KR101980052B1 - distribution panel - Google Patents

Abstract

The present invention relates to a distribution board having an earthquake-proof function of a new structure which can prevent damage when an earthquake occurs. According to the present invention, in the distribution board having an earthquake-proof function, a lower slide panel (20) and an upper slide panel (30) are firmly fixed by upper and lower braking means (80, 90) at normal times, a control means (110) controls the upper and lower braking means (80, 90) so as to release the fixing when an earthquake is detected by an earthquake detection sensor (100), accordingly, the lower slide panel (20) and the lower slide panel (20) are freely slidable in every direction of upper and lower guide rails (11, 21), and accordingly, there is an advantage that vibration of a base (10) is absorbed so as to prevent damage to a leg member (B), a case (A) and a distribution unit (C) installed on the upper slide panel (30).

Description

A distribution panel having an earthquake-proof function {distribution panel}

The present invention relates to an ASSEMBLY with an earthquake-proof function of a new structure that can prevent damage during an earthquake.

Generally, as shown in Figs. 1 and 2, an electric distribution board used for distributing electricity supplied through a power line is made of a metal material and separated from the ground by the leg members B provided on the lower side And a power distribution unit (C) provided inside the case (A).

The case A is provided with a door on the front thereof to open the door to expose the power distribution unit C provided therein.

The power distribution unit (C) includes a power distribution panel fixed to the inside of the case (A), a power distribution circuit provided in the power distribution panel, and a plurality of switches or switches provided in the middle of the power distribution circuit, And is configured to be able to distribute electricity using a power line connected to the power distribution circuit.

On the other hand, such a switchboard has a problem that when the earthquake occurs, the leg member B, the case A, or the power distribution unit C may be damaged by vibration.

Also, such a switchboard may cause a fire in the power distribution unit (C) for various reasons, and when a fire occurs, there is a problem that a person may be injured if there is a person nearby.

Therefore, there is a need for a new method to solve such a problem.

10-1155995,

SUMMARY OF THE INVENTION It is an object of the present invention to provide a switchboard having a new structure of an earthquake-proof function capable of preventing damage in the event of an earthquake.

According to an aspect of the present invention, there is provided an electronic device comprising: a case (A) made of a metal material and spaced upward from a ground by a leg member (B) provided on a lower side; (D) for fixing the leg member (B) on the upper surface and preventing vibration from being transmitted to the case (A) when an earthquake occurs, the switchboard comprising the power distribution unit (C) The buffer means D is fixed to the bottom surface and has a base 10 provided with a lower guide rail 11 extending in the front and rear direction on the upper surface thereof and a base 10 slidably coupled to the lower guide rail 11 in forward and backward directions A lower slide panel 20 provided with an upper guide rail 21 extending laterally on the upper surface thereof and a lower slide panel 20 slidably coupled to the upper guide rail 21 so as to be laterally slidable, An upper slide panel 30, A lower measuring mechanism 40 connected to the lower slide panel 20, an upper measuring mechanism 50 connected to the upper slide panel 30 and a lower measuring mechanism 50 connected to the lower slide panel 20, An upper position adjusting means 70 connected to the upper slide panel 30 to adjust the position of the upper slide panel 30 in the lateral direction, A lower braking means 80 connected to the slide panel 20 and fixing the lower slide panel 20 so as to prevent the lower slide panel 20 from sliding in the forward and backward directions and a lower braking means 80 connected to the upper slide panel 30, An earthquake detection sensor 100 provided on the foundation 10 for detecting the occurrence of an earthquake and an upper measuring mechanism 40 and an upper measuring instrument 50. The upper and lower braking means 90, And the signal of the earthquake detection sensor 100 And a control means (110) for controlling the operation of the upper and lower braking means (80,90) and the upper and lower position adjusting means (60,70). The lower slide panel (20) A lower slide block 22 having a lower rack gear 23 formed on a side surface thereof and extending downwardly from the lower guide rail 11 so as to be slidable in the forward and backward directions on the lower guide rail 11, And an upper slide block (31) having an upper rack gear (32) formed on a front surface of the upper slide rail and extending laterally to be slidable laterally to the upper guide rail (21) The upper position adjusting means 70 includes a lower pinion gear 61 and an upper pinion gear 71 coupled to the lower rack gear 23 and the upper rack gear 32, The lower drive motor 62 and the upper drive motor 72 connected to the gear 71 The upper and lower braking means 80 and 90 are fixed such that the lower slide block 22 and the upper slide block 31 are located at the center of the lower guide rail 11 and the upper guide rail 21 The control means 110 releases the brakes of the upper and lower braking means 80 and 90 to detect the occurrence of an earthquake in the earthquake detection sensor 100, The block 31 is slid in the front and rear direction along the lower guide rail 11 and the upper guide rail 21 and the signals of the lower measuring mechanism 40 and the upper measuring mechanism 50 are fed back, The operation of the position adjusting means 60 and the upper position adjusting means 70 is controlled so that the lower slide block 22 and the upper slide block 31 are separated from the lower guide rail 11 and the upper guide rail 21, A power distributing function provided with an earthquake-proof function A half is provided.

According to another aspect of the present invention, there is provided a fire alarm system comprising: a fire detection means (120) provided in the case (A) and detecting a fire in the power distribution unit (C) And a proximity sensor 140 provided on an outer circumferential surface of the case A to sense a person near the periphery of the case A, A plurality of air injection nozzles 160 provided outwardly on the outer surface of the case A and a plurality of air injection nozzles 160 provided on the outer surface of the case A, Further comprising an air supply means (170) operated by control of the control means (110) for supplying high pressure air to the air injection nozzle (160), and the control means (110) receives a signal of the fire detection means When it is detected that a fire has occurred, the fire extinguisher 130 is operated, and at the same time, When a person near the periphery of the case A is present, the warning means 150 is driven to warn a person in the vicinity of the case A, and even after a predetermined time has elapsed, , The air supply means (170) is driven to blow air to the periphery of the case (A) through the air injection nozzle (160) when the person around the air supply nozzle (160) There is provided an electric distribution board having a function.

The switchboard having the earthquake-proof function according to the present invention is normally fixed by the upper and lower braking means 80 and 90 so that the lower slide panel 20 and the upper slide panel 30 do not move, The control means 110 controls the upper and lower braking means 80 and 90 to release the fixing so that the lower slide panel 20 and the lower slide panel 20 can freely move The upper and lower guide rails 11 and 21 are freely slidable in the front and rear directions and in the left and right direction to absorb the vibration of the base 10 so that the leg members B, There is an advantage that the power distribution unit C can be prevented from being damaged.

1 is a front view showing a conventional distribution board,
2 is a side sectional view showing a conventional distribution board,
3 is a side cross-sectional view of an electrical distribution board having an earthquake-proof function according to the present invention,
FIG. 4 is a front sectional view showing a distribution board having an earthquake-proof function according to the present invention,
FIG. 5 is a circuit diagram of a distribution board having an earthquake-proof function according to the present invention,
FIG. 6 and FIG. 7 are reference views showing the operation of the switchboard having the earthquake-proof function according to the present invention,
FIG. 8 is a side sectional view showing a second embodiment of an electric distribution board having an earthquake-resistant function according to the present invention,
FIG. 9 is a plan view showing a second embodiment of the switchboard having the earthquake-proof function according to the present invention,
FIG. 10 is a view showing the construction of a load cell of the second embodiment of the switchboard having the earthquake-proof function according to the present invention,
11 and 12 are reference views showing the operation of the second embodiment of the switchboard having the earthquake-proof function according to the present invention.

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

3 to 7 illustrate an electrical switchboard having an earthquake-resistant function according to the present invention. The switchboard is made of a metal material and has a leg member B disposed on a lower side thereof, (A) and a power distribution unit (C) provided inside the case (A) are provided.

The switchboard having the adiabatic function according to the present invention is further provided with a buffering means (D) for fixing the leg member (B) on the upper surface thereof and preventing vibration from being transmitted to the case (A) when an earthquake occurs.

3 to 5, the buffering means D is made of a concrete material and has a base 10 having a lower guide rail 11 extending in the front-rear direction on the upper surface thereof, A lower slide panel 20 slidably coupled to the lower guide rail 11 in a forward and backward direction and having an upper guide rail 21 extending laterally on the upper surface thereof, An upper slide panel 30 which is slidably coupled in the lateral direction and on which the leg member B is fixed, a lower measuring mechanism 40 connected to the lower slide panel 20, A lower position adjusting means 60 connected to the lower slide panel 20 to adjust the position of the lower slide panel 20 in the forward and backward directions, And the upper slide An upper position adjusting means 70 for adjusting the position of the panel 30 in the lateral direction and a lower braking means 80 connected to the lower slide panel 20 for fixing the lower slide panel 20 so as not to slide in the forward and backward directions An upper braking unit 90 connected to the upper slide panel 30 to fix the upper slide panel 30 so as to prevent the upper slide panel 30 from sliding in the forward and backward directions, And an upper and a lower braking means 80 and 90 for receiving signals from the lower measuring mechanism 40, the upper measuring mechanism 50 and the seismic sensor 100, And control means (110) for controlling the operation of the means (60,70).

The base 10 is formed in a square block shape of a concrete material whose upper surface is flat and is fixed to the ground.

The lower guide rails 11 are provided on both sides of the upper surface of the base 10 so as to be mutually laterally spaced.

The lower slide panel 20 is formed in the shape of a rectangular plate made of a metal material having a high strength. The lower slide panel 20 is formed on both sides of the lower side and has a bar shape extending in the forward and backward directions. A lower slide block 22 is provided.

The upper and lower slide blocks 22 are spaced from each other in the lateral direction so as to correspond to the intervals of the lower guide rails 11, and a lower rack gear 23 is formed on one side surface thereof.

The upper guide rails 21 are spaced apart from each other on the upper surface of the lower slide panel 20 in the forward and backward directions.

The upper slide panel 30 is formed in the shape of a rectangular plate of a metal material having a high strength. The upper slide panel 30 is formed in a bar shape extending laterally on both sides of the lower side and is slidable laterally on the upper surface of the upper guide rail 21 A top slide block 31 is provided.

The upper slide blocks 31 are spaced from each other in the forward and backward directions so as to correspond to the intervals of the upper guide rails 21, and an upper rack gear 32 is formed on the front surface.

The lower measuring mechanism 40 and the upper measuring mechanism 50 are rotatably coupled to the base 10 and the lower slide panel 20 and are engaged with the lower rack gear 23 and the upper rack gear 32, And a lower angle sensor 42 and an upper angle sensor 52 for measuring the rotational angles of the lower driven gear 41 and the upper driven gear 51. The lower driven gear 41 and the upper driven gear 51, .

The lower driven gear 41 and the upper driven gear 51 are rotatably coupled to rotary shafts 12 and 24 provided on the upper surface of the base 10 and the lower slide panel 20 so as to extend in the vertical direction.

The lower angle sensor 42 and the upper angle sensor 52 are fixedly coupled to the rotation shafts 12 and 24 so that the lower driven gear 41 and the lower driven gear 41 are rotated when the lower driven gear 41 and the upper driven gear 51 are rotated, And the angle of rotation of the upper driven gear (51) is measured and output to the control means (110).

Since the diameters of the upper and lower driven gears 41 and 51 are known, the angle at which the upper and lower driven gears 41 and 51 are rotated is measured using the upper and lower angle sensors 42 and 52 The upper and lower slide blocks 22 and 31 and the upper and lower slide panels 20 and 30 are slid in the front and rear directions or in the left and right directions at the central portions of the upper and lower guide rails 11 and 21 Can be calculated.

The lower position adjusting means 60 and the upper position adjusting means 70 comprise a lower pinion gear 61 and an upper pinion gear 71 coupled to the lower rack gear 23 and the upper rack gear 32, And a lower drive motor 62 and an upper drive motor 72 connected to the lower pinion gear 61 and the upper pinion gear 71, respectively.

The lower driving motor 62 and the upper driving motor 72 use a BLDS motor that does not generate a resistance force when not driven.

Accordingly, when the upper and lower drive motors 62 and 72 are driven, the upper and lower pinion gears 61 and 71 are rotated to slide the lower slide block 22 in the forward and backward directions, (31) is laterally slid.

On the contrary, when the upper and lower drive motors 62 and 72 are stopped, the lower slide block 22 and the upper slide block 31 are freely slidable in the front-rear direction or the left-right direction.

The lower braking means 80 is provided on one side of the lower slide block 22 and is configured to press the peripheral portion of the lower guide rail 11 to fix the lower slide block 22 so as not to move.

The upper braking means 90 is provided on one side of the upper slide block 31 and is configured to press the peripheral portion of the upper guide rail 21 to fix the upper slide block 31 so that it does not move.

When the lower slide block 22 and the upper slide block 31 are positioned at the center of the lower guide rail 11 and the upper guide rail 21, the upper and lower braking means 80, Is operated by the control signal of the means (110) to fix the upper and lower slide blocks (22, 31) so as not to move.

That is, the lower slide panel 20 and the upper slide panel 30 are slidably coupled to the lower guide rail 11 and the upper guide rail 21 in the forward, backward, left and right directions, respectively, 11 and the upper guide rail 21 are not perfectly horizontal and vibrations generated by a vehicle passing around can be transmitted. In this case, the lower slide panel 20 and the upper slide rail 21 30 can be slid toward the end portions of the lower guide rail 11 and the upper guide rail 21. The lower slide panel 20 and the upper slide panel 30 can be slid toward the end portions of the lower guide rail 11 and the upper guide rail 21, The lower slide panel 20 and the upper slide panel 30 are caught by the end portions of the lower guide rail 11 and the upper guide rail 21 to be freely engaged with each other when an earthquake occurs in a state of being slid toward the end of the guide rail 21. [It may not flow.

At this time, the upper and lower braking means 80 and 90 are moved in a state in which the lower slide block 22 and the upper slide block 31 are positioned at the central portions of the lower guide rail 11 and the upper guide rail 21, The lower slide block 22 and the upper slide block 31 are fixed by using the upper and lower slide blocks 22 and 31. When the brakes of the upper and lower braking means 80 and 90 are released when an earthquake occurs, It is possible to freely absorb vibration in the front, rear, and left and right directions while being slid back and forth and in the lateral direction.

The earthquake detection sensor 100 senses that the foundation 10 is vibrated by an earthquake and outputs a signal. The sensor 100 is widely used, and a detailed description thereof will be omitted.

The control means 110 releases the brakes of the upper and lower braking means 80 and 90 to stop the braking of the upper slide block 22 and the upper slide block 22, When the base 10 is vibrated back and forth and in the left and right directions by an earthquake by sliding the base 31 along the lower guide rail 11 and the upper guide rail 21, Backward and lateral vibration of the leg member (B) is prevented from being transmitted to the leg member (B).

 At the same time, the control means 110 controls the operation of the lower position adjusting means 60 and the upper position adjusting means 70 while feeding back the signals of the lower measuring mechanism 40 and the upper measuring mechanism 50, The slide block 22 and the upper slide block 31 are adjusted so as not to be separated from the lower guide rail 11 and the upper guide rail 21.

6 and 7, the vibration of the base 10 causes the vibration of the lower slide block 22 to be transmitted to the lower slide block 22, The upper slide block 31 and the upper slide block 31 are swung in the front and rear directions and in the left and right direction with respect to the base 10. The upper and lower guide rails 11 and 21 are inclined, The upper slide block 31 and the upper slide block 31 can not vibrate within a certain range and the centers of both ends of the vibrating center, that is, the positions where the lower slide block 22 and the upper slide block 31 are vibrated, The lower slide block 22 and the upper slide block 31 may collide with the ends of the lower guide rail 11 or the upper guide rail 21 .

At this time, the control means 110 receives the signals of the lower measuring mechanism 40 and the upper measuring mechanism 50, and the vibration center, at which the lower slide block 22 and the upper slide block 31 are vibrated, The lower position adjusting means 60 and the upper position adjusting means 70 are driven to move the upper and lower slide blocks 11 and 20 to the lower guide rail 11 or the upper guide rail 21, 22, 31 are positioned at the center of the upper and lower guide rails 11,

For example, when the vibration center of the lower slide block 22 is moved forward of the lower guide rail 11, when the lower slide block 22 slides rearward, the lower position adjusting means 60 So that the vibration center of the lower slide block 22 can be positioned at the center of the lower guide rail 11. The lower slide block 22 can be moved in the vertical direction.

Therefore, the lower slide block 22 and the upper slide block 31 are vibrated back and forth or in the left and right direction at the central portions of the lower guide rail 11 and the upper guide rail 21, Thereby preventing the slide block 31 from escaping from the lower guide rail 11 and the upper guide rail 21.

When the control unit 110 receives the signal of the seismic sensor 100 and judges that the earthquake has stopped, the control unit 110 drives the upper and lower position adjusting units 60 and 70, The upper and lower slide rails 22 and 31 are adjusted to be positioned at the center of the upper and lower guide rails 11 and 21 and then the upper and lower braking means 80 and 90 are operated, ) To prevent it from moving.

In the switchboard having the earthquake-proof function, the upper slide panel 20 and the upper slide panel 30 are fixed by the upper and lower braking means 80 and 90 so that the lower slide panel 20 and the upper slide panel 30 do not move, The lower slide panel 20 and the lower slide panel 20 can freely move upward and downward by controlling the upper and lower braking means 80 and 90 by releasing the fixing by the control means 110 And the lower guide rails 11 and 21 freely absorb the vibration of the base 10 to move the leg member B provided in the upper slide panel 30 to the case A, There is an advantage that the unit C can be prevented from being damaged.

The operation of the lower position adjusting means 60 and the upper position adjusting means 70 is controlled while feeding back the signals of the lower measuring mechanism 40 and the upper measuring mechanism 50 so that the lower slide block 22 and the upper The slide block 31 is controlled so as not to deviate from the lower guide rail 11 and the upper guide rail 21 so that vibration or impact is transmitted to the leg member B, the case A, and the power distribution unit C There is an advantage that it can be prevented more effectively.

That is, generally, when the slide block which is freely slid along the guide rail is not moved excessively toward the end portion of the guide rail, a spring or a damper is provided at both ends of the guide rail so that the slide block is excessively moved toward the end of the guide rail In this case, when the base 10 vibrates, the leg member B, the case A, and the power distribution unit C (not shown) The impact can be transmitted.

On the contrary, in the present invention, the upper and lower slide blocks 22 and 31 are moved up and down by using the upper and lower measuring mechanisms 40 and 50 and the upper and lower position adjusting means 60 and 70, It is possible to prevent an impact from being transmitted to the leg member B, the case A, and the power distribution unit C when the base 10 vibrates by adjusting the vibrations at the central portions of the rails 11 and 21 , The leg member (B), the case (A), and the power distribution unit (C) are more effectively prevented from being damaged by the impact.

8 to 12 illustrate a second embodiment according to the present invention. In the second embodiment, when a fire is generated in the power distribution unit C, (130) provided on the outer circumferential surface of the case (A) so as to face the periphery of the case (A) A warning means 150 provided at one side of the case A and a plurality of air blowing means 140 provided outside the case A on the outer side of the case A, A nozzle 160 and an air supply unit 170 that is operated under the control of the control unit 110 and supplies high-pressure air to the air injection nozzle 160.

The fire detection means 120 is provided at one side of the case A so that when the temperature of the power distribution unit C rises to a predetermined temperature or higher and smoke is generated, And outputs a signal to the control means.

The fire extinguisher 130 uses a powder fire extinguisher 130 which injects fire extinguishing powder into the power distribution unit C under the control of the control means.

The proximity sensor 140 detects a proximity of an object within a preset distance using ultrasonic waves, and is very general and will not be described in detail.

The air injection nozzle 160 includes a plurality of nozzle bodies 142 arranged to be spaced apart from each other on the outer surface of the air supply tube 141, ).

The warning means 150 is provided at one side of the case A, and is configured to be operated and controlled by the control means 110 to output a previously stored announcement message.

The announcement means stored in the warning means 150 may consist of 'a fire has occurred in the switchboard, please keep it away from the switchboard'.

The air supply unit 170 is provided at one side of the case A and connected to the air supply unit 141 to supply high pressure air to the air supply unit 141

The control means 110 monitors the signal of the fire sensing means 120 and detects the occurrence of a fire to operate the fire extinguisher 130 to suppress the fire as shown in FIG.

At the same time, the control means 110 receives the signal of the proximity sensor 140 and drives the warning means 150 when there is a person close to the periphery of the case A, To be warned.

The control means 110 receives a signal of the proximity sensor 140 and outputs a warning to the warning means 150 after a predetermined time has elapsed The air supply unit 170 is driven to blow air to the periphery of the case A through the air injection nozzle 160 as shown in FIG.

When air is injected from the air injection nozzle 160 in this manner, air is strongly blown toward a person in the vicinity of the case A, and people are forced to move away from the case A in a surprise.

When a fire is generated in the power distribution unit C, the switchboard having the above-described earthquake-proof function operates the fire extinguisher 130 to automatically suppress the fire. When there is a person near the case A, And a person is forced to move away from the case A by injecting air through the air injection nozzle 160 when the person is not distanced even after the warning output, There is an advantage that a person can be prevented from being wounded and injured by a short circuit generated in the power distribution unit C damaged by heat or fire.

A. Case B. Support
C. Power distribution unit D. Buffering means
10. Foundation 20. Lower slide panel
30. Upper slide panel 40. Lower measuring instrument
50. Upper measuring instrument 60. Lower position adjusting means
70. Upper position adjusting means 80. Lower braking means
90. Upper braking means 100. Earthquake detection sensor
110. Control means 120. Fire detection means
130. Fire extinguisher 140. Proximity sensor
150. Warning means 160. Air injection nozzle
170. Supply means

Claims (2)

A case (A) made of a metal material and spaced upward from the ground by a leg member (B) provided on a lower side,
In an electric distribution board including a power distribution unit (C) provided inside the case (A)
(D) for fixing the leg member (B) on the upper surface and preventing vibration from being transmitted to the case (A) when an earthquake occurs,
The buffer means (D)
A base 10 fixed to the floor and having a lower guide rail 11 extending in the front and rear direction,
A lower slide panel 20 slidably coupled to the lower guide rail 11 in the front-rear direction and having an upper guide rail 21 extending laterally,
An upper slide panel (30) slidably coupled to the upper guide rail (21) in a lateral direction and having the leg member (B) fixed on an upper surface thereof,
A lower measuring mechanism 40 connected to the lower slide panel 20,
An upper measuring mechanism 50 connected to the upper slide panel 30,
A lower position adjusting means 60 connected to the lower slide panel 20 to adjust the position of the lower slide panel 20 in the forward and backward directions,
Upper position adjusting means 70 connected to the upper slide panel 30 to adjust the position of the upper slide panel 30 in the lateral direction,
A lower braking means 80 connected to the lower slide panel 20 for fixing the lower slide panel 20 so as not to slide in the forward and backward directions,
An upper braking means 90 connected to the upper slide panel 30 to fix the upper slide panel 30 so as not to slide in the lateral direction,
An earthquake detection sensor 100 provided on the foundation 10 for detecting the occurrence of an earthquake,
The operation of the upper and lower braking means 80 and 90 and the operation of the upper and lower position adjusting means 60 and 70 is performed by receiving signals of the lower measuring mechanism 40, the upper measuring mechanism 50 and the seismic sensor 100, And a control means (110)
A lower slide block 22 is formed on the lower side of the lower slide panel 20 and is coupled to the lower guide rail 11 so as to be slidable in forward and backward directions and has a lower rack gear 23 on its side. And,
An upper slide block 31 extending laterally from the lower side of the upper slide panel 30 and slidably coupled to the upper guide rail 21 in a lateral direction and having an upper rack gear 32 formed on the front side thereof And,
The lower measuring mechanism 40 and the upper measuring mechanism 50
A lower driven gear 41 and an upper driven gear 51 rotatably coupled to the base 10 and the lower slide panel 20 and meshed with the lower rack gear 23 and the upper rack gear 32, ,
And a lower angle sensor (42) and an upper angle sensor (52) for measuring the rotation angle of the lower driven gear (41) and the upper driven gear (51)
The upper and lower braking means 80 and 90 fix the lower slide block 22 and the upper slide block 31 so as to be located at the central portions of the lower guide rail 11 and the upper guide rail 21,
The control means 110 releases the brakes of the upper and lower braking means 80 and 90 to stop the braking of the upper slide block 22 and the upper slide block 22, The lower measuring mechanism 40 and the upper measuring mechanism 50 are fed back while the upper measuring mechanism 31 is slid in the forward and backward directions along the lower guide rail 11 and the upper guide rail 21, The operation of the adjusting means 60 and the upper position adjusting means 70 is controlled so that the lower slide block 22 and the upper slide block 31 do not come off the lower guide rail 11 and the upper guide rail 21 Regulating,
A fire detection means 120 provided in the case A for detecting a fire in the power distribution unit C and outputting a signal,
A fire extinguisher 130 provided inside the case A to face the power distribution unit C,
A proximity sensor 140 provided on an outer circumferential surface of the case A to sense a person approaching the periphery of the case A,
An alarm means 150 provided at one side of the case A,
A plurality of air injection nozzles 160 provided outwardly on the outer surface of the case A,
Further comprising an air supply means (170) operated under the control of the control means (110) to supply high pressure air to the air injection nozzle (160)
The control unit 110 receives the signal of the fire sensing unit 120 and activates the fire extinguisher 130 when the fire is detected and receives the signal of the proximity sensing sensor 140 When a person close to the periphery of the case A is present, the warning means 150 is driven to warn a person in the vicinity, and even if a person near the case A reaches a preset distance The air supply unit 170 is driven to blow air to the periphery of the case A through the air injection nozzle 160. In this case,
The control means 110 receives the signals of the lower measuring mechanism 40 and the upper measuring mechanism 50 and detects the vibration center of the lower slide block 22 or the upper slide block 31, The lower position adjusting means 60 and the upper position adjusting means 70 are driven to detect the movement of the lower slide block 22 or the upper guide rail 21 to one side of the guide rail 11 or the upper guide rail 21, And the vibration center of the slide block (31) is adjusted to be restored to the center of the lower guide rail (11) or the upper guide rail (21). delete

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