KR102403952B1 - Bypass clamp and hot line work device having the same - Google Patents

Abstract

The present invention is made of a cylindrical shape, one side of the casing is opened so that the electric wire is installed; a motor fixedly installed inside the casing; an upper clamp connected to the motor and installed to be movable in the vertical direction inside the casing; and a lower clamp with an upper part opened so that the upper clamp can be inserted or withdrawn according to the driving of the motor, wherein the lower clamp has an electric wire pressed by the upper clamp and positioned between the lower clamps. Bypass clamp, characterized in that a connection terminal that passes through and is electrically connected to the electric wire is formed, and the current moving along the electric wire is bypassed along a bypass cable connected to the lower clamp through the connection terminal. is about

Description

BYPASS CLAMP AND HOT LINE WORK DEVICE HAVING THE SAME

The present invention relates to a bypass clamp used during live wire work.

A clamp is a generic term for parts or tools for fastening. In the electrical field, it is used as a term to refer to parts for fastening wires. The clamp is also defined as a bypass clamp because it serves to move the bypassing current.

In the electrical field, it is connected to the bypass cable and is mainly used for live wire work. Here, the live wire operation means that the current does not flow in the electric wire for troubleshooting or maintenance.

Electrical work is required when the transformer of a power pole breaks down or when maintenance of electrical facilities is required. In the past, for maintenance or repair of high-voltage lines, the construction was carried out after the lines were turned off. However, in order to prevent damage or damage due to a power outage, electricity work is currently in progress without stopping the supply of electricity.

In this case, it is possible to prevent current from flowing in the part that needs repair through live wire work. If clamps are fastened on both sides of the part that requires troubleshooting or maintenance and the bypass cable is connected to the clamped clamp, current flows through the bypass cable. In this way, it is possible to perform electrical work without powering down the line through the live line work.

Also, in the prior art, a direct live wire method was employed when performing a live wire operation. Here, the direct live wire means that a worker directly touches the high-voltage wire and installs a member necessary for the live wire operation on the high-voltage wire. In the case of direct live wire, there have been many safety accidents in which workers are electrocuted by high-voltage wires.

Due to this problem, recently, electric work is performed by employing an indirect live wire method. Here, the indirect live wire means that the operator installs a member necessary for the live wire work on the high-voltage wire using a tool such as an insulating stick.

Compared to the direct live wire method, the indirect live wire method can guarantee worker safety. However, the operator has to rotate a member such as a screw using a tool to install the clamp on the electric wire, and this process takes a considerable amount of time compared to the direct live wire method.

The prior art discloses a bypass connection clamp comprising a clamp body consisting of a clamp arm and a clamp body, a clamp jaw, a jaw adjustment member for changing the clamp jaw in a sliding manner, and a clamp body in which a cable insertion hole to be inserted through the cable is formed, Yes (Korean Patent Publication No. 10-2020-0002212). In addition, due to this structure, a structure capable of controlling the clamp with only a simple mechanical operation without fine directional control of the clamp is disclosed.

However, in order to fasten the clamp to the high voltage wire, it is still necessary to rotate the member of the clamp using an insulating stick. In general, the worker should be located below the part where live wire work is required, and should install the members for the construction in the facility located in the upper direction. For this reason, the indirect live wire operation takes a considerable amount of time.

In addition, due to the weight of the member used for the indirect live wire, there is a problem that musculoskeletal disorders occur in the neck and arms of the worker who has to handle the insulating stick for a long time.

In addition, when the clamp is fastened to the electric wire in the indirect live wire method, the clamping strength is lower than when the clamp is fastened by the operator's hand. Due to this, the bypass cable is dropped from the high-voltage line, and there is a problem that safety accidents and distribution line accidents occur due to the falling wires.

Accordingly, the bypass clamp is automatically controlled by the control unit so that the clamp is fastened to the high-voltage wire, thereby ensuring the safety of the operator during indirect live wire work, and bypassing the wire, which can shorten the time the clamp is fastened to the wire Clamp research is needed.

Korean Patent Publication No. 10-2020-0002212 (published on Aug. 8, 2020)

A first object of the present invention is to provide a structure of a bypass clamp capable of preventing an electric shock accident of an operator during an indirect live wire operation by remotely operating the bypass clamp.

A second object of the present invention is to remotely control the bypass clamp through the control unit installed in the bypass clamp, thereby reducing the time the bypass clamp is fastened to the electric wire compared to the case of manual operation of the operator. to provide structure.

A third object of the present invention is to provide a structure of a bypass clamp in which a live wire is possible without stripping the cover of the electric wire by allowing the clamp to be connected to the electric wire through the connection terminal formed in the clamp.

A fourth object of the present invention is to provide a structure of a bypass clamp capable of recycling the bypass cable by simply connecting the bypass cable to the lower clamp after cutting the bypass cable connected to the existing bypass clamp.

According to an example of the present invention, the bypass clamp having a structure capable of solving the above-described problems includes: a casing having a cylindrical shape, one side of which is open, and installed so that an electric wire passes through; a motor fixedly installed inside the casing; an upper clamp connected to the motor and installed to be movable in the vertical direction inside the casing; and a lower clamp having an upper part opened and installed so that the upper clamp can be inserted or drawn out according to the driving of the motor, wherein the lower clamp penetrates the electric wire positioned between the lower clamps to connect the electric wire and the electric wire. A connection terminal is formed to protrude, and the current moving along the electric wire can be bypassed along the bypass cable connected to the lower clamp through the connection terminal.

In addition, an elevating guide protruding toward the lower clamp is formed on the inner circumferential surface of the casing, and the elevating guide is inserted into the side surface of the lower clamp to guide the elevating guide for guiding the movement in the up and down direction. have.

In addition, the elevating guide guide is made of a form extending in the axial direction from the side surface of the upper clamp, when the upper clamp descends in the direction of the lower clamp, the elevating guide portion of the elevating guide Interfering with the inner upper end may limit the lowering of the upper clamp.

In addition, the lower clamp may include: a fixed support part configured to surround and support the upper clamp; and a connection part made of a cylindrical conductor under the fixing support part and conducting electricity with the electric wire.

In addition, the fixed support part may be made of an insulator.

In addition, an insertion hole may be formed at a lower portion of the connection part to detach the bypass cable, and the bypass cable positioned in the insertion hole and the connection terminal may be connected to each other so as to be energized.

In addition, an inner circumferential surface of the insertion hole may be screw-fastened to one end of the bypass cable.

In addition, the connection terminal may be formed in a shape such that the diameter decreases from the bottom to the top so as to pass through the electric wire.

In addition, the motor includes a shaft screw connected to the rotation shaft to transmit the rotational force of the motor, and the upper clamp may be raised or lowered by the action of the shaft screw.

In addition, the motor may have a control unit that enables rotation in one direction by an external signal.

According to another embodiment of the present invention, there is provided a live wire device having a plurality of bypass clamps having a structure capable of solving the above-described problem, comprising: a bypass cable for changing a movement direction of a current flowing in an electric wire; and a plurality of bypass clamps fastened to a plurality of portions of the electric wire, wherein the bypass clamp has a cylindrical shape, and one side thereof is opened to allow the electric wire to pass therethrough; a motor fixedly installed inside the casing; an upper clamp connected to the motor and installed to be movable in the vertical direction inside the casing; and a lower clamp having an upper part opened and installed so that the upper clamp can be inserted or drawn out according to the driving of the motor, wherein the lower clamp penetrates the electric wire positioned between the lower clamps to connect the electric wire and the electric wire. A connection terminal is formed to protrude, and the current moving along the electric wire can be bypassed along the bypass cable connected to the lower clamp through the connection terminal.

In addition, an elevating guide protruding toward the upper clamp is formed on the inner circumferential surface of the casing, and the elevating guide is inserted into the side of the upper clamp, and an elevating guide guide for guiding the movement in the up and down direction can be formed through. have.

In addition, the elevating guide guide is made of a form extending in the axial direction from the side surface of the upper clamp, when the upper clamp descends in the direction of the lower clamp, the elevating guide portion of the elevating guide Interfering with the inner upper end may limit the lowering of the upper clamp.

In addition, the lower clamp may include: a fixed support part configured to surround and support the upper clamp; and a connection part made of a cylindrical conductor under the fixing support part and conducting electricity with the electric wire.

In addition, the fixed support part may be made of an insulator.

In addition, an insertion hole may be formed at a lower portion of the connection part to detach the bypass cable, and the bypass cable positioned in the insertion hole and the connection terminal may be connected to each other so as to be energized.

In addition, an inner circumferential surface of the insertion hole may be screw-fastened to one end of the bypass cable.

In addition, the connection terminal may be formed in a shape such that the diameter decreases from the bottom to the top so as to pass through the electric wire.

In addition, the motor includes a shaft screw connected to the rotation shaft to transmit the rotational force of the motor, and the upper clamp may be raised or lowered by the action of the shaft screw.

In addition, the motor may have a control unit that enables rotation in one direction by an external signal.

The first effect of the present invention is that, since the bypass clamp is operated by the control unit, the operator does not need to directly fasten the clamp to the electric wire during live wire work. In addition, since the electric wire is automatically fastened to the clamp, it is possible to prevent an accident in which the operator is electrocuted during live wire work.

The second effect of the present invention is that when the shaft screw part connected by the shaft rotates as the motor rotates, the upper clamp goes up and down by mutual rotation with the shaft screw, so that the wire is fastened to the clamp by the operator's manual work The clamping time can shorten the fastening time.

A third effect of the present invention is that the connection terminal formed by protruding from the lower clamp penetrates the coating and is directly connected to the electric wire, so that the current can be bypassed without separately peeling the electric wire. Through this, the process of the live wire operation can be simplified, and the time required for the live wire operation can be greatly reduced.

A fourth effect of the present invention is that an insertion hole through which a bypass cable can be installed is formed in the lower clamp, so that the existing bypass cable can be recycled and used by connecting it to the bypass clamp without producing a new cable.

1 is a schematic diagram showing a state in which a live wire device having a plurality of bypass clamps is installed on an electric wire of a power pole.
Fig. 2 is a conceptual diagram showing a live wire device.
3 is a conceptual diagram illustrating a bypass clamp.
4 is a conceptual diagram illustrating a state in which the electric wire is accommodated in the electric wire accommodating space of the bypass clamp.
5 is a perspective view illustrating a motor having a shaft screw connected to the rotating shaft and an upper clamp coupled to the shaft screw.
6 is a perspective view of a motor provided with a shaft screw.
7 is a perspective view showing the upper clamp through which the elevating guide guide is formed on the side surface.
8 is a perspective view illustrating that an insertion hole through which a bypass cable can be detached is formed in a lower clamp comprising a fixing support part and a connection part.
Fig. 9 is a perspective view showing the casing of the bypass clamp.
10 is a conceptual diagram illustrating that the control unit receives a signal from the manipulation unit to remotely drive the bypass clamp.
11 is a conceptual diagram illustrating the elevation of the upper clamp along the elevation guide and the elevation guide.
12 is a perspective view showing that the electric wire is fastened and supported by the upper clamp and the lower clamp.
13 is a conceptual diagram illustrating a state in which a connection terminal is electrically connected to an electric wire by being pressed by an upper clamp.
14 is a conceptual diagram illustrating a state in which a current flows through a bypass clamp fastened to an electric wire.

Hereinafter, a bypass clamp and a live wire device including the same according to the present invention will be described in more detail with reference to the drawings. In the present specification, the same and similar reference numerals are assigned to the same and similar components even in different embodiments, and the description is replaced with the first description. As used herein, the singular expression includes the plural expression unless the context clearly dictates otherwise.

The suffixes "module" and "part" for the components used in the following description are given or mixed in consideration of the ease of writing the specification, and do not have a meaning or role distinct from each other by themselves.

In addition, in describing the embodiments disclosed in the present specification, if it is determined that detailed descriptions of related known technologies may obscure the gist of the embodiments disclosed in this specification, the detailed description thereof will be omitted. In addition, the accompanying drawings are only for easy understanding of the embodiments disclosed in this specification, and the technical idea disclosed in this specification is not limited by the accompanying drawings, and all included in the spirit and scope of the present invention It is to be understood as including modifications, equivalents and substitutions.

Terms including an ordinal number such as 1st, 2nd, etc. may be used to describe various elements, but the elements are not limited by the terms. The above terms are used only for the purpose of distinguishing one component from another.

When a component is referred to as being “connected” or “connected” to another component, it is understood that the other component may be directly connected or connected to the other component, but other components may exist in between. it should be On the other hand, when it is said that a certain element is "directly connected" or "directly connected" to another element, it should be understood that the other element does not exist in the middle.

The singular expression includes the plural expression unless the context clearly dictates otherwise.

In the present application, terms such as "comprises" or "have" are intended to designate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, and is one or more other features or numbers , it should be understood that it does not preclude the possibility of the presence or addition of steps, operations, components, parts, or combinations thereof.

1 is a schematic diagram showing a state in which a live wire device 200 having a plurality of bypass clamps 100 is installed on an electric wire 10 of a power pole 30 .

In order to supply the electricity produced by the power plant to the general household, a process of transmitting electricity through the electric wire 10 is required. There are three-phase, four-wire, and three-phase, three-wire systems for transmitting electricity.

In general, a three-phase three-wire system or a three-phase four-wire system is employed as a method of supplying the generated power. Here, the three-phase three-wire system refers to a method of supplying three-phase power using three wires. Here, the three-phase, four-wire system refers to a method of transmitting power using four wires by using one wire as a branch in three-phase power transmission.

The three-phase three-wire system is used for general power transmission and distribution of power lines because it is the most advantageous when the weight of the electric wire 10 is compared to other methods by making the received power, the maximum inter-line voltage, and the power loss constant.

The three-phase, four-wire system is more efficient than the three-phase three-wire system by using one more branch wire. For this reason, when a product that uses a lot of power, such as an air conditioner, is used, power is transmitted using a three-phase, four-wire system.

Referring to FIG. 1 , a live wire device 200 having a plurality of bypass clamps 100 is fastened to an electric wire 10 of a power pole 30 .

That is, the live wire device 200 refers to a device in which a plurality of bypass clamps 100 are installed on both sides of the wire 10 , respectively, so that the current flowing in the wire 10 can be bypassed. In other words, it may refer to a device that fastens the bypass clamp 100 to the electric wire 10 of the power pole 30 during live wire work so that current flows through the bypass cable 160 .

Here, the live wire refers to cutting off electricity for repairing the electric wire 10 through which electricity is flowing.

As shown in Figure 1, by fastening the bypass clamp 100 on both sides of the part requiring repair or maintenance, the current can be bypassed through the bypass cable 160 connected to the bypass clamp 100. have. The electric wire 10 of the portion to which the bypass clamp 100 is fastened may be maintained in a state in which the current is cut off.

The location where the bypass clamp 100 is installed needs to be installed to be spaced apart by a certain distance from a part that needs repair or the like.

2 is a conceptual diagram illustrating a live wire device 200 according to an embodiment of the present invention.

The live wire device 200 according to an embodiment of the present invention has a first bypass clamp 100a fastened to the electric wire 10, a second bypass clamp 100b, and a current bypassing the electric wire 10 can move. It may include a manipulation unit 20 for manipulating the bypass cable 160 and the bypass clamp 100 .

The first bypass clamp 100a and the second bypass clamp 100b are the casings 110 and 100', the motors 120 and 120', the upper clamps 130 and 130' and the lower clamps 140 and 140'. ) can be composed of Hereinafter, a configuration that the first bypass clamp 100a and the second bypass clamp 100b have in common will be described.

The batteries 121 and 121' and the controllers 122 and 122' may be installed on one side of the motors 120 and 120'. In addition, the motors 120 and 120' may include rotating shafts 123 and 123', and shaft screws 124 and 124' connected to the rotating shafts 123 and 123' may be formed.

The first screw threads 124a1 and 124a1' are formed on the outer peripheral surfaces of the shaft screws 124a and 124a', and the shaft screws 124 and 124' apply the rotational force transmitted from the motors 120 and 120' to the upper clamps 130 and 130. ') to transmit.

The upper clamps 130 and 130' are formed in a cylindrical shape. In addition, first screw grooves 130a1 and 130a1' that are screwed to the first screw threads 124a1 and 124a1' are formed on the inner peripheral surfaces of the upper clamps 130a and 130a'. In addition, the upper clamp outer peripheral surface (130b, 130b') is recessed from the elevating guide (130c, 130c') is formed in the form of a hole.

The lower clamps 140 and 140' include fixing support parts 141 and 141' and connection parts 142 and 142'. The upper clamps 130 and 130' may descend while sliding along the inner circumferential surfaces of the fixing supports 141a and 141a' while descending in the direction of the lower clamps 140 and 140'.

In order for the lower clamps 140 and 140' to be accommodated in the casings 110 and 100', the diameters of the outer peripheral surfaces of the fixing supports 141b and 141b' are preferably smaller than the diameters of the inner peripheral surfaces of the casings 110 and 100'. do.

Connection terminals 143 and 143' may be formed on one side of the connection parts 142 and 142'.

The wire receiving portions 144 and 144' in which the electric wire 10 is accommodated may be formed between the fixed support portions 141 and 141' and the connecting portions 142 and 142'.

Insertion holes 145 and 145 ′ into which one end of the bypass cable 160 can be inserted may be formed under the connection portions 142 and 142 ′. In addition, second screw grooves 145a and 145' may be formed in the insertion holes 145 and 145' so that the fastening force between the connection parts 142 and 142' and the bypass cable 160 is improved.

Hereinafter, for convenience of description, the first bypass clamp 100a and the second bypass clamp 100b are not divided, and will be described as the bypass clamp 100 .

The bypass clamp 100 is fastened to the electric wire 10 and serves to change the moving direction of the current flowing in the electric wire 10 to the bypass cable 160 . That is, the current moving in the electric wire 10 through the bypass clamp 100 bypasses the bypass cable 160 .

The bypass clamp 100 is connected to both sides of the bypass cable 160 . For example, the first bypass clamp 100a may be installed on one side, and the second bypass clamp 100b may be installed on the other side.

In general, the live wire device 200 may be used when repair of an electrical facility such as a power pole 30 is required. Bypass clamps 100 may be installed on both sides of the part in need of repair. Current may be bypassed to the bypass cable 160 through the bypass clamp 100 .

Through this, electricity can flow through the live wire device 200 so that electrical work can be performed without power cut off. In addition, the operator can repair the malfunction without fear of electric shock.

As described above, the three wires 10 are connected to the power pole 30 . That is, when repair of the power pole 30 is required, three live wire devices 200 may be required. All electricity flowing from the three wires 10 must be bypassed using the three live wire devices 200 , so that the malfunction of the electric pole 30 can be repaired without the risk of an electric shock accident.

3 is a conceptual diagram illustrating a bypass clamp 100 according to an embodiment of the present invention.

The bypass clamp 100 according to an embodiment of the present invention includes a motor 120, an upper clamp 130, a lower clamp 140, and a casing 110 in which the upper clamp 130 and the lower clamp 140 are accommodated. includes

The casing 110 has a cylindrical shape, and has a shape in which one side is opened so that the electric wire 10 can pass therethrough in the cylindrical shape. The open portion may mean a wire receiving space (S1).

The wire accommodating space (S1) may be formed in a shape recessed in the inner direction of the casing (110) from the outer peripheral surface of the casing (110a).

The wire accommodating space (S1) may be formed in a portion of the casing 110 in which the lower clamp 140 is accommodated. It is preferable to have a shape corresponding to the wire receiving part 144 formed in the lower clamp 140 .

In addition, the casing 110 may have an open top and bottom. The upper part may have a closed shape in some cases, but the lower part should be open to connect the lower clamp 140 and the bypass cable 160 to each other.

The motor 120 is a driving device, and serves to transmit a rotational force to the shaft screw 124 to cause the shaft screw 124 to rotate. At one side of the motor 120 , a battery 121 that drives the motor 120 and a control unit that enables operation by the manipulation unit 20 may be installed.

Based on the longitudinal direction of the casing 110 , the motor 120 may include a rotation shaft 123 extending downward. The rotating shaft 123 connects the motor 120 and the shaft screw 124 , and serves to transmit the rotational force generated from the motor 120 to the shaft screw 124 .

The motor 120 is fixedly installed inside the casing 110 . For example, the casing inner circumferential surface 110b and the motor 120 may be fixedly installed.

The shaft screw 124 connected to the motor 120 may also be fixed. Accordingly, while the shaft screw 124 rotates in place by the rotational force transmitted from the motor 120 , the upper clamp 130 can ascend and descend through relative rotation with the upper clamp 130 .

In addition, the motor 120 must be able to rotate left and right so that the upper clamp 130 can be raised and lowered by the rotation of the shaft screw 124 .

The shaft screw outer circumferential surface 124a and the inner circumferential surface of the upper clamp 130 are coupled to abut. That is, the first screw thread 124a1 of the shaft screw 124 and the first screw groove 130a1 of the upper clamp 130 are screwed together.

The shaft screw 124 is rotated by the motor 120 driven left and right, and the upper clamp 130 is rotated in response thereto. Here, rotation of the motor 120 in the right direction means a clockwise direction, and rotation of the motor 120 in a left direction means a counterclockwise direction.

The outer diameter of the upper clamp 130 is preferably formed smaller than the inner diameter of the casing (110). In addition, it is preferable that the inner diameter of the upper clamp 130 is formed larger than the outer diameter of the shaft screw 124 .

The lower clamp 140 may include a fixing support 141 and a connecting portion 142 . The fixing support 141 may have an open top so that the upper clamp 130 can be inserted.

That is, the upper clamp 130 can be inserted while sliding into the inner peripheral surface 141a of the fixed support.

A connection terminal 143 may be formed to protrude from the upper end of the transfer unit. The connection terminal 143 passes through the electric wire 10 positioned between the upper clamp 130 and the lower clamp 140 and is electrically connected to the electric wire 10 .

It has a wire receiving portion 144 in which the wire 10 is accommodated. A connection terminal 143 capable of fastening the electric wire 10 to the electric wire accommodating part 144 is formed.

4 is a conceptual diagram illustrating a state in which the electric wire 10 is accommodated in the electric wire accommodating space S1 of the bypass clamp 100 .

As shown in FIG. 1 , in order for the live wire device 200 to be installed on the wire 10 , the bypass clamp 100 must first be mounted on the wire 10 .

The electric wire 10 needs to be inserted into the electric wire accommodating part 144 formed in the lower clamp 140 past the electric wire accommodating space S1 of the casing 110 .

As shown in FIG. 4 , after the electric wire 10 is seated in the electric wire receiving part 144 , the upper clamp 130 may be lowered by the driving motor 120 .

The upper clamp 130 descending in the direction of the lower clamp 140 may serve to support or fix the electric wire 10 together with the lower clamp 140 .

In order for the current moving along the electric wire 10 to bypass the bypass cable 160 through the bypass clamp 100 , it is seated in the electric wire receiving part 144 while being peeled off the sheath 10a of the electric wire 10 . need to be

5 is a perspective view illustrating a motor 120 having a shaft screw 124 connected to the rotation shaft 123 and an upper clamp 130 coupled to the shaft screw 124 .

6 is a perspective view of the motor 120 provided with the shaft screw 124 .

With reference to FIG. 5 , the interaction between the shaft screw 124 and the upper clamp 130 will be described in detail.

The outer diameter of the shaft screw 124 may be formed smaller than the inner diameter of the upper clamp 130 . In order for the shaft screw 124 to rotate, it is preferable that the shaft screw outer circumferential surface 124a and the inner circumferential surface of the upper clamp 130 do not come into close contact with each other.

A first screw thread 124a1 is formed on the shaft screw outer circumferential surface 124a, and a first screw groove 130a1 is formed on the inner circumferential surface of the upper clamp 130. The shaft screw 124 and the upper clamp 130 may be rotatably coupled to each other by the first screw thread 124a1 and the first screw groove 130a1.

The control unit provided in the motor 120 allows the operation unit 20 to operate the motor 120 . It serves to receive a signal transmitted through a button installed on the operation unit 20 from the control unit to drive the motor 120 according to the signal.

When the motor 120 is driven, the shaft screw 124 connected to the rotating shaft 123 rotates along the driving direction of the motor 120 . When the motor 120 rotates in the clockwise direction, the upper clamp 130 may descend downward by the rotating shaft screw 124 .

For example, the shaft screw 124 accommodated in the upper portion of the casing 110 is rotated in place by the motor 120 . When the shaft screw 124 rotates in place, the corresponding upper clamp 130 rotates together.

That is, according to the direction in which the shaft screw 124 rotates, the upper clamp 130 may rise or fall. Here, the rising of the upper clamp 130 may mean an upward direction in the longitudinal direction of the casing 110 , and descending may mean a downward direction in the longitudinal direction of the casing 110 .

Hereinafter, for convenience of explanation, when the motor 120 rotates clockwise, it will be described that the upper clamp 130 descends. However, the direction of movement may vary depending on the structure formed in the first screw thread 124a1 and the first screw groove 130a1.

When the motor 120 rotates counterclockwise according to a signal from the manipulation unit 20 , the upper clamp 130 may rise upward by the rotating shaft screw 124 .

When the shaft screw 124 rotates in the clockwise direction, the upper clamp 130 may rotate in the direction of the lower clamp 140 while rotating together.

The upper clamp 130 may descend until the upper end of the first screw groove 130a1 formed in the upper clamp 130 comes into contact with the lower end of the first screw thread 124a1 formed in the shaft screw 124. . That is, the structure of the first screw groove 130a1 formed in the upper clamp 130 may mean that the lowering degree of the upper clamp 130 can be determined.

A hole into which the elevating guide part can be inserted may be formed on the side of the upper clamp 130 . The hole may prevent the upper clamp 130 from being separated from the shaft screw 124 .

In addition, when the upper clamp 130 is lowered by the rotating shaft screw 124 , the elevating guide part comes into contact with the upper part of the hole, thereby preventing the lowering of the upper clamp 130 . That is, the hole and the elevating guide serve to determine the depth at which the upper clamp 130 descends.

As described above, the control unit 122 and the battery 121 may be installed on one side of the motor 120 .

The controller 122 may include a controller that senses the rotation direction and speed of the motor 120 .

By receiving an external signal from the operation unit 20, it is possible to generate a signal for driving the motor 120, and through this, it can serve to transmit a signal to control the rotation direction or rotation speed of the motor 120. have.

In addition, the control unit 122 may serve to transmit a signal to control the rotation direction or rotation speed of the motor 120 .

7 is a perspective view showing the upper clamp 130 through which the elevating guide guide 130c is formed on the side surface.

An elevation guide 130c into which the elevation guide parts 111a and 111b can be inserted may be formed through the side surface of the upper clamp 130 .

The elevating guide guide 130c may be formed to extend in the axial direction from the side surface of the upper clamp 130 .

According to an embodiment of the present invention, the elevating guide guide 130c may be formed in the form of a groove recessed from one side of the upper clamp outer circumferential surface 130b. In this case, one end of the elevating guide portions 111a and 111b may be configured to be accommodated in the groove.

Elevating guide guide (130c) may be formed in one or more places on the outer peripheral surface of the upper clamp (130b). It is preferable that the elevating guides (111a, 111b) be formed at two or more places to prevent the elevating and lowering guides from being separated from the elevating guides (130c).

8 is a perspective view illustrating an insertion hole 145 through which the bypass cable 160 can be detached is formed in the lower clamp 140 including the fixing support 141 and the connecting part 142 .

As described above, the lower clamp 140 may include a fixing support portion 141 and a connection portion 142 . The fixing support part 141 is formed in a shape into which the upper clamp 130 can be inserted, and the connection part 142 is made of a cylindrical conductor in the lower part of the fixing support part 141 .

A connection terminal 143 may protrude from the upper end of the connection part 142 . Referring to FIG. 8 , the upper end of the connection terminal 143 may be understood as a surface connected to the inner circumferential surface of the fixing support 141 .

In order to induce a current moving through the wire 10 to the bypass cable 160 connected to the lower clamp 140 , the fixing support 141 may be formed of an insulator through which current does not pass. Here, the insulator refers to a material with low electrical conductivity.

A wire accommodating part 144 in which the wire 10 can be accommodated is formed in the lower clamp 140 . The wire receiving part 144 means an empty space formed between the fixed support part 141 and the connection part 142 . In addition, it may refer to a portion in which the connection terminal 143 is formed.

The connection terminal 143 serves to fix the electric wire 10 together with the lower clamp 130 . The connection terminal 143 may have a truncated cone shape in which the diameter decreases from the lower part to the upper part. In addition, it may be formed in a form that can penetrate the covering (10a) of the electric wire (10). The reason why it is formed in this way will be described later.

In the lower clamp 140 according to the present invention, an insertion hole 145 into which the bypass cable 160 can be inserted is formed in the lower part of the lower clamp 140 so that the existing bypass cable 160 can be recycled. can

By forming the insertion hole 145 in the lower clamp 140 , the end of the previously used bypass cable 160 is machined, and the bypass cable 160 is fastened to the insertion hole 145 to be used. There is this. Due to this, the cost of producing the live wire device 200 according to the present invention can be reduced.

It is preferable that the inner diameter of the insertion hole 145 is larger than the outer diameter of the bypass cable 160 . The end of the bypass cable 160 inserted into the insertion hole 145 may be formed in a shape through which a current can pass by exposing a conductive wire.

In order to secure the fastening force between the lower clamp 140 and the bypass cable 160, a second screw groove 145a may be formed on the inner circumferential surface of the insertion hole 145, and the end of the bypass cable 160 is Two threads (11a) may be formed.

The portion where the second screw thread 11a is formed is formed to surround the conducting wire of the bypass cable 160, and is preferably formed of a member through which electricity can pass.

When screwed by the second screw groove 145a formed on the inner circumferential surface of the insertion hole 145 and the second screw thread 11a formed at the distal end of the bypass cable 160 , both members may be firmly coupled.

9 is a perspective view showing the casing 110 of the bypass clamp 100 .

The upper clamp 130 is accommodated in the upper part of the casing 110, and the lower clamp 140 is accommodated in the lower part.

The casing 110 is formed with a wire accommodating space (S1) through which the wire 10 can pass. The wire accommodating space (S1) is formed under the casing 110 extending in the longitudinal direction. It may mean being formed below the center of the casing 110 extending in the longitudinal direction.

In addition, the lower clamp 140 may be formed inside the casing 110 so that the electric wire 10 accommodating part and the electric wire accommodating space S1 formed in the lower clamp 140 correspond.

The upper clamp 130 is accommodated in the upper portion of the casing 110 . Accordingly, the upper portion of the casing 110 may be formed longer than the length of the upper clamp 130 so that the upper clamp 130 can be accommodated.

The wire accommodating space S1 may be formed in the size of the diameter of the wire 10 installed on the electric pole 30 or the like. The bypass clamp 100 is preferably formed to be larger than the diameter of the electric wire 10 in order to be easily fastened to the electric wire (10).

10 is a conceptual diagram illustrating that the control unit 122 receives a signal from the manipulation unit 20 to remotely drive the bypass clamp 100 .

The bypass clamp 100 may be fastened to the electric wire 10 by remote operation. In this case, the manipulation unit 20 for operating the bypass clamp 100 from a distance is required.

As described above, the three wires 10 are connected to the power pole 30 . A total of six wires (10) are connected on both sides of the electric pole (30).

It can be understood that A, B, and C shown in the manipulation unit 20 refer to wires having different phases. For example, live wire devices installed on different wires for the repair of power poles.

That is, it means that the bypass clamp 100 separately installed on the three wires 10 connected to the power pole 30 can be operated with one manipulation unit 20 .

When repair of the electric pole 30 is required, live work for a total of three electric wires 10 is required. While the six bypass clamps 100 provided in the three live wire devices 200 are fastened to the electric wire 10 , the current flowing to the power pole 30 can be diverted to the bypass cable 160 .

As described above, since the three live wire devices 200 are used together, an operation button capable of operating a total of three bypass clamps 100 is formed on the operation unit 20 .

When the R button is pressed, the motor can be rotated to rotate in the right direction from the direction in which the drawing is viewed. Here, the right direction may mean a clockwise direction.

That is, while the motor 120 rotates clockwise, the upper clamp 130 may descend in the direction of the lower clamp 140 .

When the L button is pressed, the motor can rotate in the left direction from the direction in which the drawing is viewed. Here, the left direction may mean a counterclockwise direction.

That is, while the motor 120 rotates counterclockwise, the upper clamp 130 may rise in the upper direction of the casing 110 . Here, the upper direction of the casing 110 may mean a direction away from the lower clamp 140 .

By remotely operating the three live wire devices 200 through one manipulation unit 20 , the time for the bypass clamp 100 to be fastened to the electric wire 10 can be shortened. After the bypass clamp 100 is mounted on the electric wire 10 , the bypass clamp 100 can fasten the electric wire 10 through the manipulation unit 20 , thereby reducing operator fatigue.

By performing live wire work through remote control, it is possible to prevent and minimize the operator's electric shock accident.

11 is a conceptual diagram illustrating the elevation of the upper clamp 130 along the elevation guides 111a and 111b and the elevation guide 130c.

According to an embodiment of the present invention, the elevating guide guide (130c) is formed on the side of the upper clamp (130). The elevating guide guide 130c is formed to extend in the axial direction.

Elevating guide portions (111a, 111b) that are formed to protrude from the inner circumferential surface of the casing 110 so as to be inserted into the elevating guide (130c) is formed.

When the upper clamp 130 descends, the elevating guide guide 130c descends while sliding along the elevating guide portions 111a and 111b. Therefore, the elevating guide 130c formed in the shape of a hole accommodates the elevating guide portions 111a and 111b formed to protrude, but is preferably formed in a form that is not in close contact.

The elevating guide parts 111a and 111b are inserted into the place where the elevating guide 130c is formed, and the upper clamp 130 rotating by the rotational force of the shaft screw 124 will serve to prevent the rotation together. can

As the elevating guides 111a and 111b and the elevating guide 130c are formed, the upper clamp 130 may stably descend in the direction of the lower clamp 140 .

In addition, when the upper clamp 130 descends in the direction of the lower clamp 140 , the elevating guide parts 111a and 111b interfere with the inner upper end of the elevating guide 130c to prevent the descent of the upper clamp 130 . can be limited

In order to prevent rotation of the upper clamp 130 to rotate together with the shaft screw 124, one or more pairs of elevating guide guides 130c and elevating guides 111a and 111b may be formed. In addition, in order to prevent damage to the elevating guides 111a and 111b that prevent the rotation of the upper clamp 130 from the rotational force of the motor 120, two or more pairs of elevating guides 130c and elevating guides (111a, 111b) is preferably formed.

12 is a perspective view illustrating that the electric wire 10 is fastened and supported by the upper clamp 130 and the lower clamp 140 .

13 is a conceptual diagram illustrating a state in which the connection terminal 143 is electrically connected to the electric wire 10 by being pressed by the upper clamp 130 .

A process in which the electric wire 10 is fastened to the bypass clamp 100 will be described in detail with reference to FIGS. 12 and 13 .

In order for the electric wire 10 to be fastened to the clamp, the upper clamp 130 is lowered in the direction of the lower clamp 140 after the electric wire 10 is accommodated in the electric wire accommodating part 144 through the electric wire accommodating space S1. .

In detail, the wire 10 should be located in the wire receiving portion 144 formed in the bypass clamp (100). For example, the operator must place the bypass clamp 100 on the electric wire 10 connected to the power pole 30 .

Thereafter, a worker located on the ground may drive the motor 120 of the bypass clamp 100 through the manipulation unit 20 . As the motor 120 rotates, the upper clamp 130 descends in the direction of the lower clamp 140 .

The upper clamp 130 may press the electric wire 10 located between the upper clamp 130 and the lower clamp 140 . Here, the direction in which the electric wire 10 is pressed may mean a direction in which the connection terminal 143 is installed.

The connection terminal 143 penetrates the sheath 10a of the electric wire 10 that is gradually pressed by the upper clamp 130 . When the cover 10a of the electric wire 10 is completely penetrated, the connection terminal 143 and the conductor of the electric wire 10 are electrically connected.

When this process is completed, the current moving along the electric wire 10 is diverted to the bypass cable 160 through the bypass clamp 100 on one side. The current moving along the bypass cable 160 moves back to the electric wire 10 through the bypass clamp 100 on the other side.

Through this, current may not flow inside the wire 10 on which the bypass clamp 100 is installed. In other words, it means that the operator can perform the work in a state free from the risk of electric shock.

Referring to FIG. 13 , it can be seen that the distance between the lower end of the upper clamp 130 and the connection terminal 143 of the lower clamp 140 is formed to be the same as the diameter of the electric wire 10 .

According to FIG. 13 , a connection terminal 143 is formed on the lower clamp 140 . However, the portion to which the bypass clamp 100 is fastened should be in a state in which the coating 10a of the electric wire 10 is peeled off. That is, it should be fastened to the bypass clamp 100 in a state in which the conducting wire is exposed.

Accordingly, the upper clamp 130 must be lowered enough to allow the conductive wire to be fastened between the upper clamp 130 and the wire receiving part 144 .

However, in the bypass clamp 100 according to the embodiment of the present invention, the connection terminal 143 is formed in the lower clamp, so there is no need to separate the coating 10a of the electric wire 10 . The process of peeling off the coating 10a of the electric wire 10 is omitted, and the bypass clamp 100 can be fastened to the electric wire 10, so that the working time can be shortened.

14 is a conceptual diagram illustrating a state in which current flows through the bypass clamp 100 fastened to the electric wire 10 .

A connection terminal 143 may be formed on the lower clamp 140 according to an embodiment of the present invention.

The connection terminal 143 may play a role of being electrically connected to the conductor of the electric wire 10 through the covering 10a of the electric wire 10 . Accordingly, the connection terminal 143 may be formed in a pointed shape. For example, it may have the shape of a truncated cone whose diameter decreases from the lower part to the upper part.

The connection terminal 143 serves to fix or support the electric wire 10 positioned in the electric wire receiving part 144 together with the upper clamp 130 . Due to this, it is possible to reduce the drop-off and fall accidents of the bypass clamp 100 that have occurred in the prior art.

In order for the connection terminal 143 to penetrate the covering 10a and be electrically connected to the conductor, the connection terminal 143 must be formed to be longer than the thickness of the covering 10a so that it can touch the conducting wire. The wire 10 is pressed in the direction of the connection terminal 143 of the lower clamp 140 by the descending upper clamp 130 , and the connection terminal 143 penetrates the covering 10a.

Since the electric wire 10 is lowered by the upper clamp 130, it is preferable that the upper clamp 130 descends enough to allow the conducting wire and the connection terminal 143 to touch.

In addition, the connection terminal 143 should be made of a member through which current can pass. This is because it is made of the same member as the conductor so that the current flowing from the conductor in contact with the conductor can be diverted to the bypass cable 160 .

The current flowing through the electric wire 10 is transmitted to the connecting portion 142 through the connecting terminal 143 . The current transmitted from the connection terminal 143 moves to the bypass cable 160 coupled to the insertion hole 145 of the connection part 142 .

As described above, the current flowing through the bypass cable 160 may move to the electric wire 10 through the bypass clamp 100 installed on the opposite side.

In other words, it means that electricity can continue to flow in the line and work can be done. When electricity is cut off and construction is performed, a lot of damage occurs, but the worker can efficiently perform the work through the live wire device 200 according to the present invention.

The configuration and method of the described embodiments are not limitedly applicable to the bypass clamp 100 for remote control and the live wire device 200 including the same as described above, but the embodiments are provided so that various modifications can be made. All or part of each embodiment may be selectively combined and configured.

10: wire
10a: cloth
20: control panel
30: power pole
100: bypass clamp
100a: first bypass clamp
100b: second bypass clamp
110, 110': casing
110a, 110a': outer circumferential surface of the casing
110b, 110b': inner circumferential surface of the casing
S1, S1': Wire accommodating space
111a, 111b: elevating guide
120, 120': motor
121, 121': battery
122, 122': control unit
123, 123': axis of rotation
124, 124': shaft screw
124a, 124a': shaft screw outer circumferential surface
124a1, 124a1': first thread
130, 130': upper clamp
130a, 130a': upper clamp inner circumferential surface
130a1, 130a1': first screw groove
130b, 130b': upper clamp outer peripheral surface
130c, 130c': Guide for ascending and descending
140, 140': lower clamp
141, 141': fixed support
141a, 141a': inner circumferential surface of the fixed support part
141b, 141b': outer peripheral surface of the fixed support part
142, 142': connection part
143, 143': connection terminal
144, 144': wire receiving part
145, 145': insertion hole
145a, 145a': second screw groove
150: control panel
160: bypass cable
161: second thread
200: live wire device

Claims (20)

A casing made of a cylindrical shape, one side of which is opened so that the electric wire is installed;
a motor fixedly installed inside the casing;
an upper clamp connected to the motor and installed to be movable in the vertical direction inside the casing; and
It comprises a lower clamp which is made so that the upper part is opened and is installed so that the upper clamp can be inserted or drawn out according to the driving of the motor,
A connection terminal is formed in the lower clamp to pass through an electric wire positioned between the lower clamps to be electrically connected to the electric wire,
The current moving along the electric wire is bypassed along the bypass cable connected to the lower clamp through the connection terminal,
The lower clamp is
a fixing support part having a shape to surround and support the upper clamp; and
Bypass clamp comprising a connection part made of a cylindrical conductor under the fixed support part, and conducting electricity with the electric wire. According to claim 1,
An elevating guide protruding toward the lower clamp is formed on the inner circumferential surface of the casing,
Bypass clamp, characterized in that the elevating guide is inserted into the side of the lower clamp, the elevating guide guide for guiding the movement in the vertical direction is formed through. 3. The method of claim 2,
The elevating guide guide is made of a form extending in the axial direction from the side of the upper clamp,
Bypass clamp, characterized in that when the upper clamp descends in the direction of the lower clamp, the elevating guide portion interferes with the inner upper end of the elevating guide guide to limit the lowering of the upper clamp. delete According to claim 1,
The fixed support portion is a bypass clamp, characterized in that made of an insulator. According to claim 1,
An insertion hole is formed at a lower portion of the connection part so that the bypass cable can be detached, and the bypass cable positioned in the insertion hole and the connection terminal are connected to each other so as to be energized. 7. The method of claim 6,
The bypass clamp, characterized in that the inner peripheral surface of the insertion hole is screwed to one end of the bypass cable. According to claim 1,
The connection terminal, the bypass clamp, characterized in that made of a shape in which the diameter decreases from the bottom to the top so as to pass through the wire. According to claim 1,
The motor includes a shaft screw connected to the rotating shaft to transmit the rotational force of the motor,
The upper clamp, bypass clamp, characterized in that elevating and lowering by the action of the shaft screw. According to claim 1,
The motor is a bypass clamp, characterized in that it has a control unit to be rotatable in one direction by an external signal. Bypass cable for changing the direction of movement of the current flowing in the wire; and
A plurality of bypass clamps connected to both ends of the bypass cable and fastened to a plurality of points of the electric wire,
The bypass clamp is
A casing made of a cylindrical shape, one side of which is opened so that the electric wire is installed;
a motor fixedly installed inside the casing;
an upper clamp connected to the motor and installed to be movable in the vertical direction inside the casing; and
It comprises a lower clamp which is made so that the upper part is opened and is installed so that the upper clamp can be inserted or drawn out according to the driving of the motor,
A connection terminal is formed in the lower clamp to pass through an electric wire positioned between the lower clamps to be electrically connected to the electric wire,
The current moving along the electric wire is bypassed along the bypass cable connected to the lower clamp through the connection terminal,
The lower clamp is
a fixing support part having a shape to surround and support the upper clamp; and
A live wire device comprising a connection part made of a cylindrical conductor under the fixed support part and conducting electricity with the electric wire. 12. The method of claim 11,
An elevating guide protruding toward the upper clamp is formed on the inner circumferential surface of the casing,
A live wire device, characterized in that the ascending and descending guide part is inserted into the side of the upper clamp, and an ascending and descending guide guide for guiding the movement in the vertical direction is formed through. 13. The method of claim 12,
The elevating guide guide is made of a form extending in the axial direction from the side of the upper clamp,
When the upper clamp descends in the direction of the lower clamp, the elevating guide part interferes with the inner upper end of the elevating guide guide to limit the lowering of the upper clamp. delete 12. The method of claim 11,
The fixed support portion is a live wire device, characterized in that made of an insulator. 12. The method of claim 11,
An insertion hole is formed in a lower portion of the connection part so that the bypass cable can be detached, and the bypass cable positioned in the insertion hole and the connection terminal are connected to each other so as to be energized. 17. The method of claim 16,
An inner circumferential surface of the insertion hole is screw-fastened to one end of the bypass cable. 12. The method of claim 11,
The connection terminal is a live wire device, characterized in that the diameter decreases from the bottom to the top so as to pass through the wire. 12. The method of claim 11,
The motor includes a shaft screw connected to the rotating shaft to transmit the rotational force of the motor,
The upper clamp is a live wire device, characterized in that the elevating and lowering by the action of the shaft screw. 12. The method of claim 11,
The motor is a live wire device, characterized in that it has a control unit to be rotatable in one direction by an external signal.

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