KR101530037B1 - Distributing connector unit of underground transmission line - Google Patents

Abstract

The present invention relates to the distributing connector device of an underground transmission line. The present invention relates to the distributing connector device of an underground transmission line which protects an underground transmission line from external impact by improving a connecting structure which is connected to an incoming line and an outgoing line, prevents the approach of external organisms, and prevents the short and current leakage of a connector. According to the present invention, because a part to which the incoming line and the outgoing line are connected is flexible and is electrically connected, short can be prevented by absorbing and buffering strong external impact such as earthquake. Moreover, stable power transmission can be maintained by preventing the approach of underground organisms through a disk-type panel.

Description

TECHNICAL FIELD [0001] The present invention relates to a distribution connector apparatus for underground distribution lines. [0002] DISTRIBUTING CONNECTOR UNIT OF UNDERGROUND TRANSMISSION LINE [

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a power distribution connector device for an underground power distribution line, and more particularly, to a connecting structure in which an incoming wire and a lead wire are connected to each other, The present invention relates to an improved distribution connector device for an underground distribution line so as to prevent disconnection or leakage of a connector by blocking an approach of an organism.

Generally, electricity used in each home, office, and large-scale factory is supplied through a substation installed in each region. This substation is installed for the purpose of modifying voltage and current and distributing electric power. Power generated by the power plant will be sent to the customer through the transmission line.

The substation is installed on the ground. In such a substation, the high-voltage electric current should be transferred. Most of the high-voltage electric wires are exposed to the outside, and the high-voltage electric wire exposed to the outside causes short-circuit and short- It is easy to install high voltage wires in the ground because there are problems such as hurting the surrounding scenery due to the high voltage wires that have been erroneously installed.

Such an underground transmission line is installed in an underground pipeline buried in an underground as shown in FIG. 1, and is connected to a ground level distribution board (B) via a connector.

The connector is connected to a lead wire (L ') having one end connected to a lead wire (L) drawn from a power source and the other end taken out of a switchboard (B) so that power is supplied from the power source to the switchboard do.

At this time, the connector is stably fixed to the inner wall of the underground pipe (P) through the support base (F).

However, when an external shock such as an earthquake occurs, the connector is directly connected to the external power generated from the lead wire L and the lead wire L ', and the connector is disconnected, A short circuit occurred and an accident such as electric shock or fire occurred.

On the other hand, when the temperature is low as in the winter season, the mouse may move along the inner wall of the underground pipe P in order to move to the relatively warm distribution cabin C. As a result, the rat moving along the inner wall of the underground pipe P frequently crosses the connector through the support F connected to the connector and damages the connector.

As a result, the connector was easily disconnected, and a short circuit occurred in the disconnected connector.

In order to improve this, Korean Patent Registration No. 10-0905762 (Jun. 25, 2009) "Underground distribution line connector" has been disclosed.

However, in the case of the above-mentioned registered patent, since the connector portions interconnecting the incoming wire and the outgoing wire are rigidly connected to each other, an improved effect can be obtained in terms of prevention of access to the underground creature such as a mouse, There is still a limitation that the rigid connecting part easily breaks when the same strong external impact is transmitted and the risk of disconnection is very high.

Korean Patent Registration No. 10-0905762 (June 25, 2009) "Underground Distribution Line Connector"

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made in view of the above problems, and it is an object of the present invention to provide a connector for connecting a lead wire and a lead wire, And an object of the present invention is to provide a connector for underground transmission line connection which can prevent disconnection or breakage by sufficiently absorbing shock when an excessive impact is applied from the outside such as an earthquake.

According to an aspect of the present invention, there is provided an electric power steering system comprising: an input line (L) drawn in from an electric power source; An underground distribution line connector for interconnecting electric wires L ', wherein the connector is a panel 10 made of an insulating material disposed inside the underground pipe P so as to be disposed between the lead-in wire L and the lead-out wire L' A first connecting portion 22 extending downward from the insertion portion 21 and penetrating the panel 10 and connected to the incoming wire L, And a second connecting portion 23 extending upward from the inserting portion 21 and penetrating the panel 10 and connected to the lead wire L ' And a submerged pipe fixing part 32 fixed to the inner wall of the submerged pipe P, CLAIMS What is claimed is: 1. A distribution connector device for an underground distribution line with at least two springs (30) The lead wire (L) and the lead wire (L ') are hingedly fixed on the switchboard (B) via a hinge pin (100) The lower ends of the lead wires (L) and the lead wires (L ') are connected to the rotator (110) to form an integral body; The rotatable shaft 110 is installed in the housing 200 and is rotatably assembled. A hole is drilled in the center of the rotator 110 in the thickness direction. The rotatable shaft 120 is inserted into the housing 200 And the housing 200 is configured to be hermetically sealed by the cover 210 in a state that one side is opened and the rotatable shaft 120 is integrally protruded from the bottom surface of the housing 200 A pair of left and right sides are provided, and the housing 200 has a rectangular box shape; A bolt hole 230 is formed in the fixing piece 220 and bolts are fixed to a lower end surface of the power distribution board B through bolts. The rotary shaft 110 has a circular shape and is provided with a pair of circumferential surfaces on which an operation cam portion 130 protruding to be opposed to each other is formed and on a peripheral surface opposite to the operation cam portion 130, The fixing portion 140 protrudes to form an integral body; A lead wire (Ln) or lead wire (Ln ') is integrally connected to a part of the periphery of the rotator (110); The lead wire L and the lead wire L 'are wired to the outside of the housing 200 through an upper opening 150 formed in the upper surface of the housing 200; The inlet connection line Ln and the outlet connection line Ln 'are wired to the outside of the housing 200 through a lower end opening 160 formed in a lower end surface of the housing 200; A second connection part 23 is connected to each lower end of the lead-in connection line Ln and the lead-out connection line Ln '; One end of the elastic spring 170 is fixed to the spring fixing part 140 and the other end of the elastic spring 170 is fixed to a part of the inner wall surface of the housing 200; An actuator 300 is rotatably assembled in a space between the pair of rotatable members 110 at the center of the housing 200; A rectangular motor shaft groove 320 is formed in the other end surface of the actuator 300 and a motor shaft 330 is inserted in the motor shaft groove 320. The motor shaft 330 is connected to a driving motor 340 , And the driving motor 340 is fixed to the outer surface of the cover 210; A pair of operating cams 302 protrude from the circumferential surface of the actuator 300; Wherein each of the pair of operation cams (320) is overlapped with the operation cam (130) of the rotator (110) so as to be engaged with each other.

According to the present invention, since the portion to which the lead-in wire and the lead-out wire are connected is in a state in which they can always be energized while having elasticity, even if strong external shock waves such as earthquakes are transmitted, they are absorbed and buffered to prevent these disconnection, It is possible to obtain an effect of maintaining a more stable transmission state by blocking access of underground organisms.

Brief Description of the Drawings Fig. 1 is an exemplary view showing a connection state of a distribution connector device in a ground distribution line according to the prior art.
2 is an exemplary view showing a connection state of a power distribution connector device of an underground distribution line according to the present invention.
3 is a partially enlarged view of a power distribution connector device of an underground distribution line according to the present invention.
4 is a plan view of the main part of Fig.
5 is an operational state diagram of a power distribution connector device for an underground distribution line according to the present invention.
6 is a diagram showing an example of a modification of a panel constituting a distribution connector device for an underground distribution line according to the present invention.

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

Before describing the present invention, the following specific structural or functional descriptions are merely illustrative for the purpose of describing an embodiment according to the concept of the present invention, and embodiments according to the concept of the present invention may be embodied in various forms, And should not be construed as limited to the embodiments described herein.

In addition, since the embodiments according to the concept of the present invention can make various changes and have various forms, specific embodiments are illustrated in the drawings and described in detail herein. However, it should be understood that the embodiments according to the concept of the present invention are not intended to limit the present invention to specific modes of operation, but include all modifications, equivalents and alternatives falling within the spirit and scope of the present invention.

The present invention uses the above-mentioned Patent No. 0905762 mentioned in the prior art as it is. Therefore, all of the features of the device configuration described below are those described in Patent No. 0905762. [

However, the present invention further includes improvements to the connecting structure for connecting the incoming wire and the outgoing wire out of the configurations disclosed in the above-mentioned Japanese Patent Application No. 0905762, and this is the most important configuration characteristic.

Therefore, the device configuration, characteristics and operation relationship described below will be referred to as the contents of the above-mentioned Japanese Patent Application No. 0905762, and the configuration of the panel related to the main feature of the present invention will be described in detail at the rear end.

1 to 5, an underground distribution cable connector according to the present invention includes a panel 10 of an insulating material installed in an underground pipe P, a connecting rod of a conductive material fixed through the panel 10 20 and a spring 30 for elastically supporting the panel 10.

At this time, the underground pipe (P) is buried underground so as to be installed in the vertical direction in the shape of a circular pipe, and the upper part is connected to the cabin (C) installed on the ground with the switchboard (B)

The panel 10 has a circular plate shape having a diameter smaller than that of the underground pipe P according to a preferred embodiment and is connected to the lead wire L 'drawn out from the switchboard B and the power distribution board B, And is inserted between the incoming wires (L) drawn into the submerged pipe (P).

At this time, when the panel 10 has a diameter smaller than that of the underground pipe P, it gives a natural flow when an earthquake occurs, and a mouse riding up the inner wall of the underground pipe P moves to the connecting block 20 This is to prevent it.

The connection block 20 includes an insertion portion 21 inserted into the central portion of the panel 10 in a cross shape and a connection portion 20 extending downward from the insertion portion 21 and connected to the incoming wire L through the panel 10 And a second connection part 23 extending upward from the insertion part 21 and connected to the lead wire L '. At this time, the ends of the first connection part 22, the lead-in wire L, the second connection part 23, and the lead wire L 'are bolted together and connected to each other.

The insertion portion 21 of the connecting rod 20 is formed in a cross shape so that the connecting rod 20 can be stably fixed to the panel 10.

The spring 30 includes a panel fixing portion 31 fixed to the side surface of the panel 10 and an underground pipe fixing portion 32 fixed to the inner wall of the underground pipe P so as to be horizontal with the panel fixing portion 31. [ . At this time, the panel 10 moves downward while being supported by the spring 30, and the panel fixing portion 31 is supported below the underground pipe fixing portion 32 and is elastically supported upward by the spring 30 .

Therefore, when the external force is applied to the plurality of springs 30, the load on the panel 10 is not concentrated on the lead wires L ', and the force applied to the second connecting portions 23 of the connecting rods 20 is weak It becomes.

5, the connecting part 20 and the panel 10 are inserted into the panel 10 such that the insertion part 21 of the connecting part 20 is inserted into the panel 10, And the panel fixing portion 31 of the spring 30 is fixed to the outer surface of the panel 10. [

Subsequently, the underground pipe fixing portion 32 of the spring 30 is fixed to the inner wall of the underground pipe P via the bracket BR. At this time, a plurality of springs 30 are provided and are installed along the outer surface of the panel 10.

When the panel 10 is installed on the submerged pipe P by the plurality of springs 30 as described above, the panel 10, which is to be moved downward due to its own weight, .

Subsequently, the first connecting portion 22 of the connecting rod 20 is bolted to the end of the inlet wire L and the second connecting portion 23 is bolted to the outlet wire L '. At this time, the load of the incoming wire L is dispersed by the plurality of springs 30, and the load applied to the portion where the outgoing wire L 'and the second connecting portion 23 are bolted together is weakened.

When an earthquake occurs in the state as described above, the distribution box (C) and the underground pipe (P) move up and down in accordance with the movement of the ground. At this time, the incoming wire L, the outgoing wire L ', the panel 10, and the connecting rod 20 are vertically moved by the inertia, and the connection between the incoming wire L and the connecting block 20 and the outgoing wire L ', The connecting portion of the connecting block 20, and the connecting portion of the switchboard B and the drawing wire L'.

When the lead wires L, the lead wires L, the panel 10 and the connecting rod 20 move up and down as described above, The panels 10 and the connecting rods 20 are buffered and the force applied to the connecting portions between the respective components is weakened by such a buffering force so that the connecting portions between the respective components are not broken.

The present invention is characterized in that the inner wall of the underground pipe P and the panel 10 are spaced apart from each other by a predetermined distance and the plurality of springs 30 are spaced apart from each other, (20).

This description is an example of the content of the registered patent No. 0905762, which is included in the present invention, and the main features of the present invention are disclosed in Fig. 6, which is a further modified embodiment including such an embodiment.

6, in another embodiment of the present invention, the connection structure of each of the lead wires L and the lead wires L 'is further improved while the structure of the panel 10 is maintained.

That is, as shown in the drawing, the lead wire L and the lead wire L 'are respectively hinged and fixed to the upper portion of the switchboard B via the hinge pin 100 so as to be rotatable.

The lower ends of the incoming wire (L) and the outgoing wire (L ') are connected to the rotator (110) to form an integral body.

At this time, the rotator 110 is housed in the housing 200 and rotatably assembled.

For this purpose, a hole is drilled in the center of the rotator 110 in the thickness direction, and the rotator shaft 120 is integrally formed in the housing 200.

In this case, the housing 200 is configured to be hermetically sealed by the cover 210 in a state that one side thereof is opened, so that the rotatable shaft 120 is integrally protruded from the bottom surface of the housing 200, As shown in the drawing, a pair of left and right sides are provided, and the housing 200 has a substantially rectangular box shape.

The cover 210 is fixed to the housing 200 by being fastened to the housing screw groove 202 of the housing 200 through the cover or through the hole 212, The reason for placing the cover 210 is to facilitate installation of members such as the rotator 110 and the like.

A bolt hole 230 is formed in the fixing piece 220 and a bolt hole is formed in the lower end surface of the distribution board B through a bolt Bolts are fixed.

Particularly, the rotary shaft 110 has a substantially circular shape, and a pair of the rotary shaft 110 is formed. On the pair of circumferential surfaces, a working cam 130 protruding from each other is formed, And a spring fixing portion 140 protrudes from the surface to form an integral body.

In addition, a portion of the periphery of the rotor 110, preferably the lead wire (L) or the lead wire (L '), is connected to the point where the integrally connected portion and the diametrically opposite portion are connected, The connecting line Ln 'is integrally connected.

The inlet wire L and the outlet wire L 'are wired to the outside of the housing 200 through an upper opening 150 formed in an upper end surface of the housing 200. The inlet wire Ln and the outlet wire L' The outgoing connection line Ln 'is wired to the outside of the housing 200 through the lower end opening 160 formed in the lower end surface of the housing 200.

In addition, a second connection part 23 is connected to each lower end of the lead-in connection line Ln and the lead-out connection line Ln '.

One end of the elastic spring 170 is fixed to the spring fixing part 140 and the other end of the elastic spring 170 is fixed to a part of the inner wall surface of the housing 200.

Therefore, the resilient spring 170 elastically rotates and rotates the rotator 110.

Meanwhile, the operator 300 is rotatably assembled to the center of the housing 200, more preferably, the space between the pair of rotatable members 110.

A circular axial protrusion 310 protrudes from the center of one end face of the actuator 300 and the axial protrusion 310 is formed on an axial groove (not shown) formed on the bottom face of the housing 200 So that the actuator 300 can rotate and rotate with the shaft protrusion 310 as a rotation axis.

The motor shaft 330 is inserted into the motor shaft groove 320 and the motor shaft 330 is inserted into the motor shaft 330. The motor shaft 330 is engaged with the motor shaft 330, And the drive motor 340 is fixed to the cover 210. The drive motor 340 is fixed to the cover 210. [

Therefore, the motor shaft 330 is disposed through the motor shaft hole 214 formed in the cover 210, and the driving motor 340 is fixed to the outer surface of the cover 210.

In particular, the drive motor 340 is a stepping motor, which is reciprocally rotated within a certain angle. If the motor is provided with a timer (not shown) and is automatically reciprocated within a predetermined period, the drive motor 340 can operate more smoothly.

In addition, a pair of operation cams 302 protrude from the circumferential surface of the operator 300.

Each of the pair of operation cams 320 is configured to overlap with the operation cam portion 130 of the rotator 110 while being overlapped with each other.

In addition, a housing stopper HST may be formed at a position adjacent to the top opening 150 of the housing 200 to limit the turning radius of the rotator 110, And a rotor stopper RST which is engaged with the housing stopper HST can be formed to protrude from the periphery.

When the actuator 300 reciprocates in a clockwise or counterclockwise direction within a predetermined angle by driving the driving motor 340, the actuating cam 302 is rotated by the operating cam portion 130 and so that the rotor 110 rotates to rotate the inlet and outlet wires L and L 'and the inlet and outlet connection lines Ln and Ln' in opposite directions to each other do.

Then, the inserting / outgoing wires (L, L ') are rotated with respect to the switchboard (B) with respect to the rotating pin (100), so that a mouse or the like is shaken so as not to enter the panel (10).

In addition, such swinging, that is, rotational flow, imparts fluidity to the wires, so that even when a sudden change in tension of the wire is absorbed, the risk of disconnection is prevented.

10; Panel 20; Connections
30; spring

Claims (1)

A ground distribution line connector (hereinafter referred to as " ground distribution line connector ") which is inserted in an underground pipeline P communicating with the power distribution box C installed on the ground and connects the lead- ing line L drawn from the power source and the lead- , Wherein the connector comprises a panel (10) made of an insulating material and disposed inside the underground pipe (P) so as to be disposed between the lead wire (L) and the lead wire (L ' A first connection part 22 extending downward from the insertion part 21 and penetrating the panel 10 and connected to the lead wire L and a second connection part 22 extending upward from the insertion part 21, And a second connection part 23 connected to the lead wire L 'through the first connection part 10 and the panel fixing part 31 fixed to the side surface of the panel 10, And at least two springs (30) constituted by an underground pipe fixing portion (32) fixed to the inner wall of the pipe (P) In the power distribution device connector of a spring underground distribution line;
The lead wire (L) and the lead wire (L ') are hingedly fixed on the switchboard (B) via a hinge pin (100)
The lower ends of the lead wires (L) and the lead wires (L ') are connected to the rotator (110) to form an integral body;
The rotatable shaft 110 is installed in the housing 200 and is rotatably assembled. A hole is drilled in the center of the rotator 110 in the thickness direction. The rotatable shaft 120 is inserted into the housing 200 And the housing 200 is configured to be hermetically sealed by the cover 210 in a state that one side is opened and the rotatable shaft 120 is integrally protruded from the bottom surface of the housing 200 A pair of left and right sides are provided, and the housing 200 has a rectangular box shape;
A bolt hole 230 is formed in the fixing piece 220 and bolts are fixed to a lower end surface of the power distribution board B through bolts.
The rotary shaft 110 has a circular shape and is provided with a pair of circumferential surfaces on which an operation cam portion 130 protruding to be opposed to each other is formed and on a peripheral surface opposite to the operation cam portion 130, The fixing portion 140 protrudes to form an integral body;
A lead wire (Ln) or lead wire (Ln ') is integrally connected to a part of the periphery of the rotator (110);
The lead wire L and the lead wire L 'are wired to the outside of the housing 200 through an upper opening 150 formed in the upper surface of the housing 200;
The inlet connection line Ln and the outlet connection line Ln 'are wired to the outside of the housing 200 through a lower end opening 160 formed in a lower end surface of the housing 200;
A second connection part 23 is connected to each lower end of the lead-in connection line Ln and the lead-out connection line Ln ';
One end of the elastic spring 170 is fixed to the spring fixing part 140 and the other end of the elastic spring 170 is fixed to a part of the inner wall surface of the housing 200;
An actuator 300 is rotatably assembled in a space between the pair of rotatable members 110 at the center of the housing 200;
A rectangular motor shaft groove 320 is formed in the other end surface of the actuator 300 and a motor shaft 330 is inserted in the motor shaft groove 320. The motor shaft 330 is connected to a driving motor 340 , And the driving motor 340 is fixed to the outer surface of the cover 210;
A pair of operating cams 302 protrude from the circumferential surface of the actuator 300;
Wherein each of the pair of operation cams (320) is configured to overlap with the operation cam portion (130) of the rotator (110) so as to be engaged with each other.

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