KR102391556B1 - Providing method of a replacement system for distribution lines - Google Patents

Abstract

The present invention relates to a method for providing a distribution line replacement system for an urban district, which comprises the following steps of: preparing the method for providing a distribution line replacement system for an urban district; and implementing the method for providing a distribution line replacement system for an urban district, wherein the method for providing a distribution line replacement system for an urban district is controlled by a monitor unit and a distribution line replacement system for an urban district includes: a clamp body (100) having an insertion unit (110) for inserting any one electric wire and another electric wire thereinto, at least one bolt hole (120) for inserting a fixing bolt, and a support unit hole (130) for inserting a support unit of an electric wire supporting means thereinto, which are formed at one side; at least one fixing bolt (200) inserted into the bolt hole formed at one side of the clamp body to fix the any one electric wire and another electric wire inserted into the insertion unit to the clamp body; and an electric wire supporting means (300) including the support unit (310) partially inserted into the support unit hole formed on the clamp body, an electric wire contact unit (320) formed on a terminal of the support unit to be parallel to the any one electric wire and another electric wire and come in contact with an end portion of the fixing bolt, and a spring (330) installed to provide elasticity to the support unit. Accordingly, connection of the electric wires can be simply released by loosening the fixing bolt, thereby providing speed and convenience.

Description

Providing method of a replacement system for distribution lines in urban areas

The present invention relates to a method of providing a system for replacing a distribution line in an urban area, and more particularly, to improve the shortcomings of a compression sleeve temporarily installed in a distribution line through which a high-voltage current flows, and to use a simple tool such as a spanner to attach it to the connection clamp. By simply tightening the formed fixing bolt, the wire connection is made, and it provides the convenience and quickness to simply disconnect the wire connection by loosening the fixing bolt. It relates to a method of providing a replacement system for an urban area distribution line that can be provided.

Power facilities are continuously expanding in response to the rapid increase in power demand, and as the level of demand for electricity quality from power users increases, even momentary power outages are subject to civil complaints. As the situation is increasing, the uninterruptible method is used in which the construction is performed without shutting off the electric power to supply high-quality electric power during distribution work.

For this uninterruptible method, a separate bypass cable 30 is used to separate and connect electricity between old and new wires while securing a working space between old and new replacement and relocation wires within the electric pole using a wire transfer mechanism. Techniques are being developed to improve power quality by providing a method for replacing and relocating old and new wires without uninterrupted power failure, enabling uninterrupted operation of upper distribution lines with two or more lines without power load transfer work.

On the other hand, the connection point connecting the main line and the temporary line of the distribution line is connected using a compression sleeve, which is expensive due to the process of connecting using a compressor and takes a lot of work time. In addition, when wiring from the temporary line to the main line after replacing the cable, the cables connected to the compression sleeve are cut before and after the cable is cut, and the main line and the compression sleeve must be reworked, so additional use of wires and compression sleeves occurred. Accordingly, there is a demand for a simple, quick, and economical method of construction by improving the above disadvantages.

The problem to be solved by the present invention is to improve the shortcomings of a compression sleeve temporarily installed on a distribution line through which a high-voltage current flows, and simply tighten the fixing bolt formed on the connection clamp using a simple tool such as a spanner, and then the wire connection is made, An object of the present invention is to provide a method for providing a system for replacement of a distribution line in an urban area that can be easily released by loosening a fixing bolt to provide simplicity and speed of connection of wires.

In addition, an object of the present invention is to provide a method for providing a system for replacing a distribution line in an urban area, which can be used continuously without using the connection clamp itself one-time, which has economic benefits.

In addition, the present invention provides a method for providing a system for replacing a distribution line in an urban area that can provide verification and management of the replacement system for a distribution line in an urban area as proof data afterward, so that the cause of the problem and liability for compensation can be clarified. will provide

In addition, the present invention performs verification and management of the replacement system of the distribution line in the downtown area, so that immediate real-time action is possible, thereby preventing irreversible errors and damage caused by mass work and mass installation. It is to provide a method for providing a replacement system of

In addition, the present invention monitors a number of objects in performing verification and management of the replacement system for distribution lines in urban areas, and protects storage and operation in whole or in part in response to the surrounding climatic environment or operating conditions and pollution exposure situations, etc. It is to provide a method for providing a system for replacing distribution lines in an urban area that allows selective control of

Another object of the present invention is to provide a method for providing a system for replacing a distribution line in an urban area that is capable of more stable and reliable operation by applying the earthquake-resistant structure of the monitoring means itself and the structure for shock mitigation.

The problems to be solved by the present invention are not limited to those mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

The present invention provides a method for providing a system for replacing a distribution line in an urban area, the method comprising: preparing a system for replacing a distribution line in an urban area; and installing a replacement system for the urban area distribution line, wherein the urban area distribution line replacement system is managed by a monitor unit, and the urban area distribution line replacement system is configured with one electric wire and another An insertion part 110 for inserting an electric wire is formed, and at least one bolt hole 120 for inserting a fixing bolt on one side and a support part hole 130 for inserting a support part of the electric wire support means are formed. with the clamp body 100; at least one fixing bolt 200 inserted into a bolt hole formed on one side of the clamp body to fix one electric wire formed in the insertion part and the other electric wire to the clamp body; A support part 310 partially inserted into the hole of the support part formed in the clamp body, and a wire contact part 320 formed in parallel to one electric wire and the other electric wire at the end of the support part and in contact with the end of the fixing bolt; , Wire support means 300 configured to include a spring 330 is configured to be installed to provide elasticity to the support portion; It provides a method of providing a replacement system for an urban area distribution line comprising a.

According to the present invention, there are one or more of the following effects.

The present invention improves the shortcomings of a compression sleeve temporarily installed on a distribution line through which a high-voltage current flows, so that a wire connection is made by simply tightening the fixing bolt formed in the connection clamp using a simple tool such as a spanner, and loosening the fixing bolt It is possible to provide the simplicity and speed of simply disconnecting the connection.

In addition, since the connection clamp itself can be used continuously without being used once, it is possible to provide economic benefits.

In addition, it is possible to provide verification and management according to the occurrence of abnormalities in the method of providing a replacement system for distribution lines in urban areas as evidence later, so that the cause of the problem and liability for compensation can be clarified. method can be provided.

In addition, by performing verification and management of the method of providing a replacement system for distribution lines in urban areas, immediate real-time actions are possible, thereby preventing irreversible errors and damage caused by mass work and mass installation. A method for providing a system may be provided.

In addition, in performing the verification and management of the device of the method for providing a replacement system for distribution lines in urban areas, monitoring a number of objects, and protecting, storing, and operating in whole or in part in response to the surrounding climatic environment or operating conditions and pollution exposure conditions, etc. It is possible to provide a method of providing a system for replacing distribution lines in an urban area that allows selective control of

In addition, it is possible to provide a method for providing a system for replacing a distribution line in an urban area that is capable of more stable and reliable operation by applying the earthquake-resistant structure of the monitoring means itself and the structure for shock mitigation.

1 is a perspective view of a method for providing a system for replacing a distribution line in an urban area according to an embodiment of the present invention.
2 is a front view of a method for providing a system for replacing a distribution line in an urban area according to an embodiment of the present invention.
3 is a cross-sectional view of a method for providing a system for replacing a distribution line in an urban area according to an embodiment of the present invention.
4 is a perspective view of a method for providing a system for replacing a distribution line in an urban area according to this embodiment of the present invention.
5 is a front view of a method for providing a system for replacing a distribution line in an urban area according to this embodiment of the present invention.
6 is a cross-sectional view of a method for providing a system for replacing a distribution line in an urban area according to this embodiment of the present invention.
7 is an exemplary diagram illustrating an example of using a method for providing a system for replacing a distribution line in an urban area according to an embodiment of the present invention.
8 to 12 are views showing the main components of the present invention.

In the method for providing a system for replacing a distribution line in an urban area according to an embodiment of the present invention for achieving the above object, in the method for providing a system for replacing a distribution line in an urban area, one electric wire and another electric wire are inserted therein The insertion part 110 is formed, and at least one bolt hole 120 for inserting a fixing bolt on one side and a support part hole 130 for inserting the support part of the electric wire support means are formed in the clamp body 100 )Wow; at least one fixing bolt 200 inserted into a bolt hole formed on one side of the clamp body to fix one electric wire formed in the insertion part and the other electric wire to the clamp body; The support part 310, which is partially inserted into the hole of the support part formed in the clamp body, and the wire contact part 320 formed parallel to one electric wire and the other electric wire at the end of the support part, and in contact with the end of the fixing bolt. It is characterized in that it is configured to include; the wire support means 300 configured to include.

On the other hand, in the method of providing a system for replacing a distribution line in an urban area according to another embodiment of the present invention, the insertion parts 110 for inserting one electric wire and the other electric wire are respectively formed therein, and are fixed on both sides. a clamp body 100 having at least one bolt hole 120 for inserting a bolt and a support hole 130 for inserting a support part of the electric wire support means; at least one or more fixing bolts 200 inserted into bolt holes formed on both sides of the clamp body to fix one electric wire and the other electric wire formed in the insertion part to the clamp body; The support part 310, which is partially inserted into the hole of the support part formed in the clamp body, and the wire contact part 320 formed parallel to one electric wire and the other electric wire at the end of the support part, and in contact with the end of the fixing bolt. Wire support means 300 configured to include; It is characterized in that it comprises a.

At this time, the wire support means 300 is characterized in that the spring 330 is formed in order to provide elasticity to the support part.

At this time, it is characterized in that one wire and the other wire are connected to each other by the wire contact part by turning the fixing bolt. When the fixing bolt is loosened, the wire contact part is separated from one wire and the other wire, and it is characterized in that the connection between one wire and the other wire is released.

At this time, when the spring 330 is formed to provide elasticity to the support part of the wire support means 300 and the fixing bolt is loosened, the wire contact part is separated from any one wire and the other wire by the elastic restoring force of the spring. It is characterized in that the connection of the other one wire is released. The wire contact part 320 is characterized in that it has a semicircular shape. The clamp body 100 is characterized in that it is composed of any one of copper, copper alloy, and aluminum material.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of the present invention, a method for providing a system for replacing a distribution line in an urban area will be described in detail.

1 is a perspective view of a method for providing a system for replacing a distribution line in an urban area according to an embodiment of the present invention. 2 is a front view of a method for providing a system for replacing a distribution line in an urban area according to an embodiment of the present invention. 3 is a cross-sectional view of a method for providing a system for replacing a distribution line in an urban area according to an embodiment of the present invention.

1 to 3, in the method of providing a system for replacing a distribution line in a downtown area according to an embodiment of the present invention, an insertion unit 110 for inserting one electric wire and another electric wire is formed therein. and at least one bolt hole 120 for inserting a fixing bolt on one side and a clamp body 100 having a support hole 130 for inserting a support part of the electric wire support means; at least one fixing bolt 200 inserted into a bolt hole formed on one side of the clamp body to fix one electric wire and the other electric wire formed in the insertion part to the clamp body; The support part 310, which is partially inserted into the hole of the support part formed in the clamp body, and the wire contact part 320 formed in parallel to one electric wire and the other electric wire at the end of the support part, and in contact with the end part of the fixing bolt. The wire support means 300 is configured to include;

The clamp body 100 has an inserting part 110 for inserting one electric wire and the other one therein. However, due to the insufficient capacity of the previously installed electric wire, the newly installed electric wire has no choice but to have a larger diameter than the existing one. A space is provided for inserting wires of different diameters. In addition, even if the diameter is the same, a space for inserting two wires is provided. For example, a space corresponding to a wire diameter of 95 sq and a space corresponding to a wire diameter of 160 sq are formed in one insert as shown in the drawing.

In addition, on one side of the clamp body, at least one bolt hole 120 for inserting a fixing bolt and a support hole 130 for inserting the support part of the electric wire support means are formed on the upper side in the drawing.

A part of the support part penetrates the clamp body and part is exposed to the outside of the clamp body, and a support part hole for inserting the support part is formed.

At least one fixing bolt 200 is inserted into a bolt hole formed on one side of the clamp body to fix one electric wire formed in the insertion part and the other electric wire to the clamp body. At this time, when the end of the fixing bolt is in contact with the upper surface of the wire contact part and the fixing bolt is turned (clockwise), the wire contact part moves inward, so that one wire and the other wire can be connected.

In addition, when the fixing bolt is loosened (counterclockwise), the wire contact part moves outward, thereby disconnecting one wire from the other.

That is, the wire contact portion 320 is formed at the end of the support portion in parallel with any one wire and the other wire. The support part 310 is partially inserted into the support part hole formed in the clamp body to be connected to the wire contact part. On the other hand, according to an additional aspect, the wire support means 300 forms a spring 330 in order to provide elasticity to the support part.

When a spring is formed and the fixing bolt is turned, the support part is continuously inserted into the inside, and the spring is in a compressed state. After that, when the fixing bolt is loosened, the support part moves upward without a separate operation by the restoring force of the spring formed around the support part, and the wire contact part connected to the support part naturally moves upward.

In conclusion, by turning the fixing bolt, one wire and the other wire are connected to each other by the wire contact part, and by loosening the fixing bolt, the wire contact part is separated from one wire and the other wire, and the connection of one wire and the other wire is released. will be made

In addition, when the spring 330 is formed in order to provide elasticity to the support part of the wire support means 300 and the fixing bolt is loosened, the wire contact part is separated from one wire and the other wire by the elastic restoring force of the spring. and the other wire will be disconnected. In other words, when the wire contact part is lowered, the space of the insertion part is reduced, and it is impossible to insert the wire smoothly when inserting the wire. .

On the other hand, the wire contact portion 320 is characterized in that it has a semi-circular shape, which is for the wire contact portion to perform a role of pressing the outer diameter of the wire, and to increase the conductivity by increasing the wire connection portion.

Accordingly, it will have a semicircular shape similar to that of the electric wire. In addition, the clamp body 100 is composed of any one of copper, copper alloy, and aluminum material, which is also to increase conductivity.

4 is a perspective view of a method for providing a system for replacing a distribution line in an urban area according to this embodiment of the present invention. 5 is a front view of a method for providing a system for replacing a distribution line in an urban area according to this embodiment of the present invention. 6 is a cross-sectional view of a method for providing a system for replacing a distribution line in an urban area according to this embodiment of the present invention.

4 to 6, in the method of providing a system for replacing a distribution line in a downtown area according to this embodiment of the present invention, an insertion unit 110 for inserting one electric wire and another electric wire is formed therein, respectively. and a clamp body 100 having at least one bolt hole 120 for inserting a fixing bolt on both sides and a support hole 130 for inserting a support part of the electric wire support means; at least one or more fixing bolts 200 inserted into bolt holes formed on both sides of the clamp body to fix one electric wire and the other electric wire formed in the insertion part to the clamp body; The support part 310, which is partially inserted into the hole of the support part formed in the clamp body, and the wire contact part 320 formed in parallel to one electric wire and the other electric wire at the end of the support part, and in contact with the end part of the fixing bolt. The wire support means 300 is configured to include;

The difference between the clamp of this (2) embodiment and the clamp according to the (1) embodiment is that the clamp of this embodiment has an insert formed in the clamp body 100, respectively.

That is, insertion parts of different sizes are formed to be spaced apart from each other, or insertion parts of the same size are formed to be spaced apart from each other. In addition, in the case of an embodiment when two wires are in contact, a disadvantage in that the contact portion is small and the conductivity is lowered may occur. In order to improve this, two insertion parts are formed. In addition, fixing bolts are formed on both sides rather than on either side of the clamp body to fix each wire inserted into the respectively formed insertion part to the clamp body, respectively. In addition, the length of the wire contact portion of the present invention is preferably formed to be the same length as the length of the clamp body.

7 is an exemplary diagram illustrating an example of using a method for providing a system for replacing a distribution line in an urban area according to an embodiment of the present invention. The example shown in FIG. 7 is to apply the connection clamp for wire replacement according to an embodiment of the present invention.

In the prior art, a compression sleeve (J) connected to an existing lead wire is present in the wire for dismantling, and the bypass cable 30 is connected by working the compression sleeve.

After that, after the existing electric wire is removed, a compression sleeve operation is performed on a new electric wire, and the bypass cable and the compression sleeve are removed. On the other hand, in the case of the present invention, as shown in FIG. 7 , the bypass cable 30 is connected with the connection clamp 100 in the state where the compression sleeve J connected to the existing lead wire exists in the wire 10 for removal as shown in FIG. 7 . After that, the compression sleeve connected to the existing lead wire and the existing wire are removed.

After that, a new electric wire 20 is laid on the removed area and a compression sleeve is performed to connect a new electric wire. After that, the bypass cable and the connecting clamp are separated. Therefore, it is possible to provide a new construction method that is simple, quick, and economical to construct, and if the connecting clamp is used, it can be used continuously without cutting the electric wire, and the connecting clamp itself can be used repeatedly, resulting in enormous economic gain. will do In addition, as for the construction method, one wire and the other wire are connected by simply tightening the fixing bolt using a simple tool such as a spanner, thereby greatly improving the distribution line replacement work environment, enabling simple and quick work.

8 to 12 are views showing the main components of the present invention.

A method for providing a system for replacing a distribution line in an urban area, the method comprising: preparing a system for replacing a distribution line in an urban area; and installing a replacement system for the urban area distribution line, wherein the urban area distribution line replacement system is managed by a monitor unit.

In this urban area distribution line replacement system, an insertion part 110 for inserting one electric wire and another electric wire is formed therein, and at least one bolt hole 120 for inserting a fixing bolt on one side and a clamp body 100 having a support hole 130 for inserting a support portion of the wire support means; at least one fixing bolt 200 inserted into a bolt hole formed on one side of the clamp body to fix one electric wire and the other electric wire formed in the insertion part to the clamp body; A support part 310, which is partially inserted into the support hole formed in the clamp body, and a wire contact part 320 formed in parallel with one electric wire and the other electric wire at the end of the support part and in contact with the end of the fixing bolt; Wire support means 300 configured to include a spring 330 configured to be installed in order to provide elasticity to the support part; includes.

On the other hand, the monitor unit monitors the state of at least one of a manufacturing process, a loading process for installation, an installation process, and an operating state of a replacement system for a distribution line in an urban area. In addition, the monitor unit is provided in a single or a plurality at the site of the production, preparation, inspection, etc. of the replacement system for the distribution line in the urban area, so that the elements constituting the system can be monitored in number. The monitor unit is installed on a bar-shaped first columnar module 110' positioned on one side, a bar-shaped second columnar module 210' positioned on the other side, and the first columnar module 110' a first driving body 115', a second driving body 215' installed on the second pillar module 210', the first driving body 115' and the second driving body ( It is installed between opposite sides of 215') and includes a bar-shaped accommodation module 310' to which the management module is mounted.

Here, the management module includes a first monitoring unit CM1 and a second monitoring unit CM2. The accommodation module 310', the first monitoring unit CM1 is mounted on one side and the second monitoring unit CM2 is mounted on the other side, the first driving body 115' and the second driving body ( 215') to the set radius. In addition, the monitor unit includes a first sub-pillar module 120' installed on the upper part of the first driving body 115', and a second sub-pillar module 220' installed on an upper part of the second driving body 215'. And, a movable panel 320' installed on opposite sides of the first sub-pillar module 120' and the second sub-pillar module 220', and a accommodating module installed in the center of the movable panel 320' ( 310') includes an upward movable module 330' for fixing or releasing the fixing.

Here, one side of the movable panel 320 ′ corresponding to the left side of the upper movable module 330 ′ is provided with a first temperature control unit 331 ′ for controlling the temperature of the management module by spraying a fluid thereunder. One side of the movable panel 320' corresponding to the left side of the upward movable module 330' is provided with a second temperature control unit 332' for controlling the temperature of the management module by spraying a fluid on the lower side, The module 330' is provided with a third temperature control unit 333' for controlling the temperature of the management module by injecting a fluid thereunder.

In addition, the first temperature control unit 331 ′ and the second temperature control unit 332 ′ perform cooling or heating to a set temperature through fluid injection to the receiving module 310 ′, but the receiving module 310 ′). It is possible to operate in a first operation mode for performing fluid injection in this non-rotating general state and a second operation mode for performing fluid injection in a rotational state in which the accommodating module 310' is axially rotated, but the first monitoring unit ( CM1) is mounted on the upper side of the accommodating module 310', and the second monitoring unit CM2 is mounted on the lower side of the accommodating module 310' to face the first monitoring unit CM1, and operates the second mode of operation. The fluid is evenly sprayed to the first monitoring unit CM1 and the second monitoring unit CM2.

Here, based on the second operation mode, at least a portion of the first monitoring unit CM1 includes a first region facing the first temperature control unit 331 ′ and a second region facing the second temperature control unit 332 ′. The second area and the third temperature control unit 333' are positioned in a third area opposite to the fluid injection, and at least a portion of the second monitoring unit CM2 faces the first temperature control unit 331'. The fluid injection is performed by being positioned in a first area where the temperature is adjusted, a second area facing the second temperature control unit 332', and a third area facing the third temperature control unit 333'.

On the other hand, the upward movable module 330' protrudes downward and is mounted on the upper part of the accommodating module 310'; A mount 342' is provided. The first mounting body 341' is located on the left side with respect to the third temperature control unit 333' and is mounted on the receiving module 310', and the second mounting body 342' is the third temperature control unit ( 333') is located on the right side and is mounted on the accommodation module 310'.

In addition, the first mounting body 341 ′ and the second mounting body 342 ′ have a first stop mode and a second operation in which the receiving module 310 ′ is pressed with a first intensity preset to abruptly stop the second operation mode. It is possible to operate in the second stop mode by pressing the accommodating module 310 ′ with a second strength that is weaker than the first strength to gradually stop the mode.

The first sub-pillar module 120' and the second sub-pillar module 220' are provided to be movable between the upper and lower sides from the first driving body 115' and the second driving body 215', respectively. The upward movable module 330' reduces or reinforces the degree of pressing of the first mounting body 341' and the second mounting body 342' with respect to the receiving module 310' based on the positional movement.

The upper movable module 330 ′ includes a first driving panel 351 ′ provided on an inner surface of the first pillar module 110 ′ and a second driving panel provided on an inner surface of the second movable module 210 ′. (352'), and further includes a downward movable module (360') provided between the first driving panel (351') and the second driving panel (352'). The upper one side of the lower movable module 360 ′ is provided with a fourth temperature control unit 361 ′ for controlling the temperature of the management module by spraying a fluid upward, and the other upper side of the lower movable module 360 ′ moves upward. A fifth temperature control unit 362' for controlling the temperature of the management module by spraying a fluid is provided.

The fourth temperature control unit 361 ′ and the fifth temperature control unit 362 ′ perform cooling or heating to a set temperature through the second fluid injection to the accommodating module 310 ′, but with the first operation mode and the second temperature control unit 362 ′. The second fluid injection is performed based on the second operation mode, and the second fluid injection is made evenly to the first monitoring unit CM1 and the second monitoring unit CM2 through the second operation mode.

The fourth temperature control unit 361' is provided at a position opposite to the first mounting body 341', and the fifth temperature control unit 362' is provided at a position facing the second mounting body 342'. do. The upward movable module 330' is located on the left side of the third mounting body 370' and the third mounting body 370' which protrude upward and are mounted on the upper part of the accommodating module 310', and protrude upward to the accommodating module. The fourth mounting body 371' and the third mounting body 370' mounted on the upper part of the 310' are located on the right side, and the fifth mounting body (310') protruding upward and mounted on the upper part of the receiving module 310' ( 372').

Based on the second operation mode, at least another part of the first monitoring unit CM1 includes a fourth region facing the fourth temperature control unit 361 ′ and a fifth region facing the fifth temperature control unit 362 ′. It is located in the region to perform fluid injection, and at least another part of the second monitoring unit CM2 faces a fourth region facing the fourth temperature control unit 361 ′ and a fifth temperature control unit 362 ′. It is located in the fifth area where the fluid is sprayed.

The fourth mounting body 371 ′ and the fifth mounting body 372 ′ have a third stop mode and a second operation mode in which the receiving module 310 ′ is pressed with a third intensity preset to abruptly stop the second operating mode. It is possible to operate in the fourth stop mode by pressing the accommodating module 310 ′ with a fourth strength that is weaker than the third strength to gradually stop the .

The first driving panel 351 ′ and the second driving panel 352 ′ are provided to be movable in a second position up and down from the first and second starting modules, and the downward movable module 360 ′ is located in the second position. Based on the movement, the degree of pressing of the third mounting body 370', the fourth mounting body 371', and the fifth mounting body 372' with respect to the accommodation module 310' is reduced or reinforced.

The monitor unit is mounted on the lower portion of the first fixing module 410 ′ and the second pillar module 210 ′ that are mounted on the lower portion of the first column module 110 ′ to fix the position of the first column module 110 ′. It further includes a second fixing module 510' for fixing the position of the second pillar module 210'. The first pillar module 110 ′ is provided with a first extension portion 1101 ′ with a reduced outer circumferential surface at the lower end portion, and the first fixing module 410 ′ includes a lower first body panel 411 ′ and a first 1 It includes a first press-in module 412' provided on both upper sides of the main body panel 411', and a first sub-press-fit module 413' that is provided on both upper sides of the first press-in module 412', respectively. .

The first body panel 411 ′ has a first extension 1101 ′ mounted thereon, and the first press-fit module 412 ′ press-fits the periphery of the first extension 1101 ′ to fix it, and a first sub press-in The module 413' is fixed by press-fitting the periphery of the first column module 110'.

On the other hand, the second column module 210' is provided with a second extension part 2101' with a reduced outer circumferential surface at the lower end portion, and the second fixing module 510' includes a lower second body panel 511', It includes a second press-in module 512' provided on both upper sides of the second body panel 511', and a second sub-press-fit module 513' that is provided on both upper sides of the second press-in module 512', respectively. and the second body panel 511 ′ has a second extension portion 2101 ′ mounted thereon, and the second press-fit module 512 ′ press-fits and fixes the periphery of the second extension portion 2101 ′, and the second The sub press-in module 513' is fixed by press-fitting the periphery of the second column module 210'.

The first sub press-in module 413' and the second sub press-in module 513' perform press-in based on the circumferential rotation in the first press-in module 412' and the second press-in module 512', respectively, The first sub-press-fitting module 413' and the second sub-press-fitting module 513' rotate in the circumferential direction in the first press-in module 412' and the second press-in module 512', respectively. In addition to the circumferential rotation toward the two-pole module 210', the proximity movement is added to perform press-fitting.

A first extension bar 4131' is provided on the upper portion of the first press-in module 412', and a first fixing flange 4132' installed on the upper end of the first extension bar 4131' is provided, and the second press-in module A second extension bar 5131' is provided on the upper portion of the 512', a second fixing flange 5132' installed on the upper end of the second extension bar 5131' is provided, and the first fixing flange 4132' ) is inserted and mounted on the outside of the first column module 110 ', the first extension bar 4131 ' is lowered in the state in which the first column module 110' is inserted and mounted, and the second fixing flange 5132' is The second pillar module 210' is inserted and mounted on the outside, and the second extension bar 5131' descends in a state in which the second pillar module 210' is inserted and mounted.

Based on the descent of the first extension bar (4131') and the second extension bar (5131'), the first fixing flange (4132') and the second fixing flange (5132') are the first pillar modules (110') and the second The two-pole module 210' is pulled downward to give a fixing force. The monitor unit is covered with a storage body 610 ′ having an internal accommodating space, and the storage body 610 ′ is seated on the first fixing flange 4132 ′ and the second fixing flange 5132 ′, and the storage body 610 . ') seals the monitor unit so that the fluid is filled inside according to the fluid injection and the second fluid injection to the management module.

The driving method of the physical components described above is based on a motor, an actuator, etc., and the forward and backward movement and rotational movement are made, and the shape and size of each component can be variously selected and provided according to the installation site and materials to be implemented. .

Although the present invention has been described with reference to the embodiment shown in the drawings, which is merely exemplary, it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible therefrom. Accordingly, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

100: clamp body 110: insertion part
120: bolt hole 130: support hole
200: fixing bolt 300: wire support means
310: support 320: wire contact
330: spring

Claims (2)

In the method of providing a replacement system for a distribution line in an urban area,
Preparing a system for replacing the distribution lines in the downtown area; and
Including the step of installing a replacement system for the distribution line in the downtown area,
The replacement system of the distribution line in the downtown area is managed by a monitor unit,
The replacement system for the distribution line in the downtown area is
An insertion part 110 for inserting one electric wire and another electric wire is formed therein, and at least one bolt hole 120 for inserting a fixing bolt on one side and a support part of the electric wire support means for inserting The clamp body 100 in which the support hole 130 is formed;
at least one fixing bolt 200 inserted into a bolt hole formed on one side of the clamp body to fix one electric wire formed in the insertion part and the other electric wire to the clamp body;
A support part 310 partially inserted into the hole of the support part formed in the clamp body, and a wire contact part 320 formed in parallel to one electric wire and the other electric wire at the end of the support part, and in contact with the end of the fixing bolt, and ,
Wire support means 300 configured to include a spring 330 installed and configured to provide elasticity to the support portion; including,
The monitor unit
Monitors at least one of the manufacturing process, the loading process for installation, the installation process, and the operating state of the replacement system for the distribution line in the downtown area,
The monitor unit,
A bar-shaped first column module 110' located on one side, and
A bar-shaped second column module 210' located on the other side, and
a first driving body 115' installed on the first pillar module 110';
a second driving body 215' installed on the second pillar module 210';
It is installed between opposite sides of the first driving body 115' and the second driving body 215' and includes a bar-shaped accommodating module 310' on which a management module for performing photographing is mounted,
The management module includes a first monitoring unit (CM1) and a second monitoring unit (CM2),
The management module,
It includes a first monitoring unit (CM1) and a second monitoring unit (CM2),
The accommodating module 310 'is,
The first monitoring unit CM1 is mounted on one side and the second monitoring unit CM2 is mounted on the other side, and the set radius is set between the first driving body 115 ′ and the second driving body 215 ′. pivoted,
The monitor unit,
The first sub-pillar module 120' installed on the upper part of the first driving body 115', the second sub-pillar module 220' installed on the upper part of the second driving body 215', and the first The movable panel 320' installed on opposite sides of the sub-pillar module 120' and the second sub-pillar module 220', and the accommodating module 310' installed in the center of the movable panel 320'. Includes an upward movable module 330' for fixing or releasing the fixing,
One side of the movable panel 320' corresponding to the left side of the upper movable module 330' is provided with a first temperature control unit 331' for controlling the temperature of the management module by injecting a fluid into the lower portion,
One side of the movable panel 320' corresponding to the left side of the upper movable module 330' is provided with a second temperature control unit 332' for controlling the temperature of the management module by spraying a fluid on the lower side,
The upper operation module 330 ′ is provided with a third temperature control unit 333 ′ for controlling the temperature of the management module by spraying a fluid thereunder, the method of providing a system for replacing a distribution line in an urban area. delete

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