Therefore, the spherical connecting terminals 66 are smoothly moved in the tube 21 when the tube 21 is inverted and quickly connected to the connection terminals 24 so that the lift 13 is stopped in the shortest time.

1 is a partial cross-sectional view showing a state in which a conventional construction lift is installed on a mast

Figure 2 is a schematic perspective view showing a state in which the power cable connected to the lift is separated from the cable guide

3 is a schematic partial perspective view showing a state in which the power cable is bent and the power cable is bent while the power cable is separated from the cable guide;

Figure 4 is a schematic partial side view showing a state in which the construction lift of the present invention installed on the mast

5 is a schematic perspective view showing a state in which the power cable connected to the lift is separated from the cable guide

6 is a schematic partial perspective view showing a state in which the breakage prevention switch of the present invention is operated while the power cable is bent;

Figure 7 is an exploded perspective view of the breakage prevention switch of the present invention

8 is an exploded cross-sectional view of FIG.

9 is a cross-sectional view of FIG.

10 is a schematic cross-sectional view illustrating a state in which a breakage prevention switch is inverted as the power cable is bent and the connection terminals are connected to the connection terminals.

11 is a schematic perspective view showing another embodiment of the connection terminal

12 is a schematic perspective view showing another embodiment of the connection terminal

13 is a schematic perspective view showing another embodiment of the connection terminal

14 is a schematic cross-sectional view showing another embodiment of the connection terminal

* Description of the symbols for the main parts of the drawings *

11: mast 12: cable guide

12a: guide body 12b: rubber pad

13 lift 14 cable protection tube

15 power cable 16 cable wheel

20: breakage prevention switch 21: tube

22: first cap 23: second cap

24,34,44,54: connection terminal 25: electric wire

26,66 connector 44a, 54b connector

54a: connection

Claims (5)

A hollow tube 21 made of silicon coupled to a circumference of the power cable 15 drawn out from the lift 13; A first cap 22 coupled to one open end of the tube 21; A second cap 23 coupled to the other open end of the tube 21; The wire 25 is coupled to the second cap 23 and one end is located inside the tube 21, the other end is located outside the tube 21, and the other ends are connected to the driving device of the lift 13. A pair of connection terminals 24, 34, 44 and 54; The tube 21 is provided to flow freely according to gravity, and the power cable 15 is bent by the lift 13 which is lowered so that the tube 21 is turned over to block the lifting power of the lift 13. Power cable breakage prevention switch of the construction lift, characterized in that consisting of; a plurality of connection terminals (26, 66) for connecting two connection terminals (24, 34, 44, 54). The method of claim 1, wherein the connection terminal 34, The cross section is formed to have the same area, and a pair of ends positioned inside the tube 21 are formed to open toward each other toward the end side thereof, so that the connection terminals 26 are guided between the pair of connection terminals 34. Power cable break prevention switch of construction lift. The method of claim 1, wherein the connection terminal 44, For construction, characterized in that the hemispherical connecting portion 44a having a diameter larger than the cross section of the connecting terminal 44 is formed at the pair of ends located inside the tube 21 so that the connection area with the connecting terminals 26 is expanded. Power cable break switch of lift. The method of claim 1, wherein the connection terminal 54, A pair of connecting portions 54a, one end of which is located inside the tube 21 and the other end of which is located outside the tube 21 and connected to the electric wire 25, It is formed integrally with the connecting portion (54a) in the tube 21 and the corresponding two ends are formed so as to gradually open toward the end side so that the connecting terminal 26 is guided between the two connecting terminal 54, the cylindrical connecting terminal (26) The power cable breakage prevention switch of a construction lift, characterized in that the outer circumferential surface is composed of a pair of connecting portions (54b) formed in a plate shape such that the two parts are in line contact along the longitudinal direction. The method of claim 1, wherein the connection terminals 66, Power cable breakage prevention switch of the construction lift, characterized in that made of a spherical shape with a minimum of frictional resistance so as to move smoothly in the tube 21 according to the position of the tube (21).

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