KR101880296B1 - Apparatus for breaking connection of 345kV underground transmission line - Google Patents

Abstract

The present invention relates to an apparatus for blocking connection of a 345 kV underground transmission line, which comprises: an insulation partition plate for dividing a lead-in space, in which a conductor part of a lead-in line is located on the inside of an underground pipe, and a drawn space in which a conductor part of a drawn line is located; a casing installed on the outside of the underground pipe; a connection rod formed of a conductor, passing through a connection rod through-hole formed on the insulation partition plate, and installed to be lifted between the lead0in space and the drawn space; a lifting means for lifting the connection rod; a power device extinguishing means installed on both sides of an upper end of a cabinet; a first extinguishing means and a second extinguishing means for preventing an arc generation in the lead-in space, the drawn space, and the casing; a shielding means for shielding communication of the lead-in space and the drawn space by the connection rod through-hole formed on the insulation partition plate; and a control means for controlling the lifting means, the power device extinguishing means, the first extinguishing means, the second extinguishing means, and the shielding means. According to the present invention, it is possible to extinguish fire quickly by injecting a fire extinguishing gas when fire occurs in the cabinet and a power device. In addition, in a process of blocking the lead-in line and the drawn line, the lead-in line and the drawn line are located in spaces shielded from each other, and arc generation can be prevented by injecting a fire extinguishing gas into each space. Accordingly, it is possible to prevent diffusion and reoccurrence of fire.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an underground transmission line for a 345-

The present invention relates to a power disconnecting device for a 345 kV underground transmission line, more specifically, it is capable of quickly extinguishing a fire extinguishing gas by itself in the event of a fire in a cabinet and an electric power device, It is possible to prevent an arc from occurring by injecting SOG gas into each space. In order to prevent fire from spreading and recurrence, To a transmission line disconnecting device.

Generally, a transmission line is a steel tower installed at a certain interval on the ground or a working transmission line connecting a plurality of working transmission lines through an insulator to a pole, and an underground distribution line in which a plurality of underground transmission lines are inserted into an underground buried channel embedded in the ground Respectively.

Although there is an advantage in that the initial transmission cost is low and the construction is simple, there is a problem in the appearance of the city, interference between the transmission line and the roadside line, and contact failure, short circuit and power failure due to nesting of birds such as shrike And the like.

The underground transmission line has the advantage of solving the disadvantages of the overhead transmission line, but it is buried in the ground and it is difficult to cope instantly when a fire occurs.

On the other hand, people who are dissatisfied with the society in recent years are often exposed to national facilities or public facilities. Especially when there is a fire in a power device such as a circuit breaker installed on the ground or a ground transformer or a switchboard, There is a problem that evolution becomes more difficult.

Accordingly, Korean Priority Patent No. 10-1293720 (registered on March 31, 2013) entitled " Prior Art for Connecting Underground Cable Disconnecting Device "(hereinafter referred to as " Prior Art " An electric distribution board installed in the switchgear case; An underground piping of insulating material communicating with the bottom surface of the switchgear case; An electric distribution line power supply line disposed inside the underground pipe; An external power supply line installed in the underground pipe; And a first connecting portion and a second connecting portion provided at both ends of the cut portion and having a pair of 'W' shaped cut portions. The first connecting portion and the second connecting portion are installed in the underground piping through the supporting rods and are connected to the live wire of the power- A conductor of a conductive material interconnecting the neutral conductor of the power supply line and the neutral conductor of the external power supply line; A solenoid installed inside the case, a rod which is disposed in the inner side of the underground pipe and has an engagement groove extended inward, and the other end is connected to the solenoid and reciprocates by the solenoid, A pair of cutoff mechanisms which are fixedly fitted in the coupling groove and formed at the other end in a wedge shape, and which are disposed between the cutoff portion and the cutoff portion and cut the cutoff portion; A fire detection sensor for detecting a fire in the switchboard; A control unit for operating and controlling the solenoid of the shut-off mechanism; And an alarm device which is operated and controlled by the control unit to output a fire state to the outside, thereby rapidly cutting the cut portion of the underground wire in the direction of a fire to prevent a short circuit and fire from occurring.

However, in the above-described prior art, not only the conductor portion of the power distribution board power supply line and the conductor portion of the external power supply line are located close to each other in the same space, but also the rod and the cutter are located between the conductor portion of the power distribution board power supply line and the conductor portion of the external power supply line Arc is generated between the conductor portion of the power distribution board power supply line and the conductor portion of the external power supply line, the rod and the cutter, thereby causing a problem of fire spreading and recurrence.

Therefore, it is required to develop a technique for preventing arcing, fire spreading and recurrence due to the occurrence of arcs in the space where the conductors of the distribution line power supply line and the conductor portions of the external power supply line are blocked from each other.

Korean Registered Patent No. 10-0875747 (Registered on Dec. 17, 2008) "Incoming-out connection structure of submerged underground cable"

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide a cabinet and an electric power unit that can fire a fire extinguishing gas by themselves when a fire occurs in a cabinet and an electric power appliance, And to provide a connection breaking device of a 345 kV underground transmission line which can prevent occurrence of an arc by injecting SOG gas into each space, thereby preventing spread of fire and recurrence of fire.

According to an aspect of the present invention, there is provided a power supply apparatus comprising: a power device installed inside a cabinet installed on the ground; An underground pipe 30 embedded in the lower portion of the cabinet 10; A lead-in wire 40 which is drawn into the underground pipe 30 from the power device 20 and is exposed at the lower end of the conductor portion 41; And a lead wire (50) installed at a lower portion of the lead wire (40) inside the underground pipe (30) and having a conductor portion (51) exposed at an upper end thereof, the connection and disconnection device for a 345 kV underground transmission line, The lead wires 50 are formed in a staggered shape so as to give an expansion and contraction margin and the leadframe 50 has an inlet space S1 in which the conductor portions 41 of the lead wires 40 are located, And an extraction space S2 in which the conductor portion 51 of the lead line 50 is located; A casing 200 installed outside the underground pipe 30; A connecting rod 300 composed of a conductor and installed to be able to move up and down between the lead-in space S1 and the lead-out space S2 through the connecting tube hole 110 formed in the insulating partition plate 100; An ascending / descending means 400 for ascending / descending the linkage 300; Power device evolving means (500) installed on both sides of the upper end of the cabinet (10); A first and a second superimposing means 600 and a second superimposing means 700 for preventing arc generation in the lead-in space S1, the lead-out space S2 and the casing 200; Shielding means 800 for shielding the lead-in space S1 and the lead-out space S2 from being communicated with each other by a connecting pin hole 110 formed in the insulating partition plate 100; And control means 900 for controlling the elevation means 400, the electric power equipment evolution means 500, the first and second superordinate means 600, 700 and the shielding means 800 The connecting rod 300 is formed at the upper end and is connected to the lead line connecting groove 310 through which the conductor portion 41 of the lead line 40 is inserted and the conductor portion of the lead line 50 And the lead line connecting groove 310 is formed so that the conductor portion 41 of the lead line 40 can be inserted and connected or disconnected to be disconnected, The line connecting groove 320 is configured to insert and fix the conductor portion 51 of the lead wire 50. The elevating means 400 includes a solenoid body 411 fixed to both sides of the inner wall surface of the underground pipe 30, A solenoid 410 having a working rod 412 protruding and retracted from the solenoid body 411; And a connecting mechanism 420 for connecting the upper end of the operating rod 412 and the lower end of the connecting rod 300. The solenoid 410 is operated by the resilient restoring force of the self- A solenoid of the type in which the rod 412 advances and retracts when the power is applied is used as the connection mechanism 420. The connection mechanism 420 is made of an insulating synthetic resin, And a connecting piece 430 having a connecting coupling portion 431 and a working rod coupling portion 432 coupled to the upper end of the working rod 412. The power device evolving means 500 is installed in the cabinet A fire extinguishing gas opening / closing valve 520 installed at a lower end of the fire extinguishing gas storage container 510, and a fire extinguishing gas opening / closing valve 520 installed at the lower end of the fire extinguishing gas storage container 510, The fire extinguishing gas is stored through the fire extinguishing gas opening / closing valve 520 And a first extinguishing means 600 installed on the upper side of the casing 200 for discharging the SOG gas G2 in a pressurized state, Closing valve 620 connected to the SOF gas reservoir 610 and connected to the SOF gas reservoir 610 through the SOF gas opening and closing valve 620, A SOH gas injection nozzle 630 passing through the pipe 30 and injecting SOH into the inlet space S1, a SOHO gas opening / closing valve 640 connected to the SOH gas storage tank 610, And a small-diameter gas injection nozzle 650 connected to the small-size gas reservoir 610 through a valve 640 to inject small-sized gas into the casing 200. The second small- And is installed in the lower side of the casing 200 and in a state where the soot gas (Gco3) A SOH gas opening and closing valve 720 connected to the upper end of the SOH gas storage container 710 and connected to the SOH gas storage container 710 through the SOH gas opening and closing valve 720, And a small-diameter gas injection nozzle 730 which penetrates through the underground pipe 30 and injects a small amount of gas into the drawing space S2. The shielding unit 800 is installed in the casing 200 A solenoid 810 having a solenoid body 811 and a working rod 812 protruding and retracted from the solenoid body 811; And a shield plate 820 of an electrically insulating material which is coupled to the tip end of the operating rod 812 and opens and closes the connecting pipe through hole 110 of the insulating partition plate 100 through the underground pipe 30, And the solenoid 810 is retracted by the resilient restoring force of the elastic member built in the solenoid 810 when the power is shut off and the solenoid 812 is advanced when the power is applied, 900 is provided with a fire detection sensor 910 installed in the cabinet 10 and a control unit 910 for controlling the forward operation of the solenoid 410 and the forward command for the solenoid 810 if a fire detection signal is not inputted from the fire detection sensor 910, And outputs a closing command to the fire extinguishing gas opening / closing valve 520 and the soot gas opening / closing valves 620, 640 and 720. When a fire detecting signal is inputted from the fire detecting sensor 910, For the solenoid 410, A control unit 920 for outputting a command for withdrawal and a forward command for the solenoid 810 and for outputting an open command to the extinguishing gas opening and closing valve 520 and the SOH gas opening and closing valves 620, 640 and 720, A solenoid driving unit 930 for sending a driving signal to the solenoids 410 and 810 according to a control command of the control unit 920 and a control unit 920 for controlling the extinguishing gas opening / And a valve driving unit 940 for transmitting a driving signal to the gas opening / closing valves 620, 640 and 720. The connecting / disconnecting device of the 345 kV underground transmission line is provided.

According to the 345 kV underground transmission line interrupter of the present invention, the insulated partition plate is divided into an inlet space in which a conductor portion of a lead-in line is located and a lead-out space in which a conductor portion of the lead-out line is located; A casing installed outside the underground pipe; A connection block formed of a conductor and installed so as to be able to move up and down between a lead-in space and a lead-out space through a connection tube through-hole formed in the insulating partition plate; A lifting means for lifting the connecting rod; Power device evolving means installed on both sides of the upper end of the cabinet; A first and a second subordinate means for preventing the lead-in space and the lead-out space and arc generation in the casing; Shielding means for shielding the lead-in space and the lead-out space from being communicated by the connecting tube hole formed in the insulating partition plate; And control means for controlling the elevating means, the electric power device evolving means, the first and second subordinate means, and the shielding means. When a fire occurs in the cabinet and the power device, In addition, in the process of cutting off the lead-in wire and the lead-out wire, the lead-in wire and the lead-out wire are positioned in the shielded space, and the arc can be prevented from being generated by spraying the soot gas into each space. Diffusion and recurrence can be prevented.

1 to 4 show a preferred embodiment of a connection breaking device for a 345 kV underground transmission line according to the present invention,
1 is an exploded perspective view of an underground transmission line to which the present invention is applied,
2 is a longitudinal front view showing a state in which a lead line and a lead line are connected,
3 is a longitudinal front view showing a state in which a lead line and a lead line are cut off,
4 is a functional block diagram of the control means.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a connection breaking apparatus for a 345 kV underground transmission line according to the present invention will be described in detail with reference to the accompanying drawings.

1 to 4 show a preferred embodiment of a connection breaking device for a 345 kV underground transmission line according to the present invention.

As shown in FIGS. 1 to 4, the 345 kV underground transmission line to which the present invention is applied includes an electric power unit 20 installed inside a cabinet 10 installed on the ground; An underground pipe 30 embedded in the lower portion of the cabinet 10; A lead-in line (40) leading into the inside of the underground pipe (30) from the power device (20); And a lead wire 50 installed in the lower portion of the lead wire 40 inside the underground pipe 30.

The cabinet 10 is installed on the ground, and a door is openable and closable on the front surface. The power device 20 can be a ground transformer, a circuit breaker, or an electric switchboard.

The underground pipe 30 may be made of a synthetic resin having electrical insulation.

The submerged pipe 30 has a rectangular cross-section in the drawing, but may be formed in a circular cross-section.

The lead wire 40 and the lead wire 50 are coated with an insulating coating wire. The lead wire 40 is installed in a state where the insulating coating is peeled off at the lower end and the conductor portion 41 is exposed. The lead wires 50 are provided in a state in which the insulating coating is peeled from the upper end and the conductor portion 51 is exposed.

Since the conductor portion 51 at the upper end is coupled to the lower end of the connecting rod 300 to be described later, when the connecting rod 300 is moved up and down by the raising means 400 described later, It is preferable to bend a part of the lead wire 50 in a staggered shape so as to give a stretch margin to the lead wire 50.

An inlet space S1 in which the conductor portion 41 of the lead wire 40 is located and a lead-out space S2 in which the conductor portion 51 of the lead wire 50 are located are formed in the underground pipe 30, And an insulating partition plate 100 is provided.

The insulating partition plate 100 divides the lead-in space S1 and the lead-out space S2 in a completely hermetic state, and is formed of a material having electrical insulation and a flame-retardant property.

The insulating partition plate 100 may be fixedly supported on the inner circumferential surface of the underground pipe 30 by brackets, bolts / nuts, or the like.

The lead wire 40 is suspended in the lead-in space S1 and the lower lead conductor 41 is located in the lead-in space S1. The lead wire 50 is installed in the lead-out space S2 And the upper conductor section 51 is located below the insulation partition plate 100.

The insulation partition plate 100 is connected to the insulated space S1 where the conductor portion 41 of the lead wire 40 is located and the conductor portion of the lead wire 50 when the lead wire 40 and the lead wire 50 are cut off It is possible to prevent the arcing and fire generated in the lead-in space S1 and the lead-out space S2 from being diffused to other spaces by blocking the lead-out space S2 in which the lead-

The present invention further includes a casing (200) installed outside the underground pipe (30). The casing 200 may be made of a metal material or a synthetic resin material having electrical insulation.

The casing 200 is formed in the form of a box having an opening facing the submerged pipe 30 and is constructed in the form of a cabinet that can be opened and closed by a door so that various components installed therein can be installed and maintained. .

The casing (200) can be fixed to both sides of the underground pipe (30) by a separate bracket, bolt and nut.

The conductor portion 41 of the lead line 40 and the conductor portion 51 of the lead line 50 are connected to each other by a connecting rod 300 through which the insulating partition plate 100 can be elevated.

The connection block 300 includes a lead line connection groove 310 formed at the upper end of the insulation partition plate 100 so as to pass through the insulation partition plate 100 and into which the conductor portion 41 of the lead line 40 is inserted, And a lead wire connecting groove 320 formed at the lower end of the lead wire 50 and into which the conductor portion 51 of the lead wire 50 is inserted.

The lead line connecting groove 310 is formed so that the conductor portion 41 of the lead line 40 is inserted and connected or disconnected and the lead line connecting groove 320 is formed in the conductor portion 51 are inserted and fixed.

A connection pin hole 110 is formed in the insulation partition plate 100 so that the connection pin 300 can be lifted and lowered.

The present invention further includes a lifting means (400) for lifting the linkage (300).

The elevating means 400 includes a solenoid body 411 fixed to both sides of the inner wall of the underground pipe 30 and a solenoid 410 having a working rod 412 protruding and retracted from the solenoid body 411; And a connecting mechanism 420 connecting the upper end of the operating rod 412 and the lower end of the connecting rod 300.

The solenoid body 411 is fixed to the underground pipe 30 by a bolt B1 passing through a flange portion 413 formed on the side surface and a wall surface of the underground pipe 30 and a nut N1 fastened thereto.

The solenoid 410 is of a solenoid type in which the operating rod 412 advances (ascends) due to the elastic restoring force of its own built-in elastic member when the power is turned off and retracts (descends) when power is applied.

The connection mechanism 420 includes a connection coupling portion 431 connected to the lower end of the connection rod 300 and a working rod coupling portion 432 coupled to the upper end of the operation rod 412. [ (Not shown).

The lower end of the connection unit 300 is inserted in the connection upper coupling unit 431 in the process of forming the connection unit 430 so that the connection upper coupling unit 431 and the connection unit 300 are integrally coupled.

The working rod connecting portion 432 and the working rod 412 are inserted through the working rod 412 into the working rod through hole 433 formed in the working rod connecting portion 432 and the male thread portion 414 by tightening a pair of nuts N2 so as to be brought into close contact with the upper surface and the lower surface of the operating rod engaging portion 432. [

The present invention further includes power device evolving means (500) installed on both sides of the upper end of the cabinet (10).

The power device evolving means 500 includes a fire extinguishing gas storage box 510 installed on both upper sides of the cabinet 10 to store the extinguishing gas G1 in a pressurized state, And a fire extinguishing gas injection nozzle 530 connected to the fire extinguishing gas storage container 510 through the fire extinguishing gas opening and closing valve 520. The fire extinguishing gas opening /

The extinguishing gas stored in the extinguishing gas storage container 510 may be carbon dioxide.

The fire extinguishing gas opening / closing valve 520 is a solenoid valve that is opened and closed by an electrical signal.

The present invention further includes a first and a second superhigher means 600 and a second superhigher means 700 for preventing arc generation in the lead-in space S1 and the lead-out space S2 and the casing 200, respectively.

The first sub-hopper means 600 includes a soho gas reservoir 610 disposed inside the casing 200 and containing a soot gas G2 in a pressurized state, And is connected to the SOF gas storage container 610 through the SOF gas opening and closing valve 620 and the SOF gas opening and closing valve 620. The SOF gas is introduced into the inlet space S1 through the underground pipe 30, Off valve 640 connected to the SOH gas reservoir 610 and connected to the SOH gas reservoir 610 through the SOH gas opening and closing valve 640, And a small-diameter gas injection nozzle 650 for injecting small-sized gas in the plurality of nozzles 200.

The second supercharging unit 700 includes a soho gas reservoir 710 installed inside the casing 200 and stored in a state in which SO gas G3 is pressurized, And is connected to the SOH gas reservoir 710 through the SOH gas opening and closing valve 720 connected to the SOH gas opening and closing valve 720. The SOH gas is introduced into the withdrawing space S2 through the underground pipe 30, And a soot gas injection nozzle 730 that injects the gas.

SF ₆ gas may be used as the SO ₄ gas stored in the SO 2 gas reservoirs 610 and 710.

The submerged pipe 30 is formed with a nozzle through hole 31 through which the SOG injection nozzle 630 passes and a nozzle through hole 32 through which the SOG injection nozzle 730 passes.

The present invention further includes a shielding means 800 for shielding the lead-in space S1 and the lead-out space S2 from being communicated by the connecting tube hole 110 formed in the insulating partition plate 100. [

The shielding means 800 includes a solenoid body 811 installed in the casing 200 and a solenoid 810 having a working rod 812 protruding and retracted from the solenoid body 811; And a shielding plate 820 coupled to a front end of the operating rod 812 and opening and closing the connecting pipe through hole 110 of the insulating partition plate 100 through the underground pipe 30.

The solenoid 810 retracts due to the resilient restoring force of the elastic member built in itself when the power is turned off, and the solenoid of the type in which the operating rod 812 advances when power is applied is used.

The shielding plate 820 is formed of a synthetic resin of an electrically insulating material.

The underground pipe 30 is formed with a shielding plate pipe through hole 33 through which the shielding plate 820 passes.

The control means 900 for controlling the elevation means 400, the electric power unit evolution means 500, the first and second superordinate means 600 and 700 and the shielding means 800 is further provided .

The control means 900 controls a fire sensor 910 installed in the cabinet 10 and a forward command for the solenoid 410 and a solenoid 810 and outputs a closing command for the fire extinguishing gas opening / closing valve 520 and the soot gas opening / closing valves 620, 640, 720. The fire detection sensor 910 outputs a fire detection signal Off valve 520 and the SOH gas opening / closing valves 620, 640, and 720 are opened and a forward command for the solenoid 810 is output, A solenoid driving unit 930 for sending driving signals to the solenoids 410 and 810 according to a control command of the control unit 920 and a control unit 920 for controlling the solenoids The fire extinguishing gas opening / closing valve 520 and And a valve driving unit 940 for sending a driving signal to the SOH gas opening / closing valves 620, 640 and 720.

The power required for the fire detection sensor 910, the solenoids 410 and 810, the fire extinguishing gas opening and closing valve 520 and the SOH gas opening and closing valves 620, 640 and 720 is connected to a separate commercial power source or a solar power generating device And may be supplied from a battery (not shown) that is charged by the charging device, and detailed description thereof will be omitted.

Hereinafter, the operation of the connection breaking device of the 345 kV underground transmission line according to the present embodiment will be described.

The fire signal is not transmitted from the fire detection sensor 910 to the control unit 920. In this case, the control unit 920 instructs the solenoid 410 to move forward to the solenoid 410, The solenoid driving unit 930 outputs a closing command for the fire extinguishing gas opening / closing valve 520 and the soot gas opening / closing valves 620, 640 and 720 and outputs a closing command to the solenoid driving unit 930 in response to the control command of the control unit 920. [ The valve driving unit 940 sends a forward driving signal to the solenoid 410 and a backward driving signal to the solenoid 810 so that the valve driving unit 940 applies the backward driving signal to the fire extinguishing gas opening / closing valve 520 and the soot gas opening / closing valves 620, 640 and 720 The closed drive signal is transmitted.

The solenoid 810 of the shielding unit 800 is turned off in accordance with the retraction drive signal of the solenoid drive unit 930 so that the operation rod 812 is retracted by the elastic restoring force of the self- The shield plate 820 coupled to the connecting pipe 812 is retracted to open the connecting pipe through-hole 110.

The solenoid 410 of the lifting unit 400 is powered off in response to the forward driving signal from the solenoid driving unit 930. The elastic restoring force of the elastic member incorporated in the solenoid 410 causes the working rod 412 to advance, The connecting rod 300 connected to the working rod 412 by the connecting mechanism 420 and the lower end fixedly connected to the conductor portion 51 of the lead wire 50 is inserted into the connecting pipe hole 110 of the insulating partition plate 100, And the conductor portion 41 of the lead wire 40 is inserted into the lead wire connecting groove 310 formed at the upper end of the connecting block 300.

Thus, the lead wires 40 and the lead wires 50 are maintained in a connected state by the connecting rod 300.

The fire extinguishing gas opening and closing valve 520 and the SOH gas opening and closing valves 620 and 640 and 720 are both closed in accordance with the closing drive signal of the valve driving unit 940, So that the stored digested gas and the SOH gas stored in the SOH gas storage tanks 610 and 710 of the first and second SOHO units 600 and 700 are maintained in a state of not being injected (see FIG. 2).

In the connecting operation of the lead wire 40 and the lead wire 50 as described above, the retracting operation of the shielding plate 820 of the shielding means 800 and the forward movement of the connecting rod 300 by the elevating means 400, The operation has a momentary parallax but the retraction operation of the shielding plate 820 is preceded and the advance (ascending) operation of the linkage 300 is controlled to follow.

When a fire occurs in the power device 20 or the cabinet 10 in this state, the fire detection sensor 910 senses the fire and transmits it to the control unit 920. The control unit 920 controls the solenoid 410 And outputs a closing command for the fire extinguishing gas opening / closing valve 520 and the soot gas opening / closing valves 620, 640 and 720, and outputs the closing command to the control unit 920 The solenoid driver 930 transmits a backward driving signal to the solenoid 410 and a forward driving signal to the solenoid 810 according to the control command.

The solenoid 410 of the elevating means 400 is energized in accordance with the retraction driving signal of the solenoid driving unit 930 so that the operating rod 412 is retracted and the connecting rod 420 is connected to the connecting rod 420, And a lower end connected to the conductor portion 51 of the lead wire 50 is lowered into the lead-out space S2 through the connecting cap hole 110 to be connected to the lead wire 50 formed at the upper end of the lead- The conductor portion 41 of the lead wire 40 is disconnected from the connection groove 310.

Therefore, the lead wire 40 and the lead wire 50 are kept in a cut-off state.

The solenoid 810 of the shielding means 800 is energized in accordance with the forward driving signal of the solenoid driving unit 930 so that the operating rod 812 advances and the shielding plate 812 coupled to the operating rod 812 820 move forward to shield the connection pipe through-hole 110 formed in the insulating partition plate 100. Accordingly, the lead-in space S1 and the lead-out space S2 are kept in a shielded state.

The fire extinguishing gas opening and closing valve 520 and the SOH gas opening and closing valves 620 and 640 and 720 are both opened according to the closing drive signal of the valve driving unit 940, The stored fire extinguishing gas and the SOG gas stored in the SOG gas reservoirs 610 and 710 of the first and second SOG means 600 and 700 are supplied to the extinguishing gas injection nozzle 530 and the SOG injection nozzles 630, (As described above, see Fig. 3).

At this time, the extinguishing gas injected through the extinguishing gas injection nozzle 530 is injected into the cabinet 10 to suppress the fire generated in the cabinet 10 and the power device 20, and the soot gas injection nozzle 630, The arc is injected into the inlet space S1 to prevent arc generation in the process of separating the connecting rod 300 from the conductor section 41 of the inlet line 40 and the arc is injected from the SOH gas injection nozzle 730, The soot gas injected from the soot gas injection nozzle 650 is injected into the outlet space S2 so as to prevent the arcing which may possibly occur in the conductor section 51 of the outgoing line 50 from flowing into the casing 200 So as to prevent an arc that may occur in the operation process of the solenoid 810 and the SOF gas injection valves 620, 640 and 720 in the casing 200.

In addition, the fire in the cabinet 10 and the power device 20 can be rapidly evolved, and the inlet space S1 and the drawing space S2 of the underground pipe 30 can be separated from each other by the insulating partition plate 100 and the shield plate 820 The conductor portion 41 of the lead wire 40 is located in the lead-in space S1 and the conductor portion 51 of the lead wire 50 is located in the lead-out space S2, So that it is possible to reliably prevent it.

Since the lead wires 50 are bent in a zigzag fashion, the lead wires 50 can be expanded and contracted when the connecting rod 300 connected to the upper conductor 51 is moved up and down.

The opening operation of the extinguishing gas opening and closing valve 530 and the SOH gas opening and closing valves 620, 640 and 720 and the opening operation of the shielding means 800, Closing action of the valve 820 and the retracting (descending) operation of the connecting rod 300 by the elevating means 400 have momentary parallaxes, but the extinguishing gas opening / closing valve 530 and the soh gas opening / closing valves 620, 640, 720 Is controlled so that the retraction (descending) operation of the connecting rod 300 and the advancing operation of the shielding plate 820 are sequentially performed in a sequential manner.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Such modified embodiments should not be individually understood from the technical idea or viewpoint of the present invention, but should be included in the claims attached hereto.

10: Cabinet 20: Power equipment
30: Underground pipe 40: Lead wire
41: conductor portion 50: lead wire
51: conductor portion 100: insulating partition plate
110: connecting tube hole 200: casing
300: connecting rod 310: connecting rod connecting groove
320: leading line connecting groove 400: elevating means
410: Solenoid 412: Working rod
420: connection mechanism 500: power device evolution means
510: Extinguishing gas storage container 520: Extinguishing gas opening / closing valve
530: fire-extinguishing gas injection nozzle 600, 700: first and second sub-
610, 710: SOHO gas reservoir 620, 640, 720: SOHO gas opening / closing valve
630, 650, 730: Extinguishing gas injection nozzle
800: shielding means 810: solenoid
812: Working rod 820: Shield plate
900: Control means 910: Fire detection sensor
920: control unit 930: solenoid driving unit
940:

Claims (1)

A power device (20) installed inside the cabinet (10) installed on the ground; An underground pipe 30 embedded in the lower portion of the cabinet 10; A lead-in wire 40 which is drawn into the underground pipe 30 from the power device 20 and is exposed at the lower end of the conductor portion 41; And a lead wire (50) installed at the lower part of the lead wire (40) inside the underground pipe (30) and having a conductor part (51) exposed at an upper end thereof, the connection and breaking device for a 345 kV underground transmission line,
The lead wires (50) are formed in a zigzag shape in order to give a stretch and expansion margin,
A lead-in space S1 provided inside the underground pipe 30 and in which a conductor portion 41 of the lead-in wire 40 is located, and a lead-out space S1 in which a conductor portion 51 of the lead- (S2, S3); A casing 200 installed outside the underground pipe 30; A connecting rod 300 composed of a conductor and installed to be able to move up and down between the lead-in space S1 and the lead-out space S2 through the connecting tube hole 110 formed in the insulating partition plate 100; An ascending / descending means 400 for ascending / descending the linkage 300; Power device evolving means (500) installed on both sides of the upper end of the cabinet (10); (600) for preventing arc generation in the inlet space (S1) and the casing (200); A second SOHO means (700) for preventing arc generation in the drawing space (S2); Shielding means 800 for shielding the lead-in space S1 and the lead-out space S2 from being communicated with each other by a connecting pin hole 110 formed in the insulating partition plate 100; And control means 900 for controlling the elevation means 400, the electric power equipment evolution means 500, the first and second superordinate means 600, 700 and the shielding means 800 Respectively,
The connection unit 300 includes a lead line connection groove 310 formed at an upper end of the lead wire insertion slot 50 and into which the conductor portion 41 of the lead line 40 is inserted, And a lead line connecting groove 320,
The lead line connecting groove 310 is formed so that the conductor portion 41 of the lead line 40 is inserted and connected or disconnected and the lead line connecting groove 320 is connected to the conductor portion 51 are inserted and fixed,
The elevating means 400 includes a solenoid body 411 fixed to both sides of the inner wall of the underground pipe 30 and a solenoid 410 having a working rod 412 protruding and retracted from the solenoid body 411; And a connection mechanism (420) for connecting the upper end of the operating rod (412) and the lower end of the connecting rod (300)
When the solenoid 410 is powered off, the solenoid of the type in which the operating rod 412 advances (rises) due to the resilient restoring force of the elastic member built therein and retreats (descends) when power is applied is used,
The connection mechanism 420 includes a connection coupling portion 431 connected to the lower end of the connection rod 300 and a working rod coupling portion 432 coupled to the upper end of the operation rod 412. [ And a connecting piece 430,
The power device evolving means 500 includes a fire extinguishing gas storage box 510 installed on both upper sides of the cabinet 10 to store the extinguishing gas G1 in a pressurized state, And an extinguishing gas injection nozzle 530 connected to the extinguishing gas storage container 510 through the extinguishing gas opening and closing valve 520,
The first sub-hopper means 600 includes a soho gas reservoir 610 disposed inside the casing 200 and containing a soot gas G2 in a pressurized state, And is connected to the SOH gas storage container 610 through the SOH gas opening and closing valve 620 and the SOH gas opening and closing valve 620. The SOH gas opening and closing valve 620 passes through the injection nozzle through hole 31 formed in the underground pipe 30, Off valve 640 connected to the SOF gas reservoir 610 and a SOF gas opening / closing valve 640 connected to the SOF gas storage tank 640. The SOF gas injection nozzle 630 is connected to the SOF gas storage / And a small-diameter gas injection nozzle 650 connected to the small-diameter gas inlet 610 to inject small-sized gas into the casing 200,
The second supercharging unit 700 includes a soho gas reservoir 710 installed inside the casing 200 and stored in a state in which SO gas G3 is pressurized, (720) connected to the SOG gas reservoir (710) through the SOG gas opening / closing valve (720) and through the injection nozzle through hole (32) formed in the underground pipe (30) And a SOH gas injection nozzle 730 for injecting SOH into the drawing space S2,
The shielding means 800 includes a solenoid body 811 installed in the casing 200 and a solenoid 810 having a working rod 812 protruding and retracted from the solenoid body 811; And a shielding plate hole penetrating through the shielding plate hole (33) formed in the underground pipe (30) and connected to the tip end of the operating rod (812) Plate 820,
The solenoid 810 retracts due to the resilient restoring force of the elastic member built in itself when the power is turned off and a solenoid of the type in which the operating rod 812 advances when power is applied,
The control means 900 controls a fire sensor 910 installed in the cabinet 10 and a forward command for the solenoid 410 and a solenoid 810 and outputs a closing command for the fire extinguishing gas opening / closing valve 520 and the soot gas opening / closing valves 620, 640, 720. The fire detecting sensor 910 outputs a fire detection signal Off valve 520 and the SOH gas opening / closing valves 620, 640, and 720 are opened and a forward command for the solenoid 810 is output, A solenoid driving unit 930 for sending driving signals to the solenoids 410 and 810 according to a control command of the control unit 920 and a control unit 920 for controlling the solenoids The fire extinguishing gas opening / closing valve 520 and And a valve driving unit (940) for sending driving signals to the SOHO switching valves (620, 640, 720).

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