KR102153479B1 - A temporary gripping device for indirect hot-line work - Google Patents

Abstract

The present invention relates to a temporary hanging device for live wire work of an overhead distribution line, and the present invention provides a temporary hanging device 100 capable of temporarily mounting a bypass cable 170 during indirect live wire work on an overhead power distribution line, The temporary hanging device 100 is coupled to a body portion 110 having a certain length and an upper end of the body portion 110 to secure an insulation distance from the power line 180, and clamps the power line 180 A pair of upper clamp plates that are fastened and assembled in a clamp structure facing up and down using the hinge bolt 123 that is fitted into the clamp hinge holes 121c and 122c in the central part to be held and fixed in a structure as a hinge drive point, and A clamp part 120 comprising a lower clamp plate 121 and 122 and having a first elastic member 150 disposed between the upper clamp plate and the lower clamp plate 121 and 122 to perform elastic restoration, and the bypass cable 170 ), the hinge bolt 133 fitted into the clamping hinge holes 131c and 132c in the central part so that it can be temporarily mounted by gripping the cable head 171 connected to the power line 180 in a direction perpendicular to the power line 180 as a hinge driving point. It consists of a pair of clamping clamp plates 131 and 132 that are fastened and assembled in a clamping structure opposite to each other, and a clamping with a second elastic member 160 that is disposed between the pair of clamping clamp plates 131 and 132 to perform elastic restoration. A rotating member 140 having a part 130 and a clamping fastening part 141 in a form in which a part of the outer circumferential surface is left symmetrically left and right while being fitted to the lower part of the body part 110 and the entire outer circumferential surface is opened. Including, the clamping portion 130 is assembled horizontally in the clamping fastening portion 141 and is fastened to the body portion 110 by a hinge bolt 133 acting as a hinge driving point of the clamping portion 130 , The clamping part 130 is fastened and assembled to be rotatable along the rotating member 140 that is rotatably fastened and assembled at an arbitrary angle α at the bottom of the body part 110.

Description

A temporary gripping device for indirect hot-line work on overhead distribution lines

The present invention relates to a temporary hanging device for live wire work of an overhead distribution line, and more particularly, when an operator boarding an insulating bucket for an indirect live wire work proceeds to apply and cut a working wire with an insulating stick and a basic tool in a non-contact state of the power line, It relates to a temporary hanging device for live wire work of an overhead distribution line that can temporarily mount a cable head so that it is much easier for an operator to move it to fix it to a power line or a temporary mount in the process of constructing a bypass cable.

In general, it is desirable to perform maintenance work on distribution lines in a state that maintains the stability of power supply and minimizes power outages to improve the reliability of power supply to power consumers.

In order to increase the reliability of the power supply as described above, work must be performed in a state where the voltage is alive, that is, a live wire, and most of the current work is performed in the state of a live wire.

The live wire work of such a distribution line is divided into two types, namely, direct live wire work and indirect live wire work.

In the case of direct live wire work, when the operator wears insulated gloves and contacts extra-high voltage wires with a voltage of 22.9kV, the working time is short, but there is a very high risk. There has been a lot of damage.

Accordingly, advanced foreign countries are using robots or auxiliary equipment that can directly assist or perform tasks on behalf of live lines.

In the case of the indirect live wire work, the work is performed using a tool called a hot stick. This indirect live wire work is a work using a tool and has a disadvantage of taking a lot of work time, although it is safe.

On the other hand, in the distribution work by the uninterruptible method as described above, a bypass cable is usually installed to bypass power supply, and then the distribution line is replaced and relocated, and the bypass cable is removed again to complete the distribution work. It becomes.

In other words, in the temporary transmission method using the existing bypass cable, if there are branch lines and extra-high voltage customers and facilities within the construction section, the power and load sides of the construction section are connected to the construction switchgear and the 50m long bypass cable as a number of intermediate connectors. It is a method of separating and constructing jumper wires in the construction section by working with live wires while supplying power by temporarily connecting to them.

In this way, the high-voltage distribution line bypass device temporarily connects a certain distance point of the high-voltage distribution line with a bypass (BY PASS) conductor in order to perform live work without shutting off the power during maintenance work of transformers or switchgear installed on the electric pole. After allowing high-voltage electricity to flow through the pass wire, the wire at the work site was cut off and the work was carried out.

At this time, the method of connecting the bypass wire being used is to connect one clamp of the bypass wire to the high-voltage wire first, and temporarily connect the high-voltage wire when connecting the clamp on the other side to the high-voltage wire while electricity is connected to the bypass wire. There was no hanging device, so the operator was using both hands together, so there was a risk such as electric shock.

In addition, since the bypass wire through which electricity is flowing has a considerable weight, it was struck down by its own weight and interfered with the work, as well as the corna phenomenon that occurs when it comes into contact with the wancheol installed in the electric pole. Due to this, the insulation of the conductor wire was destroyed.

In the order of installation by this uninterruptible bypass method, the ground wire is connected to the case of the construction switchgear and grounded while the switchgear for construction is installed first, and the spare length treatment bracket and cable clamp are installed at the construction switchgear installation column, and the intermediate cable and After installing the branch cable and connecting the intermediate cable, connect the branch cable, and take protective measures for the neutral and power lines, and the columnar worker installs temporary hooks, temporary support cleats and cable clamps on the power side, branch side and load side.

Then, the cable is connected to the construction switch bushing, the branch line cable is connected, the power side and the load side and the main cable line are connected, the power side and the load side construction switch are inserted, the cable is connected to the branch line power line, and the power side and the load side jumper line After cutting, the work is carried out after the grounding of the grounding for the work section before work.

The technology related to the uninterruptible bypass method as described above is disclosed as a high-voltage wire bypass device in Korean Utility Model Publication No. 1996-0002696 (Announcement on March 30, 1996).

As shown in Figs. 1 to 4, the high-voltage electric wire bypass device includes a bypass wire support for temporarily supporting the bypass cable lead on a wancheol (support) fastened to a pole, and both ends of the bypass cable lead. Among the clamps fastened to the clamp, one clamp is first caught between the hangers of the temporary hanger made of insulating resin, then the other clamp is clamped to the high-voltage wire, and then the clamp that is long caught between the hangers of the temporary hanger is placed at the nearest location. When electricity flows to the bypass cable lead and the high-voltage cable at the same time by clamping the wire, the high-voltage wire is blocked so that electricity flows only to the bypass cable lead.

Here, in the lower part of the bypass wire support 5 made of insulating resin, a "c"-type wancheol fitting part 5a to which the wancheol 9 installed on the electric pole 10 is fitted is formed, and the bypass wire support 5 ), a cable lead for bypass (1) is inserted into the "C"-type locking part (6) formed on the upper part, and a through hole (6a) with a locking groove is drilled into the "C"-type locking part (6) (7b) and the release preventing pin (7) with the locking projection (7a) is fitted through the spring (7c) to have an outward elasticity.

And, a fastening bolt (3b) having a high-voltage wire locking portion (3a) at the top of the temporary hanger (3) is screwed, and a temporary hanger (4) and a hook (4a) at the bottom of the temporary hanger (3) It is a structure in which the tightening bolt (3b) is tightened by the rotation of the ring (4a).

Here, by rotating the hook (4a) at the bottom of the temporary hook (3) made of insulating resin to adjust the distance between the hook (3a) to suit the thickness of the high voltage wire (8), the point where the bypass is required After locking the high-voltage wire (8), rotate the ring (4a) again to fix it to the high-voltage wire (8), and then to the wancheol (9) installed on the pole (10), the "bypass wire support (5)" By inserting the c"-type wancheol fitting part (5a) and fixing it with the release preventing pin (5b), and pulling the hook (7b), the locking projection (7a) of the release preventing pin (7) compresses the spring (7c). The opening 6c is opened.

At this time, the bypass cable lead (1) can be inserted into the locking portion (6) through the opening (6b). After the bypass cable lead (1) is inserted into the locking portion (6), leave the ring (7b) Bypass cable lead (1) inserted in the locking part 6 as the locking protrusion 7a of the departure prevention pin 7 moves inward by the restoration elasticity of the lower spring 7c to shield the opening 6b Silver teeth are prevented from dislodging.

The clamping part (2a) of the clamp (2) on one side of the cable lead (1) is caught by the temporary hanger (4) protruding from one side of the temporary hanger (3), and then the clamp on the other side of the bypass cable lead (1). After clamping the locking part (2a) of (2) to the high-voltage electric wire (8), remove the clamp (2) that is temporarily caught in the temporary hanger space (4) of the temporary hanger (3) and remove the locking part ( If 2a) is clamped to the high-voltage wire 8 located right next to it, the moving distance thereof is very short, so the connection work is made quickly and safely.

However, the temporary hanger 3 applied to the bypass method according to the prior art as described above is not only inconvenient in use, but also the high-voltage wire 8 by walking on the high-voltage wire locking portion 3a at the top of the temporary hanger 3. ) After clamping the cable conductor (1), the locking part (2a) of the clamp (2) on the other side of the cable conductor (1) is hooked to the temporary hanger (4) protruding from the temporary hanger (3). Since it has a simple hanging shape, there is a problem in that it cannot provide a stable working environment due to its high vibration and fluidity.

Republic of Korea Utility Model Publication No. 1996-0002696 (Announcement on March 30, 1996, name: High-voltage wire bypass device)

Accordingly, the present invention has been researched and developed to supplement and improve the inconvenience of a temporary hanger when performing a live wire operation applying a bypass method in the conventional high-voltage distribution line as described above.

As such, it is an object of the present invention to perform an indirect live wire work when an operator boarding an insulating bucket performs a bypass method with an insulating stick and a basic tool in a non-contact state of the power line to perform the work wire coating and cutting work, etc. It is to provide a temporary hanging device for live wire work of an overhead distribution line that can temporarily mount a cable head so that it is much easier for an operator to move it to fix it on a temporary mounting or power line.

In other words, an object of the present invention is the upper clamping part for gripping and fixing in the form of tongs by hanging on the power line, the lower clamping part for gripping and fixing the cable head of the bypass cable in the form of tongs, and the upper clamping part and lower clamping By providing a temporary hanging device consisting of a trunk that connects parts and secures the insulation distance of the power line, it is possible to secure sufficient insulation distance in the process of fixing the temporary hanging device to the power line when temporarily mounting the bypass cable during indirect live wire work. As a result, the operator can always maintain a safe separation distance from the power line to prevent safety accidents, and the entire component constituting the temporary hanging device uses a synthetic resin insulator to maintain insulation and reduce the fatigue level of the operator by reducing the weight of the work efficiency. It is to provide a temporary hanging device for live work of an overhead distribution line that can increase the efficiency.

The present invention for achieving the above object relates to a temporary hanging device for live wire work of an overhead distribution line, and the present invention provides a temporary hanging device capable of temporarily mounting a bypass cable during indirect live wire work on an overhead distribution line. Provided, however, that the temporary hanging device includes a body having a certain length in order to secure an insulation distance from the power line, and a clamp hinge hole at the center portion that is coupled to the upper end of the body part, and holds the power line in a clamp structure. It is composed of a pair of upper and lower clamp plates that are fastened and assembled in a clamp structure facing up and down using a hinge bolt that is fitted to the hinge bolt, and is disposed between the upper and lower clamp plates to restore elasticity. The clamping part having the first elastic member and the hinge bolt that is fitted into the clamping hinge hole in the central part to be temporarily mounted by gripping the cable head connected to the bypass cable in a direction perpendicular to the power line as a hinge driving point. It consists of a pair of clamping tongs plates that are fastened and assembled in a clamping structure so as to be opposite to each other, and a clamping part having a second elastic member that is disposed between the pair of clamping tongs plates to act to restore elasticity, and a lower part of the body It includes a rotating member having a clamping fastening part in the shape of which the entire outer circumferential surface is opened while leaving a part of the outer circumferential surface symmetrically while being fitted, and the clamping part is assembled horizontally in the clamping fastening part and acts as a hinge driving point of the clamping part. It is fastened to the body by means of a hinge bolt, and the clamping part is fastened and assembled to be rotatable along a rotating member that is rotatably fastened and assembled at an arbitrary angle α at the bottom of the body.

Here, according to the present invention, it is preferable that the body part, the clamp part, the clamping part, and the rotating member are made of an insulator made of synthetic resin.

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In addition, it is preferable that the upper and lower clamp plates are further provided with friction members that increase frictional resistance with the power line to prevent the tongs from being separated from the power line.

In this case, the friction member is preferably made of a rubber material installed on a surface of the upper and lower clamp plates to which the power line contacts.

According to the present invention, the upper clamping part for gripping and fixing in the form of tongs by hanging on the power line, the lower clamping part for gripping and fixing the cable head of the bypass cable in the form of clamps, and the upper clamping part and the lower clamping part are connected. By providing a temporary hanging device composed of a body part that secures the insulation distance of the power line, it is possible to secure a sufficient insulation distance in the process of fixing the temporary hanging device to the power line when temporarily mounting the bypass cable during indirect live wire work. There is an effect of preventing safety accidents by always maintaining a safe distance from the power line.

In addition, according to the present invention, the entire component constituting the temporary hanging device is made of an insulator made of synthetic resin, thereby reducing the fatigue of the operator by maintaining insulation and reducing weight, thereby improving work efficiency.

In addition, according to the present invention, by providing each of the first and second elastic members made of torsion coil springs to the clamping portion and the clamping portion of the temporary hanging device, the gripping force is optimally applied in the mounting process of fixing the power line and the cable head. There is an advantage in that there is no inconvenience in work by minimizing the shaking or fluidity of the temporary hanging device.

In addition, according to the present invention, in the temporary hanging device, the clamping unit is configured to be rotatable at an arbitrary angle (approximately 90° range), so that the clamping unit rotates to the left and right within a range of approximately 45° each in a situation where the operator is facing the power line. By configuring this to be possible, in a structure in which the bypass cable is mounted at a right angle to the power line, it is possible to rotate in consideration of the working environment such as the positional relationship with the power line and the temporary housing conditions, so temporary mounting and moving of the cable head is not required. There is an effect that can be performed more easily.

1 is a view showing a high-voltage wire bypass device disclosed in Utility Model Publication No. 1996-0002696 according to the prior art.
Figure 2 is a perspective view showing the bypass wire support shown in Figure 1 according to the prior art.
Figure 3 is a perspective view showing a temporary hanger for temporarily mounting the bypass cable shown in Figure 1 according to the prior art.
Figure 4 is a cross-sectional view of the temporary hanger shown in Figure 3 according to the prior art.
5 is a perspective view showing the configuration of a temporary hanging device capable of temporarily mounting a bypass cable during indirect live wire work according to a preferred embodiment of the present invention.
Figure 6 is an exploded perspective view showing the configuration of the temporary hanging device shown in Figure 5 according to a preferred embodiment of the present invention.
Figure 7 is a schematic cross-sectional view showing the configuration of the temporary hanging device shown in Figure 5 according to a preferred embodiment of the present invention.
8 is a use state diagram schematically showing a state in which a temporary hanging device according to a preferred embodiment of the present invention is attached to a power line and then temporarily mounts a bypass cable.
9 is an example usage diagram showing a state in which the clamping part of the temporary hanging device according to a preferred embodiment of the present invention is rotated at an arbitrary angle and used.
10 is a side view showing a state in which a temporary hanging device according to another embodiment of the present invention in which a friction member is installed is coupled to a power line.
11 is a side view showing a state in which a temporary hanging device according to another embodiment of the present invention in which a modified friction member is installed is coupled to a power line.

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

In this case, the thickness of the lines or the size of components shown in the accompanying drawings to describe a preferred embodiment of the present invention may be exaggerated or omitted for clarity and convenience of description, and according to the reference numerals indicated in the drawings. The terms given are terms defined in consideration of functions in the present invention and may vary according to the intention or custom of an operator or operator.

* As shown in Figures 5 to 8, the temporary hanging device 100 for live wire work of the overhead distribution line according to the present invention, largely the trunk portion 110, the clamp portion 120, the clamping portion 130, rotation It consists of a member 140.

Here, the body portion 110 is designed in a circular rod structure made of an insulator made of synthetic resin having a predetermined length in order to secure an insulation distance from the power line 180 (see FIG. 8).

Of course, in addition to the body portion 110, the clamping portion 120, the clamping portion 130, and the rotating member 140 are all made of an insulator made of synthetic resin, so that the temporary hanging device 100 is configured to maintain the overall insulation state. It is desirable to do.

In addition, a clamping portion 120 is coupled to an upper end of the body portion 110, and a clamping portion 130 is coupled to a lower end of the body portion 110 via a rotating member 140.

On the outer circumferential surface of the lower end of the body portion 110, the rotating long hole 111 for guiding the rotational state of the rotating member 140 and the rotating member 140 are prevented from being separated while holding the exact fastening position of the rotating member 140. A fitting rib 112 that can be given is formed.

The rotating long hole 111 and the fitting rib 112 will be described in more detail in the process of describing the rotating member 140 to be described later.

Since the body portion 110 is manufactured using an insulator made of a synthetic resin material, it is possible to maintain insulation and to reduce the weight of the product, thereby improving the fatigue of the operator and thus improving work efficiency.

In addition, in the process of fixing the temporary hanging device 100 to the power line 180 (refer to FIG. 8), the length of the body portion 110 is designed to ensure a sufficient insulation distance. It has the advantage of preventing safety accidents by always maintaining a safe separation distance from.

As shown in FIGS. 5 and 6, the clamp part 120 is a part that holds the power line 180 (refer to FIG. 8) with tongs and fixes the temporary hanging device 100 to the power line 180. It is arranged and coupled to the top of the body portion 110 in the form of tongs having an elastic member 150.

That is, in the clamp part 120, a pair of upper and lower clamp plates 121 and 122 are arranged to face up and down, and clamp hinge holes 121c and 122c respectively formed in the central portions of the upper and lower clamp plates 121 and 122 ) Is fitted to the clamp hinge holes (121c, 122c) to rotate the clamp, and a nut (124) is fastened to one end of the hinge bolt (123) so that the hinge bolt The clamp structure can be implemented by fixing 123 so as not to deviate from the clamp hinge holes 121c and 122c engaged with each other.

Each of the upper and lower clamp plates 121 and 122 has clamping parts 121b and 122b and clamping parts 121a and 122a formed at both portions, centering on the clamping hinge holes 121c and 122c at the center, respectively. Has.

It is preferable that the outer circumferential surfaces of the claw handles 121b and 122b are provided with anti-slip irregularities so that when the operator holds it, it does not slip well and can smoothly apply a pressing force.

Likewise, the inner circumferential surface of the clamping portions 121a and 122a is a portion that serves to hold the high voltage power line 180 in the overhead distribution line to hang the temporary hanging device 100, and the high voltage power line 180 When gripping, it is preferable that wedge-shaped irregularities found in ordinary tongs are formed so that it can be firmly gripped.

In this case, it is natural that the clamping portions 121a and 122a are designed in a long curved structure to have a sufficient length to have a sufficient gripping surface and a gripping space in consideration of the thickness of the power line 180 through which high voltage flows.

In addition, the upper clamp plate 121 has a shape structure that can be fastened by engaging with the upper end of the body portion 110 through a fastening support portion 121d, and the lower clamp plate 122 has a fastening support portion 121d It has a structure in which the clamps can be rotated by the hinge bolts 123 as described above in a state of being engaged with the lower part of the upper clamp plate 121 by passing through the fastening through hole 121e formed in.

In particular, between the upper and lower clamp plates 121 and 122, when the operator held the clamp handle portions 121b and 122b and opened the clamp gripping portions 121a and 122a to perform the clamping action, it was compressed and the operator's pressing force was released. At this time, a first elastic member 150 is interposed to provide an elastic restoring force so that the clamping portions 121a and 122a are elastically restored to their initial state to perform a gripping action.

The first elastic member 150 is a type of torsion coil spring, and consists of an elastic support 152 having elastic force by having both free ends open at an acute angle to each other around the central coil winding part 151.

Therefore, when the first elastic member 150 is fastened and assembled so that the upper and lower clamp plates 121 and 122 can be rotated by the hinge bolt 123, the coil winding part 151 is inserted into the hinge bolt 123. The elastic support portions 152, which are inserted and fixed, forming both ends of the first elastic member 150, are closely fixed to the inner surfaces of the claw handles 121b and 122b of the upper and lower claw plates 121 and 122, respectively, so that the operator When holding and pressing the claw handles 121b and 122b, the elastic support portion 152 of the first elastic member 150 is elastically compressed around the coil winding portion 151 to have an elastic restoring force.

On the other hand, the clamping part 130 is fastened and assembled at the lower end of the body part 110 via the rotating member 140 to temporarily fix the cable head 171 of the bypass cable 170 as shown in FIG. 8. As a function of mounting with, like the tongs 120, it has a structure consisting of a pair of clamping tongs plates 131 and 132 that open in the form of tongs.

Here, the clamping tongs plates 131 and 132 are a pair of clamping gripping parts 131a and 132a and a pair of clamping gripping parts 131b formed to be opposite to each other of the pair of clamping gripping parts 131a and 132a. , 132b) to be fastened and assembled to be implemented with tongs, and the pair of clamping gripping parts 131a and 132a is a body part 110 so that the cable head 171 of the bypass cable 170 can be vertically mounted. Arranged through the rotating member 140 horizontally with respect to the ground at the lower end of the body 110 in a direction having a gripping surface facing 90° with the gripping surface of the gripping parts 121a and 122a located at the top of) Assembled, the pair of clamping handles (131b, 132b) opposite to the opposite sides of the pair of clamping grips (131a, 132a) have a structure that is fastened and assembled by horizontally penetrating the rotating member (140). .

In this way, the clamping tongs plates 131 and 132 constituting the clamping part 130 have a pair of clamping gripping parts 131a and 132a and the clamping gripping parts 131b and 132b engaged with each other to face each other, and the clamping hinge holes 131c, 132c) is formed at both ends to implement a clamp structure.

At this time, the clamping gripping portions 131a and 132a are designed to have a gripping surface of a cylindrical structure in accordance with the shape of the cable head 171 formed in a cylindrical shape to temporarily mount the cable head 171, and thus It is preferable that the inner circumferential surfaces of the clamping gripping portions 131a and 132a to be formed are formed with wedge-shaped irregularities that can be found in ordinary tongs so that when the cable head 171 is gripped, it can be firmly gripped.

The clamping handle parts 131b and 132b are handle parts that hold and press the clamping gripping parts 131a and 132a in the form of tongs so that they can be opened and closed, and the clamping grips 121b of the clamping part 120 described above are Similarly to 122b), anti-slip irregularities are formed on the outer circumferential surfaces of the clamping handles 131b and 132b so that they do not slip well and smoothly apply a pressing force when held by an operator.

In addition, in the clamping hinge holes (131c, 132c) formed in the central portion of the clamping clamp plates (131, 132), the operator holds the clamping handles (131b, 132b) and opens the clamping gripping parts (131a, 132a) to perform a clamping action. The second elastic member 160 provides an elastic restoring force so that the clamping gripping portions 131a and 132a are elastically restored to their initial state when the pressing force of the operator is released, and the hinge bolt 133 is compressed. ) Is fitted on top.

And, the second elastic member 160, like the first elastic member 150, is a type of torsion coil spring, and both free ends are opened at an acute angle to each other around the central coil winding part 161 It consists of an elastic support 162 having.

Therefore, when the second elastic member 160 is fastened and assembled so that the clamping clamp plates 131 and 132 can be rotated by the hinge bolt 133, the coil winding part 161 is inserted into the hinge bolt 133. The elastic support portions 162 that are fixed and form both ends of the second elastic member 160 are in close contact with the inner surfaces of the clamping handles 131b and 132b of the clamping tongs plates 131 and 132, respectively, so that the operator can use the clamping handles ( When holding and pressing the 131b and 132b, the elastic support portion 162 of the second elastic member 160 is elastically compressed around the coil winding portion 161 to have an elastic restoring force.

As such, the clamping part 130 is horizontally assembled and fixed to the lower end of the body part 110 via the rotation member 140, and the rotation member 140 attaches the clamping part 130 to the body part 110 It plays a role of supporting and fixing at the bottom.

The rotation member 140 has a cylindrical structure having a hole corresponding to the outer diameter diameter of the body portion 110 so that it can be fitted to the lower outer peripheral surface of the body portion 110, the overall The outer diameter is formed relatively larger than the outer diameter of the body portion 110.

At this time, the rotating member 140 is provided with a clamping fastening part 141 in a shape in which a part of the outer circumferential surface is left symmetrically left and right and the entire outer circumferential surface is opened so that the clamping part 130 can be horizontally inserted and assembled.

That is, the rotating member 140 is fastened and assembled to the lower end of the body portion 110, and the clamping portion 130 is horizontal to the lower end of the body portion 110 through the clamping fastening portion 141 of the rotating member 140. At this time, the hinge bolt 133 is inserted through the lower opening surface of the rotating member 140 and penetrated through the clamping hinge holes 131c and 132c of the clamping tongs plates 131 and 132. As it is fastened to the part 110, the clamping part 130 is fastened and assembled to the lower end of the body part 110.

The hinge bolt 133 acts as a hinge driving point when the clamping part 130 acts as a forceps, as well as the rotating member 140 while rotating a spiral according to a helical bolt coupling when rotating the rotating member 140 to be described later. It is fastened and assembled to be rotatable according to the direction of rotation.

In addition, a plurality of fitting ribs 112 capable of inducing fitting coupling of the rotating member 140 are formed at predetermined intervals on the outer peripheral surface of the lower end of the body portion 110 as described above, and this fitting rib ( A fitting rib guide 142 is formed on the inner circumferential surface of the rotating member 140 to face 112.

Therefore, when the rotating member 140 is fastened to the lower end of the body portion 110, the fitting rib guide 142 of the rotating member 140 is matched to the fitting rib 112 of the body portion 110 and fitted. When this is done, it is possible to hold the correct fastening position of the rotating member 140 and fasten it.

Further, the rotating member 140 may be firmly fixed to the lower end of the body portion 110, but in a preferred embodiment of the present invention, as shown in FIG. 9, the rotating member 140 is the body portion 110 It is fastened and assembled so that it can be rotated (or rotated) at an arbitrary angle (α, for example, it can be rotated in a range of approximately 90° as a whole, since it can be rotated approximately by 45° to the left and right) at the lower part of ).

To this end, as shown in FIG. 5, a rotating long hole 111 capable of guiding the rotation (or rotation) of the rotating member 140 is formed on the outer circumferential surface of the lower end of the body 110, and The rotating long hole 111 is fitted with a rotating pin 144 fitted through a pin hole 143 formed on the outer circumferential surface of the rotating member 140.

That is, the rotating long hole 111 is the body portion 110 by a length that can limit the rotation range of the rotating member 140 rotating at an arbitrary angle α to about 90° as exemplarily described above. It is preferably formed on the outer circumferential surface, and the rotation pin 144 guides the rotation state while moving along the rotation hole 111 of the body portion 110 when the rotation member 140 rotates.

The reason why the clamping unit 130 is designed to be rotatable in a range of approximately 90° from the bottom of the body 110 through the rotation of the rotating member 140 is, in a situation where the operator is facing the power line, the clamping unit ( By configuring the 130) to be rotated within a range of approximately 45° to each of the left and right, the bypass cable 170 is mounted perpendicularly to the power line 180 due to the mounting structure of the temporary hanging device 100 according to the present invention. It is easier to temporarily mount and move the cable head 171 by implementing the clamping unit 130 to be rotatable in consideration of the working environment such as the power line 180 and the positional relationship and temporary mounting conditions in the state of having the structure It is intended to be able to perform well.

Meanwhile, a friction member may be further provided on the tongs.

The friction member serves to prevent separation of the tongs from the power line by increasing frictional resistance between the power line and the tongs when the tongs are coupled to the power line.

A temporary hanging device in which the friction member is installed is presented as another embodiment of the present invention and will be described in detail with reference to FIGS. 10 and 11.

Prior to the description, reference numerals are assigned to the same components as in the preferred embodiment, and detailed descriptions will be omitted.

As shown in FIG. 10, friction members 190 are respectively installed on the inner surface of the tongs 120.

The inner surface of the clamp unit 120 refers to a surface in which the power line 180 is engaged with the upper clamp plate 121 and the lower clamp plate 122 and comes into contact.

Since the friction members 190 are installed on each of the upper and lower clamp plates 121 and 122, the power line 180 is in close contact between the friction members 190.

As described above, by installing the friction member 190 on the clamp part 120, the gap between the upper clamp plate 121 and the lower clamp plate 122 is reduced by the thickness of the friction member 190, so that the power line 180 and the clamp It is possible to increase the bonding force of the unit 120.

In addition, since the frictional resistance between the clamp unit 120 and the power line 180 can be increased, the coupling force between the clamp unit 120 and the power line 180 can be further maximized, so that the clamp unit 120 in the power line 180 It is possible to prevent the slipping or separation of the tongs 120 from the power line 180.

The material of the friction member 190 is not specifically limited, but is preferably made of a rubber material.

Meanwhile, the friction member may be provided in a configuration capable of covering the upper clamp plate 121 and the lower clamp plate 122.

That is, as shown in FIG. 11, the friction member 191 may be provided in a tube shape and then fitted to each of the upper clamp plate 121 and the lower clamp plate 122.

This means that unlike the friction member 190 shown in FIG. 10, it is a detachable configuration.

Since the friction member 191 is provided to be detachable from the clamp unit 120 as described above, the operator can perform the installation work of the friction member 191 in consideration of the diameter of the power line 180 and the surrounding work environment. .

The tube-shaped friction member 191 is also preferably a rubber material, but is not limited to a rubber material.

In the above, preferred embodiments of the present invention have been illustrated and described, but the present invention is not limited to the above-described embodiments, and is not departing from the gist of the present invention claimed in the claims. Anyone with knowledge can implement various modifications, of course, and such modifications will fall within the scope of the claimed claims.

100: temporary hanging device 110: body
111: rotating long hole 112: fitting rib
120: clamp part 121: upper clamp plate
122: lower clamp plate 121a, 122a: clamp holding portion
121b, 122b: claw handle 121c, 122c: hinge hole
121d: fastening support part 121e: fastening through hole
123,134: hinge bolt 124: nut
130: clamping part 131,132: clamping clamp plate
131a, 132a: clamping gripping part 131b, 132b: clamping gripping part
131c, 132c: clamping hinge hole 140: rotating member
141: clamping fastening part 142: fitting rib guide
143: guide pin 144: rotation guide pin
150: first elastic member 151,161: coil winding part
152,162: elastic support 160: second elastic member
170: bypass cable 171: cable head
180: power line 190: friction member
191: tube-shaped friction member

Claims (5)

In the temporary hanging device 100 that can temporarily mount the bypass cable 170 during indirect live wire work on an overhead distribution line,
The temporary hanging device 100 includes a body portion 110 having a predetermined length in order to secure an insulation distance from the power line 180,
A hinge bolt 123 that is coupled to the upper end of the body part 110 and is fitted into the clamping hinge holes 121c and 122c in the central part to hold and fix the power line 180 in a clamp structure as a hinge driving point The first elastic member is composed of a pair of upper and lower clamp plates 121 and 122 that are fastened and assembled in a clamp structure so as to face up and down, and is disposed between the upper and lower clamp plates 121 and 122 to perform elastic restoration. The clamp part 120 with 150, and
Hinge bolts 133 fitted into the clamping hinge holes 131c and 132c at the central portion so that the cable head 171 connected to the bypass cable 170 is gripped in a direction perpendicular to the power line 180 and temporarily mounted. ) As a hinge driving point and consisting of a pair of clamping tongs plates 131 and 132 that are fastened and assembled in a clamping structure opposite to the left and right, and a second elastic member that is disposed between a pair of clamping tongs plates 131 and 132 to act for elastic restoration A clamping portion 130 with 160,
It includes a rotating member 140 having a clamping fastening part 141 in a form in which a part of the outer circumferential surface is left symmetrically left and right while being fitted to the lower end of the body 110 and the entire outer circumferential surface is opened,
The clamping part 130 is fitted horizontally into the clamping fastening part 141 and is fastened to the body part 110 by a hinge bolt 133 acting as a hinge driving point of the clamping part 130,
The clamping part 130 is a live wire of an overhead distribution line, characterized in that it is fastened and assembled to be rotatable along a rotating member 140 that is rotatably fastened and assembled at an arbitrary angle α from the bottom of the body 110 Temporary hanging device for work. The method of claim 1,
The body portion 110, the clamping portion 120, the clamping portion 130, and the rotating member 140 is a temporary hanging device for live wire work of an overhead distribution line, characterized in that made of an insulator made of synthetic resin.
delete The method according to claim 1 or 2,
An overhead distribution line, characterized in that the upper clamp plate 121 and the lower clamp plate 122 are further provided with a friction member 190 that increases frictional resistance with the power line to prevent the tongs 120 from being separated from the power line. Temporary hanging device for live work of The method of claim 4,
The friction member 190 is a temporary hanging device for live wire work of an overhead distribution line, characterized in that the rubber material installed on the surface of the upper clamp plate 121 and the lower clamp plate (122) in contact with the power line.

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