KR102582144B1 - Fixing Equipment for Overhead Line - Google Patents

Abstract

The present invention relates to an insulator-mounted fixture for connecting overhead distribution lines,
An installation space (11) formed in the left and right directions inside the complete iron (10) and open on the left and right sides; A guide hole (12) is formed on the lower surface of the complete iron (10) in the left and right directions, the left and upper and lower sides are open, the right side is formed to be located to the right of the electric pole (P), and the upper side communicates with the installation space (11). each complete iron (10) installed facing each other front and rear at the top of the electric pole (P), each equipped with ;;
Each complete iron damage prevention mechanism 60 is formed in a 'ㅁ' shaped pipe shape and is removably installed on the left end of the complete iron 10, and limits the movement of the moving mechanism 30;
A 'ㄷ'-shaped connecting plate (21) that is removably installed on the full-bar damage prevention mechanism (60) and arranged laterally, the full-bar damage prevention mechanism (60), the guide hole (12), and the connecting plate (21). A fastening rod 22 penetrating, a fastening body 23 fastened to the fastening rod 22 to secure the complete iron damage prevention mechanism 60 and the connecting plate 21 to the complete iron 10, and the connecting plate 21. ), each suspension insulator (20) installed on the complete iron (10) and equipped with an insulator (24) installed in the transverse direction;
A support insulator (20') installed on the upper right end of one of the complete irons (10) and positioned to the right of the guide hole (12) of the complete iron (10);
An insertion part (31a) movable to the left and right in the installation space (11) of the complete iron (10), and a protrusion that protrudes downward from the insertion part (31a) and passes through the guide hole (12) of the complete iron (10). A moving member (31) having (31b) and a fastening portion (31c) connected to the protrusion (31b) and disposed on the upper surface of the complete iron (10), the front and rear width of which is larger than the front and rear width of the guide hole (12); A rotating shaft 32 rotatably installed in the insertion portion 31a and protruding to the left; The lower end is connected to the rotating shaft 32, and a screw groove 33a with an open front side is formed on the upper side of the connecting body 33. As the rotating shaft 32 rotates, the screw groove 33a is connected to the screw shaft 42. A connecting body (33) that is engaged or disengaged with the thread (42a) of; Each moving mechanism (30) provided with a linkage rotating device (34) installed in the insertion portion (31a) and rotating the rotating shaft (32);
A support bar (41) installed in the installation space (11) of the complete iron (10); A screw shaft 42 having a screw thread 42a formed thereon and rotatably installed on the support 41; A screw shaft rotation device (43) is installed in the installation space (11) of the complete iron (10) located to the right of the electric pole (P) and rotates the screw shaft (42), and the screw groove of the connecting body (33) (33a) and the screw thread (42a) of the screw shaft (42) are engaged, and when the screw shaft rotation device (43) is driven, each moving mechanism transfer device (40) transfers the connecting body (33) to the left and right, and ;
First and second fastening bars (51, 51') respectively detachably installed on the fastening portions (31c) of each moving mechanism (30); First and second vertical bars (52 and 52') respectively installed to protrude downward on the first and second fastening bars (51 and 51'); A jumper wire support installation device (50) equipped with a horizontal bar (53) connecting the first and second vertical bars (52, 52'), and:
A jumper wire supporter (70) equipped with a support bar (71) installed on the horizontal bar (53) and protruding downward, and a seat (72) installed on the lower side of the support bar (71) on which the jumper wire (J) is placed. and;
A remote controller that communicates remotely with each linkage rotation device (34) and each screw shaft rotation device (43) and controls the operation of each linkage rotation device (34) and each screw shaft rotation device (43). (80)
It is characterized by including.

Description

Insulator-mounted fixing equipment for connecting overhead distribution lines {Fixing Equipment for Overhead Line}

The present invention relates to an insulator-mounted fixture for connecting overhead distribution lines.

In general, an overhead distribution line (1) is installed on a utility pole through wire iron (2) and a suspension insulator (3), as shown in FIG. 1, and power is distributed from the installed overhead distribution line (1) to each customer.

At this time, the connection between the overhead distribution line (1) and the overhead distribution line (1) is made through a jumper wire (4). Conventionally, the jumper wire (4) may interfere with surrounding objects, so the jumper wire (4) is safely used. It was difficult to support.

In addition, in the past, insulators were installed on both sides of a complete iron, and space remained between the insulators, so there was a problem that the space between the insulators was wasted.

Republic of Korea Patent Publication No. 10-2206803

The present invention was invented to solve the above problems, safely supporting the jumper wire (J), ensuring the structural safety of the complete iron (10), and maintaining the gap between the suspension insulator (20) and the support insulator (20'). By utilizing the space of the complete iron (10), the placement position of the jumper wire support (70) can be adjusted in various ways, and the moving mechanism (30) for moving the jumper wire support (70) can be easily installed and uninstalled on the complete iron (10). The problem to be solved is to provide an 'insulator-mounted fixture for connecting overhead distribution cables'.

The present invention to solve the above problems,

An installation space (11) formed in the left and right directions inside the complete iron (10) and open on the left and right sides; A guide hole (12) is formed on the lower surface of the complete iron (10) in the left and right directions, the left and upper and lower sides are open, the right side is formed to be located to the right of the electric pole (P), and the upper side communicates with the installation space (11). each complete iron (10) installed facing each other front and rear at the top of the electric pole (P), each equipped with ;;

Each complete iron damage prevention mechanism 60 is formed in a 'ㅁ' shaped pipe shape and is removably installed on the left end of the complete iron 10, and limits the movement of the moving mechanism 30;

A 'ㄷ'-shaped connecting plate (21) that is removably installed on the full-bar damage prevention mechanism (60) and arranged laterally, the full-bar damage prevention mechanism (60), the guide hole (12), and the connecting plate (21). A fastening rod 22 penetrating, a fastening body 23 fastened to the fastening rod 22 to secure the complete iron damage prevention mechanism 60 and the connecting plate 21 to the complete iron 10, and the connecting plate 21. ), each suspension insulator (20) installed on the complete iron (10) and equipped with an insulator (24) installed in the transverse direction;

A support insulator (20') installed on the upper right end of one of the complete irons (10) and positioned to the right of the guide hole (12) of the complete iron (10);

An insertion part (31a) movable to the left and right in the installation space (11) of the complete iron (10), and a protrusion that protrudes downward from the insertion part (31a) and passes through the guide hole (12) of the complete iron (10). (31b) and a moving member (31) connected to the protrusion (31b) and disposed on the upper surface of the complete iron (10), and having a fastening part (31c) whose front and rear width is larger than the front and rear width of the guide hole (12); A rotating shaft 32 rotatably installed in the insertion portion 31a and protruding to the left; The lower end is connected to the rotating shaft 32, and a screw groove 33a with an open front side is formed on the upper side of the connecting body 33, and as the rotating shaft 32 rotates, the screw groove 33a is connected to the screw shaft 42. A connecting body (33) that is engaged or disengaged with the thread (42a) of; Each moving mechanism (30) provided with a linkage rotating device (34) installed in the insertion portion (31a) and rotating the rotating shaft (32);

A support bar (41) installed in the installation space (11) of the complete iron (10); A screw shaft 42 having a screw thread 42a formed thereon and rotatably installed on the support 41; A screw shaft rotation device (43) is installed in the installation space (11) of the complete iron (10) located to the right of the electric pole (P) and rotates the screw shaft (42), and the screw groove of the connector (33) (33a) and the screw thread (42a) of the screw shaft (42) are engaged, and when the screw shaft rotation device (43) is driven, each moving mechanism transfer device (40) transfers the connecting body (33) to the left and right, and ;

First and second fastening bars (51, 51') respectively detachably installed on the fastening portions (31c) of each moving mechanism (30); First and second vertical bars (52 and 52') respectively installed to protrude downward on the first and second fastening bars (51 and 51'); A jumper wire support installation device (50) equipped with a horizontal bar (53) connecting the first and second vertical bars (52, 52'), and:

A jumper wire supporter (70) equipped with a support bar (71) installed on the horizontal bar (53) and protruding downward, and a seat (72) installed on the lower side of the support bar (71) on which the jumper wire (J) is placed. and;

A remote controller that communicates remotely with each linkage rotation device (34) and each screw shaft rotation device (43) and controls the operation of each linkage rotation device (34) and each screw shaft rotation device (43). (80)

It is characterized by including.

The present invention according to a means of solving the above problem has the effect of safely supporting the jumper wire (J) via the jumper wire support (70) when the overhead distribution wire (L) is supported by the suspension insulator (20). there is.

In addition, the present invention has the effect of adjusting the position of the jumper wire support 70, so that the jumper wire J and the jumper wire support 70 can be safely supported without interfering with surrounding objects.

In addition, the present invention allows the jumper wire support installation mechanism 50 to be detached from the moving mechanism 30, so that when moving the moving mechanism 30 through the electric pole (P), the jumper wire support installation mechanism 50 By separating and moving from the moving mechanism 30, there is an effect that the moving mechanism 30 and the jumper wire support installation mechanism 50 can be freely moved.

In addition, the present invention utilizes the space of the complete iron (10) between the suspension insulator (20) and the support insulator (20') to efficiently utilize the space of the complete iron (10) and conveniently move the position of the jumper wire support (70). There is an effect that can be done.

In addition, the present invention has the effect of stably installing the jumper wire support installation mechanism (50) on the moving mechanism (30) by consisting of a pair of complete iron (10), a moving mechanism (30), and a moving mechanism transfer device (40). There is.

In addition, in the present invention, a guide hole 12 with an opening on the left side (one side) is formed in the complete iron 10, so that the moving mechanism 30 for moving the position of the jumper wire support 70 is conveniently used in the complete iron 10. It has the effect of being able to install and uninstall easily. At this time, the present invention allows only the left side (one side) of the guide hole 12 to be opened, thereby minimizing the decrease in structural safety of the complete iron 10.

In addition, in the present invention, a damage prevention mechanism 60 is installed at the left end of the complete iron 30, so that when an external force is applied to the complete iron 30, the complete iron 30 is torn in the direction of forming the guide hole 12. While preventing the moving mechanism 30 from colliding with the support 41 due to malfunction of the screw shaft rotation device 43 or the moving mechanism 30 from breaking away from the complete iron 10 after destroying the support 41. There is an effect.

In addition, the present invention, when supplementing the structural stability of the complete iron 10 through the complete iron damage prevention mechanism 60, the fastening rod 22 of the suspension insulator 20 is used to prevent damage to the complete iron 60 and the complete iron 10. ) and the connection plate 21, the suspension insulator 20 is installed on the complete iron 10, which has the effect of further compensating for the decrease in structural safety of the complete iron 10 due to the guide hole 12.

1 is a diagram for explaining the prior art,
Figure 2 is an overall perspective view for explaining the present invention,
Figure 3 is a perspective view showing the suspension insulator part in the present invention,
Figure 4 is a perspective view showing the moving mechanism portion of Figure 2 turned over;
Figure 5 is an exploded perspective view showing a partial configuration of the moving mechanism and the moving mechanism transfer device of the present invention upside down;
Figure 6 is an exploded perspective view showing the moving mechanism of the present invention upside down,
Figure 7 is a left side view for explaining the connection relationship between the complete iron and moving mechanism and the moving mechanism transport device in the present invention;
Figure 8 is a partial front cross-sectional view for explaining the connection relationship between the complete iron and moving mechanism and the moving mechanism transport device in the present invention;
Figure 9 is a control configuration diagram for explaining the connection between electrical components of the present invention;
10 and 11 are diagrams for explaining the operation of the present invention.

Hereinafter, the present invention will be described so that those skilled in the art can easily practice it.

Figure 2 is an overall perspective view for explaining the present invention, Figure 3 is a perspective view showing the suspension insulator part of the present invention, Figure 4 is a perspective view showing the moving mechanism part of Figure 2 turned over, and Figure 5 is a moving mechanism of the present invention. and an exploded perspective view showing some of the configurations of the mobile device transport device upside down, Figure 6 is an exploded perspective view showing the mobile device of the present invention upside down, and Figure 7 shows the connection relationship between the complete iron and the mobile device and the mobile device transport device in the present invention. It is a left side view for explanation, Figure 8 is a partial front cross-sectional view for explaining the connection relationship between the complete iron and moving mechanism and the moving mechanism transfer device in the present invention, and Figure 9 is a control configuration for explaining the connection between the electrical components of the present invention. As a diagram, the configuration of the present invention will be described with reference to FIGS. 2 to 9 as follows. Meanwhile, in the present invention, the ), the direction of the configuration of the present invention is explained.

The insulator-mounted fixing mechanism for connecting overhead distribution lines according to the present invention includes each complete iron (10), each complete iron damage prevention mechanism (60), each suspension insulator (20), and a support insulator (20') , each moving mechanism 30, each moving mechanism transfer device 40, a jumper wire support installation mechanism 50, a jumper wire support 70, and a remote controller 80.

As shown in FIGS. 2, 3, 4, and 5, the complete iron 10 is provided with an installation space 11 and a guide hole 12, and is installed front and rear at the top of the electric pole (P). They are installed opposite to each other. In the present invention, as shown in FIG. 5, the complete iron 10 includes a suspension insulator 20 installation section a1, a jumper wire support 70 installation section a2, and a support insulator 20' installation section ( It can be divided into a3).

The installation space 11 is formed on the left and right inside the complete iron 10, and the left and right sides are open. In the present invention, the complete iron 10 is formed in the shape of a square pipe and is provided with an installation space 11.

The guide hole 12 is formed in the left and right directions on the lower surface of the complete iron 10, and is open on the left and upper and lower sides, and the right side is formed to be located to the right of the electric pole (P), and the upper side is the installation space 11. communicates with

Meanwhile, in the present invention, the central portion of the complete iron 10 is installed at the top of the electric pole (P).

As shown in FIGS. 2, 3, and 7, the complete iron damage prevention mechanism 60 is removably installed on the left end of the complete iron 10 in the shape of a 'ㅁ'-shaped pipe, and the moving mechanism 30 restrict the movement of Meanwhile, in the present invention, the complete iron damage prevention mechanism 60 can be installed on the complete iron 10 in various plate shapes as long as it can limit the movement of the moving mechanism 30.

As shown in FIGS. 2 and 3, the suspension insulator 20 is equipped with a connecting plate 21, a fastening rod 22, a fastening body 23, and an insulator 24, and is made of complete iron. It is installed at (10).

The connection plate 21 is removably installed on the complete iron damage prevention mechanism 60 and is disposed in the transverse direction. In the present invention, the connection plate 21 forms a 'ㄷ' shape.

The fastening rod 22 penetrates the complete iron damage prevention mechanism 60, the guide hole 12, and the connecting plate 21. In the present invention, the fastening rod 22 can have various bar shapes.

The fastening body 23 is fastened to the fastening rod 22 to fix the complete iron damage prevention mechanism 60 and the connecting plate 21 to the complete iron 10. In the present invention, the fastening body 23 has a nut shape, and the fastening rod 22 and the fastening body 23 are threaded, but the fastening method of the fastening rod 22 and the fastening body 23 can be modified in various ways. You can.

The insulator 24 is installed on the connecting plate 21 and arranged in the horizontal direction. In the present invention, the insulator 24 is equipped with a plurality of insulators.

Meanwhile, in the present invention, an overhead distribution line (L) is installed on the suspension insulator (20).

As shown in FIG. 2, the support insulator 20' is installed on the upper right end of one of the complete irons 10 and is located to the right of the guide hole 12 of the corresponding complete iron 10. In the present invention, the support insulator (20') is installed on the complete iron (10) located at the front of the complete iron (10). Additionally, in the present invention, an overhead distribution line (L) is disposed at the top of the support insulator (20'). Meanwhile, in the present invention, the support insulator 20' is of the LP insulator type, but may be installed on the side of the iron 10 as a suspension insulator so as to be arranged in the transverse direction (not shown).

As shown in FIGS. 2, 3, 4, 5, 6, 7, and 8, the moving mechanism 30 includes a moving member 31, a rotating shaft 32, and a connection body ( 33) and a linkage rotation device (34).

The moving member 31 includes an insertion portion 31a movably installed in the installation space 11 of the complete iron 10 to the left and right, and a guide for the complete iron 10 that protrudes downward from the insertion portion 31a. It has a protrusion 31b passing through the hole 12, and a fastening part 31c connected to the protrusion 31b, disposed on the upper surface of the complete iron 10, and having a front-to-back width greater than the front-to-back width of the guide hole 12. In the present invention, since the front and rear width of the fastening part 31c is larger than the front and rear width of the guide hole 12, the moving member 31 is prevented from tipping over when an external force acts on the moving member 31 forward and backward. Additionally, in the present invention, the insertion portion 31a is preferably provided so that its front and rear width is larger than the front and rear width of the guide hole 12.

The rotation shaft 32 is rotatably installed in the insertion portion 31a and protrudes to the left.

The lower end of the connecting body 33 is connected to the rotating shaft 32, and a screw groove 33a with an open front side is formed on the upper side of the connecting body 33. As the rotating shaft 32 rotates, the screw groove (33a) is formed. 33a) is engaged or disengaged with the thread 42a of the screw shaft 42. In the present invention, the connecting body 33 forms a cam shape whose width narrows upward when viewed from the side.

The linkage rotating device 34 is built into the insertion portion 31a and rotates the rotating shaft 32. In the present invention, the connecting body rotation device 34 may be a motor. In addition, in the present invention, the connecting body rotation device 34 can be supplied with power in various forms, such as having its own battery built in or receiving power from an external source.

Meanwhile, in the present invention, a plurality of moving mechanisms 30 may be provided, and when a plurality of moving mechanisms 30 are provided, the linkage rotation device 34 of each moving mechanism 30 is connected to the remote controller 80. It is individually controlled by.

As shown in FIGS. 5, 7, and 8, the mobile device transfer device 40 includes a support 41, a screw shaft 42, and a screw rotation device 43.

The support 41 is installed in the installation space 11 of the complete iron 10. In the present invention, the support 41 may be provided on the left and right sides of the screw shaft 42, respectively.

The screw shaft 42 has a screw thread 42a and is rotatably installed on the support 41.

The screw shaft rotating device 43 is installed in the installation space 11 of the complete iron 10 to the right of the electric pole P, and rotates the screw shaft 42. In the present invention, the screw shaft rotating device 43 may be a motor. In addition, in the present invention, the screw shaft rotating device 43 may be supplied with power in various forms, such as having its own battery built in or receiving power from an external source.

Meanwhile, in the present invention, the moving mechanism transfer device 40 drives the screw shaft rotation device 43 in a state in which the screw groove 33a of the connecting body 33 and the thread 42a of the screw shaft 42 are engaged. When this happens, the connecting body (33) is transferred to the left and right.

As shown in FIGS. 2, 3, and 4, the jumper wire support installation mechanism 50 includes first and second fastening bars 51 and 51' and first and second vertical bars 52 and 52'. ) and a horizontal bar (53).

The first and second fastening bars 51 and 51' are detachably installed on the fastening portions 31c of each moving mechanism 30, respectively. In the present invention, the first fastening bar 51 is installed on the fastening part 31c of the moving mechanism 30 located at the front of the moving mechanism 30, and the second fastening bar 51' is installed on the fastening part 31c of the moving mechanism 30. It is installed on the fastening part 31c of the moving mechanism 30 located at the rear. In the present invention, the first and second fastening bars 51 and 51' are respectively threadedly fastened to the fastening portion 31c.

The first and second vertical bars 52 and 52' are respectively installed to protrude downward from the first and second fastening bars 51 and 51'. In the present invention, the first and second vertical bars 52 and 52' are rotatably installed on the first and second fastening bars 51 and 51', respectively.

The horizontal bar 53 connects the first and second vertical bars 52 and 52'. In the present invention, the first and second vertical bars 52 and 52' can be detachably installed on the horizontal bar 53.

The jumper wire support 70 is equipped with a support bar 71 and a seating base 72, as shown in FIGS. 2, 3, and 4.

The support bar 71 is installed on the horizontal bar 53 and protrudes downward. In the present invention, the support bar 71 is arranged in the vertical direction. Additionally, in the present invention, the support bar 71 may be installed on the horizontal bar 53 to be rotatable clockwise or counterclockwise. And in the present invention, the support bar 71 may be provided to have its length adjustable in the vertical direction.

The seating stand 72 is installed on the lower side of the support bar 71 and a jumper wire (J) is disposed. In the present invention, the seating base 72 can have various shapes as long as the jumper wire (J) can be arranged.

As shown in FIG. 9, the remote controller 80 communicates remotely with each linkage rotation device 34 and each screw shaft rotation device 43, so that each linkage rotation device 34 and Controls the operation of each screw shaft rotation device (43). In the present invention, the remote controller 80 may be in the form of a portable terminal. Meanwhile, in the present invention, the remote controller 80, the connection rotation device 34, and the screw shaft rotation device 43 are equipped with a communication unit (not shown) for communication, and the remote controller 80 and the connection rotation device 43 are provided with a communication unit (not shown) for communication. Communication is made between (34), and communication is made between the remote controller (80) and the screw shaft rotation device (43). Additionally, in the present invention, the remote controller 80 is provided with an input unit (not shown) for signal input and a display unit (not shown) that indicates the operating status of the components controlled by the remote controller 80.

FIGS. 10 and 11 are diagrams for explaining the operation of the present invention. The operation of the present invention is explained with reference to FIGS. 10 and 11 as follows.

The present invention supports the overhead distribution line (L) through the suspension insulator (20) as shown in Figure 2, and jumper wire ( J) can be safely supported.

On the other hand, when the present invention is installed as shown in FIG. 2, when the position of the jumper wire support 70 needs to be adjusted to avoid interference with surrounding objects, the operator can use the remote controller 80 to adjust the connection rotation device 34. is driven to rotate the connecting body 33 clockwise, so that the connecting body 33 and the screw shaft 42 are maintained in a screw-coupled state.

Thereafter, when the operator drives the screw shaft rotation device 43 through the remote controller 80 to rotate the screw shaft 42 in the forward or reverse direction, the moving member 31 along with the connection body 33 moves to the left or right. Move to , and through this, the jumper wire support 70 can be placed in a necessary position (a position to avoid interference with surrounding objects).

In this way, when the jumper wire support 70 is placed at the required position, the worker drives the connecting body rotating device 34 through the remote controller 80 to ensure that the connecting body 33 and the screw shaft 42 are screwed together. to be maintained or released (see Figure 10).

At this time, when the screw connection state of the connector 33 and the screw shaft 42 is released, the worker, if necessary, separates the complete iron damage prevention mechanism 60 from the complete iron 10 and then moves the moving mechanism 30 to the complete iron. (10) It can be easily removed to the outside.

On the other hand, if the screw shaft rotating device 43 malfunctions, the moving mechanism 30 may continue to move to the left due to the rotation of the screw shaft 42.

However, in the case of the present invention, even if the twist shaft rotation device 43 malfunctions, the movement of the moving mechanism 30 is restricted by the complete iron damage prevention mechanism 60 as shown in FIG. 11, and the moving mechanism 30 is ) do not deviate from the

The present invention as described above has the effect of safely supporting the jumper wire (J) via the jumper wire support (70) when the overhead distribution wire (L) is supported by the suspension insulator (20).

In addition, the present invention has the effect of adjusting the position of the jumper wire support 70, so that the jumper wire J and the jumper wire support 70 can be safely supported without interfering with surrounding objects.

In addition, the present invention allows the jumper wire support installation mechanism 50 to be detached from the moving mechanism 30, so that when moving the moving mechanism 30 through the electric pole (P), the jumper wire support installation mechanism 50 By separating and moving from the moving mechanism 30, there is an effect that the moving mechanism 30 and the jumper wire support installation mechanism 50 can be freely moved.

In addition, the present invention utilizes the space of the complete iron (10) between the suspension insulator (20) and the support insulator (20') to efficiently utilize the space of the complete iron (10) and conveniently move the position of the jumper wire support (70). There is an effect that can be done.

In addition, the present invention has the effect of stably installing the jumper wire support installation mechanism (50) on the moving mechanism (30) by consisting of a pair of complete iron (10), a moving mechanism (30), and a moving mechanism transfer device (40). There is.

In addition, in the present invention, a guide hole 12 with an opening on the left side (one side) is formed in the complete iron 10, so that the moving mechanism 30 for moving the position of the jumper wire support 70 is conveniently used in the complete iron 10. It has the effect of being able to install and uninstall easily. At this time, the present invention allows only the left side (one side) of the guide hole 12 to be opened, thereby minimizing the decrease in structural safety of the complete iron 10.

In addition, in the present invention, a damage prevention mechanism 60 is installed at the left end of the complete iron 30, so that when an external force is applied to the complete iron 30, the complete iron 30 is torn in the direction of forming the guide hole 12. While preventing the moving mechanism 30 from colliding with the support 41 due to malfunction of the screw shaft rotation device 43 or the moving mechanism 30 from breaking away from the complete iron 10 after destroying the support 41. There is an effect.

In addition, the present invention, when supplementing the structural stability of the complete iron 10 through the complete iron damage prevention mechanism 60, the fastening rod 22 of the suspension insulator 20 is used to prevent damage to the complete iron 60 and the complete iron 10. ) and the connection plate 21, the suspension insulator 20 is installed on the complete iron 10, which has the effect of further compensating for the decrease in structural safety of the complete iron 10 due to the guide hole 12.

Meanwhile, the present invention has a structure that electrically connects overhead distribution lines (L) via jumper wires (J), and further includes various configurations for overhead distribution, such as controlling the lateral position movement of the jumper wire (J). In this sense, the title and subject matter of the present invention are defined as 'insulator-mounted fixing device for connecting overhead distribution lines.'

10: Wancheol 20: Susooaeja
20': Supporter 30: Mobile device
40: Mobile device transfer device 50: Jumper wire support installation device
60: Complete iron damage prevention mechanism 70: Jumper wire support
80: remote controller

Claims (1)

An installation space (11) formed in the left and right directions inside the complete iron (10) and open on the left and right sides; A guide hole (12) is formed on the lower surface of the complete iron (10) in the left and right directions, the left and upper and lower sides are open, the right side is formed to be located to the right of the electric pole (P), and the upper side communicates with the installation space (11). each complete iron (10) installed facing each other front and rear at the top of the electric pole (P), each equipped with ;;
Each complete iron damage prevention mechanism 60 is formed in a 'ㅁ' shaped pipe shape and is removably installed on the left end of the complete iron 10, and limits the movement of the moving mechanism 30;
A 'ㄷ'-shaped connecting plate (21) that is removably installed on the full-bar damage prevention mechanism (60) and arranged laterally, the full-bar damage prevention mechanism (60), the guide hole (12), and the connecting plate (21). A fastening rod 22 penetrating, a fastening body 23 fastened to the fastening rod 22 to secure the complete iron damage prevention mechanism 60 and the connecting plate 21 to the complete iron 10, and the connecting plate 21. ), each suspension insulator (20) installed on the complete iron (10) and equipped with an insulator (24) installed in the transverse direction;
A support insulator (20') installed on the upper right end of one of the complete irons (10) and positioned to the right of the guide hole (12) of the complete iron (10);
An insertion part (31a) movable to the left and right in the installation space (11) of the complete iron (10), and a protrusion that protrudes downward from the insertion part (31a) and passes through the guide hole (12) of the complete iron (10). (31b) and a moving member (31) connected to the protrusion (31b) and disposed on the upper surface of the complete iron (10), and having a fastening part (31c) whose front and rear width is larger than the front and rear width of the guide hole (12); A rotating shaft 32 rotatably installed in the insertion portion 31a and protruding to the left; The lower end is connected to the rotating shaft 32, and a screw groove 33a with an open front side is formed on the upper side of the connecting body 33, and as the rotating shaft 32 rotates, the screw groove 33a is connected to the screw shaft 42. A connecting body (33) that is engaged or disengaged with the thread (42a) of; Each moving mechanism (30) provided with a linkage rotating device (34) installed in the insertion portion (31a) and rotating the rotating shaft (32);
A support bar (41) installed in the installation space (11) of the complete iron (10); A screw shaft 42 having a screw thread 42a formed thereon and rotatably installed on the support 41; A screw shaft rotation device (43) is installed in the installation space (11) of the complete iron (10) located to the right of the electric pole (P) and rotates the screw shaft (42), and the screw groove of the connector (33) (33a) and the screw thread (42a) of the screw shaft (42) are engaged, and when the screw shaft rotation device (43) is driven, each moving mechanism transfer device (40) transfers the connecting body (33) to the left and right, and ;
First and second fastening bars (51, 51') respectively detachably installed on the fastening portions (31c) of each moving mechanism (30); First and second vertical bars (52 and 52') respectively installed to protrude downward on the first and second fastening bars (51 and 51'); A jumper wire support installation device (50) equipped with a horizontal bar (53) connecting the first and second vertical bars (52, 52'), and:
A jumper wire supporter (70) equipped with a support bar (71) installed on the horizontal bar (53) and protruding downward, and a seat (72) installed on the lower side of the support bar (71) on which the jumper wire (J) is placed. and;
A remote controller that communicates remotely with each linkage rotation device (34) and each screw shaft rotation device (43) and controls the operation of each linkage rotation device (34) and each screw shaft rotation device (43). (80)
An insulator-mounted fixture for connecting overhead distribution lines, comprising: