KR101017132B1 - An underground transmission line is case - Google Patents

Abstract

PURPOSE: An underground transmission line exclusive protection housing is provided to prevent the damage and cut due to the earthquake by securing the underground transmission line to the securing block. CONSTITUTION: An underground transmission line exclusive protection housing comprises a case(10), a base(20), a securing block(30), a combining block(40), a controller(70), and a buffer damper(90). A case is of rectangular shape. The underground transmission line(1) is connected to the base. The securing block forms the T shape.

Description

Underground Transmission Line Is Case}

The present invention relates to a protective enclosure dedicated to the underground transmission line.

In general, power lines are installed in the telephone poles or buried in the ground to supply electricity. The ground and aerial construction method is more economical than construction in the ground in consideration of constructability, required construction cost, and construction period. There is an advantage that can be simplified, but the building is very close to the dense place, such as downtown, the installation is quite difficult disadvantages, when installed in the underground or in the case of demanding high current in the city.

In the case of the method of embedding in the underground, when connecting the wire and the wire to the wire sheathed stripping of the wire and then twisted together, and the outer surface of the connected portion to protect the insulation tape wrapped, this work method is the diameter of the wire This is possible in the case of thin, but if the diameter is thick installation is difficult.

In addition, most of the wires are simply wired, so when an earthquake occurs, the underground cable is severely shaken from side to side due to transverse waves, and strong tensile force is generated between the underground wires, which short-circuits the joints of the underground wires. Research is actively underway.

The present invention has been made in order to solve the above problems, to protect the joints of the underground transmission line to be connected to the wires from short-circuit from the external force, and to freely change the position and length of the underground cable during the earthquake in the transverse direction The purpose is to provide a protective enclosure for underground cable entry that can protect joints between cables.

The present invention for achieving the above object,

A case part including a door part:

A fixing member fixed to the inside of the case by means of a fastening member having a guide groove formed along a longitudinal direction at the center of the upper surface;

Insulation consisting of a coupling protrusion formed on the bottom surface and a guide member which is provided with a longitudinal groove on one side and is arranged to face each other on the upper surface, and is movable to be installed through the coupling protrusion in the guide groove of the fixing member. Base of material:

A fixing part for electrically connecting the underground transmission line; It consists of a connecting portion which is connected to the outer surface of the fixed portion and disposed in front of the guide member, and fixed on the base, the fixed shape of the conductive material, the overall shape of the T-shape:

A connection part detachably coupled to the connection part; A protrusion formed on the outer surface and engaged with the groove; A coupling block made of a conductive material having a ventilation portion penetrating therein and being detachably fixed to the power distribution line and slidably installed in the groove of the guide member via a projection:

A valve seat configured to face the distal end of the connecting portion; A valve body installed to be seated on the valve seat; A check valve installed in the ventilation section, comprising a spring which is elastically pressurized so that the valve body is pushed toward the distal end of the connecting portion and prevents the valve body from seating on the valve seat;

Installed on the fixed block and the temperature sensor for measuring the surface temperature of the fixed block and outputting the measured value:

A control unit for receiving the measured value from the temperature sensor and controlling the operation of the control valve:

An inflator comprising a gas chamber filled with a high pressure carbon dioxide gas and connected to a connection part of a fixed block via a gas supply pipe, and a control valve installed in the gas supply pipe and operated by a controller to open and close the inside of the gas supply pipe:

One end is fixed to the coupling block, the other end is characterized in that it comprises a buffer damper for buffering the coupling block protruding backward by the carbon dioxide gas.

According to the present invention having the above configuration, since the underground transmission line fixed to the fixed block moves together along the longitudinal direction, the underground transmission line is separated from the fixed portion of the fixed block by an earthquake or the underground transmission line is caused by an earthquake. It can be prevented from being damaged and broken by the tension caused.

In addition, the coupling projection of the movable member is installed to be movable in the guide groove of the fixed member. When an earthquake occurs in this state, the underground wires fixed to the fixed block are moved together along the longitudinal direction. It is possible to prevent the ground wire from being separated from the fixed portion of the fixed block by the earthquake of the underground wire or the underground wire is damaged and broken by the tension due to the earthquake.

In addition, when the temperature of the fixed block rises, the high pressure carbon dioxide gas stored in the gas chamber of the inflator is injected into the connection part to push the connection part of the coupling block inserted into the connection part, thereby automatically releasing the coupling state between the fixed block and the coupling block. The fixed block and the coupling block are electrically blocked, and at the same time, the rapidly expanding carbon dioxide gas rapidly cools the fixed block and the coupling block.

Therefore, the temperature of the underground distribution line connector can be prevented from increasing further, and the temperature of the underground distribution line connector can be lowered to prevent the damage of the covering of the underground wiring and the distribution line.

1 and 2 are an exploded perspective and exploded perspective view of the protective enclosure for underground transmission line inlet according to the present invention.
Figure 3 is a partial side cross-sectional view of the protective enclosure for underground transmission line only in accordance with the present invention.
Figure 4 is a partial cross-sectional view of the protective enclosure for underground transmission line inlet only in accordance with the present invention.
5 and 6 is a view showing the operation relationship of the protective box for the transmission line only for underground transmission line according to the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail.

1 and 2 are a perspective view and an exploded perspective view of a combined transmission enclosure for the underground transmission line inlet only, according to the invention, Figure 3 is a partial side cross-sectional view of the underground transmission line for intake protection box according to the invention, Figure 4 is Partial cross-sectional view of a protective enclosure for underground transmission line entry only.

1 to 4, the protection box for the underground transmission line entrance according to the present invention, the case 10 having a door portion 11 and: the base is installed and protected inside the case (10) ( 20); A fixed block 30 fixedly installed at the base 20 and having an underground transmission line 1 connected to one side thereof; A coupling block 40 slidably installed on the base 20 and coupled to the fixed block 30; A check valve 50 installed on the coupling block 40; A temperature sensor 60 provided in the fixed block 30; A controller 70 connected to the temperature sensor 60; An inflator 80 connected to the coupling block 40 and operated according to a signal of the controller 70; It is composed of a buffer damper 90 connected to the base 20 and the coupling block 40, respectively.

The case part 10 is a rectangular parallelepiped with an open top, and wiring holes are formed on both sides of the longitudinal direction on the same horizontal line, and underground transmission lines 1 are inserted and wired in the wiring holes. Although not specifically illustrated in the case of the wiring hole to prevent the penetration of the infiltration water through the sealing treatment. And, the door portion 11 which is installed to be opened and closed through the hinge is installed on the open upper portion. Here, the case part 10 wraps and protects the base 20 installed therein, and in particular, serves to prevent electric short circuit accidents caused by mixing by blocking the foreign matter from flowing into the wired inside.

The base 20 has a guide groove (21a) formed along the longitudinal direction in the center of the upper surface, the fixing member 21 is fixed to the inside of the case portion 10 via a fastening member; Coupling projection 22a formed on the bottom and the groove 22b-1 in the longitudinal direction is provided on one side and the guide member 22b disposed to face each other on the upper surface, the fixing member 21 is a guide groove ( 21a) is composed of a moving member 22 is installed to be movable through the coupling projection (22a).

In particular, since the base 20 is connected to the underground power transmission line 1 through which a high voltage current flows, it is formed of synthetic resin, which is a non-conductor for insulation, or formed by thickly covering the synthetic resin, which is a non-conductor, on the circumferential surface of a high-strength metal material. desirable.

According to this embodiment, the coupling protrusion 22a of the movable member 22 is installed in the guide groove 21a of the fixing member 21 to be movable. When an earthquake occurs in this state, the fixing block Since the underground transmission line 1 fixed to 30 moves the movable member 22 along the longitudinal direction, the underground transmission line 1 is separated from the fixed portion 31 of the fixed block 30 by an earthquake or Underground transmission line (1) can be prevented from being damaged and broken by the tension caused by the earthquake.

In addition, a pair of guide members 22b are arranged side by side on the upper surface of the movable member 22, and grooves 22b-1 formed along the longitudinal direction are provided inside the guide member 22b. Here, the groove 22b-1 serves to guide the coupling block 40 when the protrusion 42 of the coupling block 40 to be described later is inserted.

The fixed block 30, the overall shape forms a T-shape, the material is a steel or copper which is a conductor, the fixing portion 31 for electrically connecting the underground transmission line (1); It is connected to the outer surface of the fixing portion 31 is composed of a connecting portion 32 disposed in front of the guide member (22b). In addition, underground transmission lines 1 are respectively inserted into both ends of the fixing portion 31, and the inserted underground transmission lines 1 are fixed through fixing means (bolts).

In addition, in the present embodiment, it is preferable to form a precise hole such as a cylinder in the center of the connecting portion 32 so that the connecting portion 41 of the coupling block 40 can be accurately inserted.

The coupling block 40 includes a connection portion 41 detachably coupled to the connection portion 32; A protrusion 42 formed on the outer surface and engaged with the groove 22b-1; Consists of a vent 43 penetrating the inside, the material was formed of a conductor such as copper.

In the present embodiment, the coupling block 40 is slidably installed in the groove 22b-1 of the guide member 22b via the protrusion 42, and the distribution line 2 is inserted backward to fix the fixing means (bolts). It is fixed via). Here, when the coupling block 40 is pushed along the groove 22b-1, the connection portion 41 of the coupling block 40 is inserted into the connection portion 32 to be electrically connected.

In addition, a rubber packing 31a is installed on the circumferential surface of the connection part 41. Here, the packing 31a allows the connecting portion 41 to be hermetically coupled to the inside of the hole of the connecting portion 32.

In addition, the vent part 43 penetrates the coupling block 40 forward and backward to insert or pull the connection part 41 into the connection part 32 hole of the fixed block 30 through the vent part 43. The internal air of 32 is discharged or air is introduced into the connection part 32 so that the connection part 41 can be easily inserted into or removed from the connection part 32.

The check valve 50, the valve seat 51 formed to face the front end of the connecting portion 41; A valve body 52 provided to be seated on the valve seat 51; The valve body 52 is constituted by a spring 53 which elastically presses so that the valve body 52 is pushed toward the front end of the connecting portion 41 and prevents the valve body 52 from being seated on the valve seat 51. Here, the check valve 50 is installed in the vent portion 43 penetrating the center of the coupling block 40, preferably it is installed in the portion penetrating the center of the connection portion 41.

The temperature sensor 60 is installed on the fixed block 30 to measure in real time the temperature of the fixed block 30 which is changed by heat generated when supplying high voltage electricity to the power distribution line 2, and the measured value. Is output to the control unit 70.

In the present embodiment, since there is a possibility of malfunction due to high-pressure electricity, it is preferable to apply a non-contact temperature sensor that can measure the surface temperature of the fixed block 30 by being spaced apart through a bracket (not shown). .

The control unit 70 receives the temperature value from the temperature sensor 60 and controls the operation of the control valve 83 of the inflator 80 when the temperature of the fixed block 30 rises above a preset safety temperature. .

The inflator 80, the gas chamber 81 is filled with a high-pressure carbon dioxide gas therein and connected to the connecting portion 32 of the fixed block 30 via the gas supply pipe 82; It is installed in the gas supply pipe 82 and is operated by the control unit 70 is composed of a control valve 83 for opening and closing the interior of the gas supply pipe (82).

Referring to FIG. 5, when the control valve 83 is opened in response to a signal from the control unit 70, the high pressure carbon dioxide gas stored in the gas chamber 81 is discharged into the connection part 32 to form the coupling block 40. When pushing the connection portion 41 of the strong pressure, the connection portion 41 is separated from the connection portion 32 to release the mechanical and electrical coupling of the fixed block 30 and the coupling block 40 coupled with the fixed block 30 The electricity supplied to the power distribution line 2 is cut through the block 40.

The buffer damper 90 is disposed to be parallel to the sliding direction of the coupling block 40 in a concave portion on the upper surface of the base 20 to be positioned below the coupling block 40, one end of which is in the base 20. The other end is connected to the lower end of the coupling block 40, respectively, when the coupling block 40 is pushed back by the inflator 80, the coupling block 40 is retracted at an excessively high speed guide member 22b It is strongly prevented from being damaged by collision with the end of the strong, and prevents the coupling block 40 is advanced by the repulsive force generated during the collision to contact the fixed block 30 again.

Accordingly, the user connects the underground transmission line 1 and the distribution line 2 to the fixed block 30 and the coupling block 40, respectively, and then pushes the coupling block 40 to connect the connection portion 41 to the hole of the connection portion 32. When inserted into the ground line 1 and the distribution line 2 is electrically connected to the electricity supplied through the ground line 1 is branched through the distribution line (2).

When the user inserts the connecting portion 41 into the hole of the connecting portion 32, air inside the connecting portion 32 is slowly discharged to the outside through the vent 43, so that the valve body 52 is connected to the spring 53. As a result of being pushed by the valve seat 51, the vent part 43 is opened so that the connection part 41 can be easily inserted into the hole of the connection part 32.

On the other hand, when the operator pulls the coupling block 40 to pull out the connecting portion 41 from the hole of the connecting portion 32, the check valve 50 is kept open so that the air resistance does not work and can be easily taken out.

Then, when the temperature of the fixed block 30 and the coupling block 40 is increased due to the continuous wiring connection, the control unit 70 operates the inflator 80 in accordance with the signal of the temperature sensor 60 of the connection portion 32 By supplying a high pressure carbon dioxide gas therein to push the connection portion 41, the fixed block 30 is disconnected from the coupling block 40 to cut off electricity.

At this time, the valve body 52 of the check valve 50 is strongly pushed by the high-pressure carbon dioxide gas supplied to the connecting portion 32, so that the spring 53 is retracted and retracted closely to the valve seat 51. Therefore, the carbon dioxide gas is prevented from being discharged to the outside through the vent 43.

In addition, the carbon dioxide gas in addition to the function to block the electricity by releasing the coupling of the fixed block 30 and the coupling block 40, the adiabatic expansion to absorb the heat around the fixed block 30 and the coupling block 40 It has the function of cooling instantaneously and also has the function of extinguishing fire in case of possible fire.

As such, by blocking the supply of electricity to prevent the fixed block 30 and the coupling block 40 is no longer heated by the electricity flowing through the fixed block 30 and the coupling block 40, underground transmission line (1) ) Or the coating of the power distribution line (2) is melted, there is an advantage that can prevent a short, electric shock or fire caused by this, and also by injecting a high-pressure carbon dioxide gas, extinguish the fire in the event of a fire There is an advantage to this.

On the other hand, referring to Figure 6 another embodiment of the present invention, the engaging projection (22a) of the movable member 22 is installed in the guide groove (21a) of the fixing member (21), which is installed as described above When an earthquake occurs in the state, since the underground transmission line 1 and the movable member 22 fixed to the fixed block 30 are moved together along the longitudinal direction, the fixed block 30 by the earthquake of the underground transmission line 1 It can be prevented from being separated from the fixing portion 31 of the underground transmission line (1) is damaged or broken by the tension due to the earthquake.

Although the present invention has been described in detail only with respect to the specific embodiments described, it will be apparent to those skilled in the art that various modifications and changes can be made within the technical scope of the present invention, and such modifications and modifications belong to the appended claims. It is natural.

10: case 20: base 21: fixing member
22: guide member 30: fixed block 31: fixed part
32: connection part 40: coupling block 41: connection part
42: projection 43: vent 50: check valve
51: valve seat 52: valve body 53: spring
60: temperature sensor 70: control unit 80: inflator
81: gas chamber 82: gas supply pipe 83: control valve
90: damper damper

Claims (1)

Case part 10 having a door part 11 and:
A fixing member 21 having a guide groove 21a formed along the longitudinal direction at the center of the upper surface, and fixed to the inside of the case part 10 by a fastening member;
A guide groove 22b of the fixing member 21 is provided with a coupling protrusion 22a formed at a bottom surface and a guide member 22b provided at one side thereof with a longitudinal groove 22b-1 and disposed to face each other on an upper surface thereof. And the base 20 of the insulating material consisting of a movable member 22 which is installed to be movable through the coupling protrusion 22a to 21a):
A fixed part 31 for electrically connecting the underground power transmission line 1; It is connected to the outer surface of the fixing portion 31 and consists of a connecting portion 32 disposed in front of the guide member 22b, fixed on the base 20, the overall shape of the T-shaped, the fixing of the conductor material With block 30:
A connection portion 41 detachably coupled to the connection portion 32; A protrusion 42 formed on the outer surface and engaged with the groove 22b-1; A conductive material having a ventilation portion 43 penetrating therein so as to be detachably fixed to the power distribution line 2 and to be slidably installed in the groove 22b-1 of the guide member 22b via the projection 42. Query combining block 40 and:
A valve seat 51 formed to face the front end of the connecting portion 41; A valve body 52 provided to be seated on the valve seat 51; It is composed of a spring 53 which elastically pressurizes the valve body 52 to be pushed toward the distal end of the connecting portion 41 and prevents the valve body 52 from seating on the valve seat 51. Installed check valve 50 and:
Installed on the fixed block 30 and the temperature sensor 60 for measuring the surface temperature of the fixed block 30 and outputs the measured value:
The control unit 70 receives the measured value from the temperature sensor 60 and controls the operation of the control valve 83.
The inside of the high pressure carbon dioxide gas is filled and connected to the connecting portion 32 of the fixed block 30 via the gas supply pipe 82 and the gas chamber 81 and the gas supply pipe 82 is installed in the control unit 70 An inflator 80 configured to be controlled by a control valve 83 for opening and closing the inside of the gas supply pipe 82 by:
One end is fixed to the coupling block 40, the other end is fixed to the base 20 underground transmission line, characterized in that it comprises a buffer damper 90 for buffering the coupling block 40 protruding backward by the carbon dioxide gas Ingress protection enclosure.

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