KR102646135B1 - Electric switchboard with modular earthquake-resistant structure - Google Patents

Abstract

An electric switchboard with a modular earthquake-resistant structure according to an embodiment of the present invention includes a switchboard body in which electric devices are stored therein; An upper base installed on the lower surface of the switchboard body; a lower base spaced downward from the switchboard body and installed on the ground; A plurality of movement guide parts disposed between the upper base and the lower base, arranged on the outside in a vertical wrinkled shape and having fixed upper ends, and disposed in the center of the plurality of movement guide parts and connecting the upper base and the lower base. An earthquake-resistant unit equipped with a vibration damping unit to attenuate movement; A sensor unit mounted within the earthquake-resistant unit and measuring a state quantity; And a control unit that compares and determines the state quantity measured by the sensor unit with a reference value to control power supply to the electric device. It includes a control unit that blocks the power supply to the electric device when the state quantity measured by the sensor unit exceeds the standard value. It is characterized by

Description

Electric switchboard with modular earthquake-resistant structure}

The present invention relates to an electric switchboard with a modular earthquake-resistant structure that can withstand external forces such as earthquakes.

In general, a switchboard is an electrical facility that safely supplies industrial power to users, and is widely used to monitor, control, and protect the electric system when receiving and distributing power sent from a power plant or substation to consumers. Such a switchboard generally includes an enclosure with a storage space inside to attach and support electronic devices such as circuit breakers and protection relays.

Recently, large and small earthquakes have occurred not only in Korea but also in many regions around the world, causing numerous casualties and property damage. The most basic countermeasure against such earthquake damage is to ensure that artificial structures have sufficient earthquake resistance by taking into account the local ground during design and construction.

This is very important in modern metropolitan cities with dense populations and many high-rise buildings. In accordance with these measures, governments in each country are increasingly mandating that new buildings be equipped with dustproof facilities. In addition, factories, government offices, and hospitals have generators installed to provide a minimum amount of emergency power through self-generation when commercial power is cut off.

However, these conventional generators are designed to prepare for earthquakes with only anchor bolts to secure them and stoppers to prevent the generator from falling, so there is a limit to actually suppressing the vibration of the generator. As a result, if the generator cannot withstand the vibrations of an earthquake and is damaged or overturned, the generator cannot produce emergency power and thus cannot supply the power needed for disaster relief, which can cause serious social damage.

Therefore, the switchboard or generator is firmly fixed to the ground to prevent it from shaking or falling over. If it is firmly fixed to the ground in this way, when an earthquake occurs, a large impact may be applied to the switchboard fixed to the ground due to the impact of seismic waves, which may deform the shape of the switchboard or damage various electronic devices installed inside the switchboard, especially when exposed to large vibrations. This may cause the switchboard to collapse.

In addition, if switchboards or generators are not designed to be earthquake-resistant, they may frequently be damaged or fall down due to earthquakes, causing problems in power supply and secondary damage due to power outages after an earthquake. Therefore, switchboards and generators that play an important role in power supply and demand require earthquake-resistant design to minimize damage and prevent collapse due to shock or vibration applied by an earthquake.

Republic of Korea Patent Publication No. 10-1714716

The present invention was developed to solve the above-mentioned problems. It has a modular structure, making it easy to replace parts due to damage or deterioration. The structure is simple, so installation is easy, and the direction is free without restrictions depending on the direction of the seismic wave. It is movable and its purpose is to prevent vibration from being transmitted to electrical devices in the switchboard.

It is not limited to the technical challenges described above, and other technical challenges may be derived from the description below.

The present invention for achieving the above object includes a switchboard body in which electric devices are stored; An upper base installed on the lower surface of the switchboard body; a lower base spaced downward from the switchboard body and installed on the ground; A plurality of movement guide parts disposed between the upper base and the lower base, arranged on the outside in a vertical wrinkled shape and having fixed upper ends, and disposed in the center of the plurality of movement guide parts and connecting the upper base and the lower base. A seismic unit equipped with a vibration damping unit to attenuate movement; A sensor unit mounted within the earthquake-resistant unit and measuring a state quantity; a control unit that controls power supply to the electric device by comparing and determining the state quantity measured by the sensor unit and a reference value; A moving member disposed between the upper base and the lower base and installed on the inner edge of the switchboard body, mounted on the upper base and having a lower part recessed, and a movement that limits the movement of the moving member when inserted into the lower part of the moving member. Fixed unit equipped with a restrictor; A power supply unit that supplies power to the electric device; and an administrator terminal that receives an earthquake alarm signal from the control unit, wherein the sensor unit includes a vibration detection sensor that measures the frequency within the earthquake-resistant unit, a movement detection sensor that measures a movement value, and a movement device and movement within the fixed unit. It includes an impact detection sensor that measures the impact value of hitting the limiting ball, and the control unit blocks power supply from the power supply unit when the impact value measured by the impact detection sensor exceeds the standard impact value, and the manager terminal An earthquake alarm message is output, and if the measured frequency exceeds the standard frequency and one or more of the measured movement value and the measured shock value do not exceed the standard range, a replacement and inspection alarm message is output to the manager terminal. Make it possible.

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In addition, the control unit cuts off power supply from the power supply unit when the frequency measured by the vibration detection sensor exceeds the reference frequency and outputs an earthquake alarm message to the manager terminal.

In addition, the control unit cuts off power supply from the power supply unit when the movement value measured by the movement detection sensor exceeds the reference movement value and outputs an earthquake alarm message to the manager terminal.

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The electric switchboard with a modular earthquake-resistant structure according to an embodiment of the present invention configured as described above has the following advantages.

It has a modular structure, making it easy to replace parts due to damage or aging. The simple structure makes installation easy, and it can move freely without restrictions depending on the direction of the seismic wave, preventing vibration transmission to electrical devices in the switchboard. there is.

In addition, the movable support member of the earthquake-resistant unit has a finger structure, which has the advantage of supporting the switchboard body and allowing it to move freely in multiple directions. In addition, the moving support earth of the earthquake-resistant unit can be installed in an array structure suitable for the direction of seismic waves according to the area or location where the electric switchboard is installed.

In addition, the earthquake-resistant unit and the fixed unit are fixedly installed on a movable plate and a fixed plate, respectively, so there is an advantage of easy installation and replacement due to the modular structure. Additionally, the movement of the switchboard body can be restricted by the fixing unit to prevent the switchboard body from falling over.

In addition, vibration, movement, and impact state quantities can be measured by the sensor unit, and secondary accidents can be prevented in advance by controlling the power supply to electric devices by comparing and judging the measured state quantities and reference values. In addition, an earthquake alarm message or a replacement and inspection alarm message can be output through the administrator terminal carried by the administrator, making maintenance easy and prompt response.

Figure 1 is an exemplary installation diagram of an electric switchboard according to an embodiment of the present invention.
Figure 2 is a configuration diagram of an earthquake-resistant unit of an electric switchboard according to an embodiment of the present invention.
Figure 3 is a detailed view of the upper mounting portion of the movement guide part of Figure 2.
Figure 4 is a detailed view of the movement guidance tool of the movement guidance part of Figure 2.
Figure 5 is a configuration diagram of an earthquake-resistant unit of an electric switchboard according to another embodiment of the present invention.
Figure 6 is an operational diagram of the earthquake-resistant unit of an electric distribution board according to an embodiment of the present invention.
Figure 7 is an arrangement structure diagram of the movement guidance part of the earthquake-resistant unit according to an embodiment of the present invention.
Figure 8 is a configuration diagram of a fixing unit of an electric distribution board according to an embodiment of the present invention.
Figure 9 is a configuration diagram showing a state in which the movement of the fixing unit of Figure 8 is restricted.
Figure 10 is a configuration diagram of an earthquake-proof device for a shelf of an electric distribution board according to an embodiment of the present invention.
Figure 11 is a block diagram of a control unit of an electric switchboard according to an embodiment of the present invention.
Figure 12 is a diagram showing a control sequence using a vibration detection sensor of an electric switchboard according to an embodiment of the present invention.
Figure 13 is a diagram showing a control sequence using a movement detection sensor of an electric switchboard according to an embodiment of the present invention.
Figure 14 is a diagram showing a control sequence using an impact detection sensor of an electric switchboard according to an embodiment of the present invention.
Figure 15 is a diagram showing a control sequence using the sensor unit of an electric switchboard according to an embodiment of the present invention.

Hereinafter, with reference to the attached drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily implement the present invention. The present invention may be implemented in many different forms and is not limited to the structure or method described herein.

The embodiment of the present invention has a modular structure, making it easy to replace parts due to damage or deterioration, the structure is simple, so installation is easy, and it can be moved freely without direction restrictions depending on the direction of the seismic wave, so it can be used as an electrical device in the distribution panel. This relates to an electric switchboard with a modular earthquake-resistant structure that prevents vibration transmission. Hereinafter, it will be simply referred to as an “electric switchboard.”

Figure 1 is a diagram illustrating the installation of an electric switchboard according to an embodiment of the present invention, and Figure 2 is a configuration diagram of an earthquake-resistant unit of an electric switchboard according to an embodiment of the present invention. And FIG. 3 is a detailed view of the upper mounting device of the movement guidance unit of FIG. 2, and FIG. 4 is a detailed view of the movement guidance device of the movement guidance unit of FIG. 2.

Figure 5 is a configuration diagram of an earthquake-resistant unit of an electric switchboard according to another embodiment of the present invention, and Figure 6 is a diagram illustrating an operation of the earthquake-proof unit of an electric switchboard according to an embodiment of the present invention. And Figure 7 is a structural diagram of the movement inducing part of the earthquake-resistant unit according to an embodiment of the present invention, and Figure 8 is a structural diagram of a fixing unit of an electric switchboard according to an embodiment of the present invention.

FIG. 9 is a configuration diagram showing a state in which the movement of the fixing unit of FIG. 8 is restricted, and FIG. 10 is a configuration diagram of an earthquake-proof device for a shelf of an electric switchboard according to an embodiment of the present invention.

In addition, with respect to the up, down, left and right directions of the electric switchboard of this embodiment, the left direction is defined as 'one side', the right direction is defined as 'the other side', and the ground direction is defined as 'downward' and the opposite direction, based on the switchboard body shown in Figure 1. An embodiment of the present invention will be described by defining the direction as 'upward'. This is for the purpose of explaining the present invention so that it can be clearly understood, and of course, each direction may be defined differently depending on where the standard is set.

As shown in Figures 1 to 10, the electric switchboard according to an embodiment of the present invention has a modular structure, making it easy to install and replace, and is equipped to support the electric switchboard and move along the direction of the earthquake when an earthquake occurs, thereby Vibrations are not transmitted to the switchboard, preventing accidents. In addition, the electric switchboard of the present invention includes a switchboard body 100, an upper base 200, a lower base 300, an earthquake-resistant unit 400, a fixing unit 500, an earthquake-proof device for a shelf 600, and a sensor unit 700. ), and may include a control unit 1000.

The switchboard body 100 is in the form of a cabinet in which electric devices are stored inside. The switchboard body 100 is designed with an earthquake-resistant structure to prevent electrical devices from being broken or damaged by earthquakes or external forces. In this way, the switchboard body 100 may be made of a metal frame to protect the electrical equipment, and is equipped to reduce shock from the outside.

The upper base 200 is configured to provide space for the switchboard main body 100 to be installed. The upper base 200 is made of a flat plate and is installed on the lower surface of the switchboard main body 100, and is equipped so that the switchboard main body 100 can be erected horizontally. In this way, the upper base 200 may be made of a steel plate material of a standard thickness, and is equipped so that the switchboard body 100 can be installed in a fixed or lying state with bolts. In addition, the upper base 200 is fixed to the upper part of the earthquake-resistant unit 400 and is interlocked with the earthquake-resistant unit 400 so that the upper base 200 can move together.

The lower base 300 is configured to provide a space so that the lower part of the earthquake-resistant unit 400 is fixed. These lower bases 300 are arranged spaced apart below the switchboard main body 100, and can be placed on the ground or installed at a predetermined interval by an installation frame. The lower base 300 may be made of a steel plate material with a similar standard thickness as the upper base 200, and is equipped so that the earthquake-resistant unit 400 can be fixed with bolts. That is, the lower base 300 is equipped to transmit vibration generated from the ground when an earthquake occurs to the earthquake-resistant unit 400.

The earthquake-resistant unit 400 is configured to uniformly support the switchboard body 100 and at the same time attenuate vibration. These earthquake-resistant units 400 may be disposed between the upper base 200 and the lower base 300 and installed at the edges of the switchboard main body 100, respectively. In addition, the earthquake-resistant unit 400 is installed so that the load of the switchboard body 100 is evenly distributed and has a structure that can be safely supported.

In detail, the earthquake-resistant unit 400 may include a movable plate 410, a fixed plate 420, a movement guide unit 430, and a vibration damping unit 440. The earthquake-resistant unit 400 composed of this configuration prevents the transmission of vibration to the distribution board body 100 by moving the movement inducing part 430 according to the direction of the earthquake, and is equipped with a modular structure to enable partial replacement.

The movable plate 410 is fixed to the lower surface of the upper base 200, and a plurality of mounting holes 411 may be formed at the edge. At this time, a plurality of mounting holes 411 are formed to penetrate the movable plate 410 in a vertical direction, and a groove 411a of a set shape may be formed at the lower portion to allow the movement guide 430 to be mounted. Here, the plurality of mounting holes 411 may have a set-shaped groove 411a formed as a circular or square groove, and a fixing jaw 411b protruding inward may be formed at the central height point.

And the movable plate 410 can be screwed to the movement guide 430 through a plurality of mounting holes 411. In addition, the movable plate 410 has a plurality of mounting holes 411 formed at its edges so that four movement guide parts 430 can be mounted at each point. In this way, the movable plate 410 is equipped so that the movement guide parts 430 can be arranged and installed at even intervals, so that the load can be distributed evenly. In addition, the movable plate 410 extends downward from the center and the lower end protrudes laterally to form a mounting protrusion 412.

The fixed plate 420 is fixed to the upper surface of the lower base 300 and may be in the form of a flat plate. At this time, the fixed plate 420 may be made of a steel plate material and is equipped so that the vibration damping part 440 can be attached. In addition, the fixed plate 420 can be provided with a smooth surface treatment, and the end of the movement guide part 430 is equipped so that it can be moved in contact with it.

The movement guidance unit 430 may be arranged on the outside in a vertically wrinkled shape and fixed at the top. At this time, the movement guidance unit 430 may include an upper mounting unit 431, a movement support unit 432, and a movement guidance unit 433. The movement inducing part 430 with this configuration may be made of rubber, an elastic material with high hardness, and is equipped to support the switchboard main body 100 and at the same time play the role of damping vibration.

The upper mounting port 431 is respectively inserted and fixed into the mounting hole 411 of the movable plate 410, and a fixing screw groove 431-1 is formed in the center to enable attachment and separation from the movable plate 410. You can. In detail, the upper mounting port 431 is disposed at the top and has an insertion guide surface 431a whose outer peripheral surface is inclined downward, and which extends to the lower part of the insertion guide surface 431a and is formed to be recessed inward, forming a movable plate 410. A fixed recessed surface (431b) that is in close contact with the fixed jaw (411b) formed in the mounting hole (411), and a fixed seating surface that extends to the lower part of the fixed recessed surface (431b) and is formed to correspond to and adheres to the mounting hole (411). It may include (431c).

The movable support member 432 extends downward from the upper mounting portion 431, and has a finger structure in which wave-shaped corrugated protrusions 432a are continuously formed on the outer surface, and may have a hemispherical end. Additionally, the movable support member 432 may have a flat inner surface to form a plurality of wrinkle grooves 432b. In particular, the movable support member 432 is equipped with corrugated protrusions 432a and corrugated grooves 432b so that they can be convexly opened outward after the switchboard main body 100 is installed. In this way, the movable support member 432 can improve the support force due to the finger structure and makes it easy to move according to the direction of vibration.

The movable support member 432 may be formed in a wave shape in which the corrugated protrusions 432a are deeper and wider than the corrugated grooves 432b. In this way, the movable support member 432 is equipped to be flexibly bent outward due to the shape of the corrugated protrusion 432a. Additionally, the movable support member 432 may have a hollow interior so that it can be bent more flexibly. And the Idongji district (432) is As shown in FIG. 5, wrinkle protrusions 432a may be formed along the finger-shaped outer peripheral surface. This movable support unit 432 is equipped to be easily moved in multiple directions and can be bent depending on the direction, thereby minimizing the impact of earthquake resistance.

As shown in FIG. 7, the movable support district 432 can be arranged in an array structure taking into account the direction of vibration according to the seismic waves in the installation area. This movable support unit 432 can change its arrangement structure according to the direction of vibration due to its separable structure within the earthquake-resistant unit 400, and is equipped to provide an optimized earthquake-resistant structure for each installation area.

The movement guide 433 is mounted on the end of the movable support 432 and has a hemispherical shape so that it can be moved on the upper surface of the fixed plate 420. Additionally, the movement guide 433 may be made of a metal material and is equipped to be mounted on the bottom of the movement support device 432 made of an elastic rubber material. At this time, the movement guide 433 is made of a metal material so that it can be moved smoothly along the direction of vibration on the upper surface of the lower base 300.

For example, the movable support device 432 has a plurality of fixing protrusions 432c protruding in a hemispherical shape along the outer peripheral surface at the end, and a fixing groove corresponding to the fixing protrusion 432c along the inner peripheral surface of the movement guide 433. (433a) may be formed into a depression and combined. As another example, the movable support device 432 has a 'T' shaped fixing groove 432c' recessed upward at the bottom, and corresponds to the fixing groove 432c' at the center of the inner peripheral surface of the movement guide 433. Preferably, a 'T' shaped fixing protrusion 433a' may be formed to protrude and be coupled.

The vibration damping unit 440 is disposed in the center of the movement inducing unit 430, and can connect the upper base 200 and the lower base 300 to dampen movement. In detail, the vibration damping unit 440 is equipped so that its upper and lower ends can be connected to the mounting protrusion 412 of the movable plate 410 and the lower fixed plate 420. At this time, the vibration damping unit 440 may include an elastic body 441, a magnetic body 442, and a connector 443.

The elastic body 441 is in the form of a spring, and its upper end is mounted on the mounting protrusion 412 of the movable plate 410 so that it can be erected vertically. The magnetic material 442 may be attached to the upper surface of the fixed plate 420 by magnetic force. The connector 443 is fitted at the bottom of the elastic body 441 and may be fixed to the upper surface of the magnetic body 442. The vibration damping unit 440 composed of this configuration allows the magnetic substance 442 to be temporarily separated from the fixed plate 420 as the elastic body 441 moves according to the moving direction of the movement inducing unit 430 and then reattached by magnetic force. It can be equipped.

The vibration damping unit 440 configured in this way serves to attenuate vibration by allowing the movement inducing unit 430 to be stopped while moving in the direction of vibration. In this way, the vibration damping unit 440 can stop the repeated movement of the movement inducing unit 430. In addition, the vibration damping part 440 is equipped so that it can be temporarily separated from the fixed plate 420 by the elastic body 441, and the movement inducing part 430 is moved according to the direction of vibration to cause vibration to the switchboard main body 100. This can be effectively prevented from being transmitted.

The fixing unit 500 is configured to prevent the switchboard main body 100 from falling due to excessive movement of the earthquake-resistant unit 400. This fixing unit 500 is disposed between the upper base 200 and the lower base 300, and is preferably installed inside the earthquake-resistant unit 400. In addition, the fixing unit 500 includes a moving device 510 that moves according to the movement of the movement inducing part 430 of the seismic unit 400, a movement limiting device 520 that limits the movement of the moving device 510, and a moving limiting device. It may include a fixed base 524 that provides an installation space for 520.

The moving tool 510 is installed on the inner edge of the switchboard body 100, is mounted on the upper base 200, and the lower part may be recessed. This moving device 510 moves in conjunction with the moving direction of the moving guide unit 430, and is capable of moving in multiple directions on a plane and is also equipped to move in the vertical direction. In detail, the moving device 510 may include a moving space 511, a moving guide surface 512, and a moving limiting protrusion 513.

The movement space 511 is partially open downward, is recessed inward, and is equipped to form a space therein. And the moving guide surface 512 may be formed such that the upper surface of the moving space 511 is convex upward. The movement limiting protrusion 513 may be formed to protrude convexly inward at the bottom of the inner surface of the movement space 511. At this time, the movement limiting protrusion 513 may be formed to protrude in a hemispherical shape, and is equipped to engage with the movement limiting sphere 520, so that it can be restricted from moving beyond a certain distance.

The movement limiting device 520 may restrict the movement of the moving device 510 while being inserted into the lower portion of the moving device 510 . In this way, the movement limiter 520 can prevent the switchboard main body 100 from falling due to excessive movement distance of the seismic unit 400 by limiting the moving distance of the movement member 510. In detail, the movement limiter 520 may include a fixed body 521, a movable protrusion 522, and a movement limit groove 523. The fixing body 521 is made in a cylindrical shape and its upper surface may be formed to be convex upward so that it can be inserted into the lower part of the moving tool 510.

A plurality of moving protrusions 522 may be formed to protrude from the upper surface of the fixed body 521 in a small hemisphere shape. At this time, the moving protrusion 522 may be made of a metal material and may be equipped to move smoothly along the moving guide surface 512. And the movement limiting groove 523 is formed along the central outer peripheral surface of the fixing body 521 to correspond to the shape of the movement limiting protrusion 513 of the moving tool 510, regardless of the direction in which the moving tool 510 is moved. It is equipped so that it can be reached and fixed.

The fixed base 524 is fixedly installed at the lower part of the movement limiter 520, is disposed on the upper surface of the fixed plate 420, and may have a '∩' shape. In this way, the fixing base 524 is equipped to fix the movement restriction device 520 and can be coupled with screws, and has a detachable structure to facilitate replacement and installation of the movement restriction device 520.

The fixing unit 500 configured as described above moves the movement inducing part 430 of the earthquake-resistant unit 400 according to the direction of the earthquake to prevent vibration from being transmitted to the switchboard main body 100 and at the same time prevents the transfer of vibration to the switchboard main body 100 by the fixing unit 500. (100) can be prevented from conducting.

The earthquake-proof device 600 for a shelf is configured to prevent vibration from being transmitted to the shelf within the switchboard body 100. This seismic device for a shelf 600 is connected and arranged between the upper shelf and the lower shelf of the switchgear body 100, and is inserted into the earthquake-resistant main body 610, which is erected in the form of a cylinder, and the earthquake-resistant main body 610, and is installed on both sides. A seismic member 620 may be provided that protrudes and is made of an elastic material, with both ends connected to the upper shelf and the lower shelf, respectively.

Figure 11 is a block diagram of a control unit of an electric switchboard according to an embodiment of the present invention, and Figure 12 is a diagram showing a control sequence using a vibration detection sensor of an electric switchboard according to an embodiment of the present invention. And Figure 13 is a diagram showing a control sequence using a movement detection sensor of an electric switchboard according to an embodiment of the present invention.

Figure 14 is a diagram showing a control sequence using an impact detection sensor of an electric switchboard according to an embodiment of the present invention, and Figure 15 is a diagram showing a control sequence using a sensor unit of an electric switchboard according to an embodiment of the present invention.

Referring to Figures 11 to 15, the sensor unit 700 is mounted within the earthquake resistant unit 400 and is configured to measure state quantities. This sensor unit 700 may include a vibration detection sensor 710, a movement detection sensor 720, an impact detection sensor 730, etc. At this time, the vibration detection sensor 710 is installed in the earthquake-resistant unit 400 and can measure the frequency and detect changes in frequency due to vibration. And the movement detection sensor 720 is installed in the earthquake-resistant unit 400 and can measure the movement value of the movable plate 410. In addition, the impact detection sensor 730 is installed in the fixing unit 500 and can measure the impact value when the moving device 510 and the movement limiting device 520 collide.

The power supply unit 800 is configured to supply power to electric devices. The power supply unit 800 is equipped to supply power so that electric devices can be operated even in an emergency. This power supply unit 800 is a commonly used configuration, so detailed information will be omitted.

The manager terminal 900 is configured to receive an earthquake alarm signal or a replacement and inspection alarm signal and output it for the manager to check. When this manager terminal 900 receives an earthquake alarm signal or a replacement and inspection alarm signal, it can output an earthquake alarm message or a replacement and inspection alarm message through the terminal screen. In this way, the administrator terminal 900 is equipped to respond to emergency situations by outputting an alarm message so that the administrator can immediately recognize it.

The control unit 1000 is configured to control power supply to electric devices by comparing and determining the state quantity measured by the sensor unit 700 and the reference value. This control unit 1000 controls the power supply from the power supply unit 800 to the electric device to prevent secondary accidents when the state quantity measured by the sensor unit 700 exceeds the reference value.

As shown in FIG. 12, when the frequency measured by the vibration detection sensor 710 exceeds the reference frequency, the control unit 1000 cuts off the power supply from the power supply unit 800 and then sends an earthquake alarm message to the manager terminal 900. It is transmitted so that it is output. In contrast, the control unit 1000 may determine that an earthquake has not occurred if the frequency measured by the vibration detection sensor 710 is less than the reference frequency.

As shown in FIG. 13, when the movement value measured by the movement detection sensor 720 exceeds the reference movement value, the control unit 1000 cuts off the power supply from the power supply unit 800 and then sends an earthquake signal to the manager terminal 900. Sends an alarm message to be output. In contrast, the control unit 1000 may determine that an earthquake has not occurred if the movement value measured by the movement detection sensor 720 is less than the reference movement value.

As shown in FIG. 14, when the shock value measured by the shock detection sensor 730 exceeds the standard shock value, the control unit 1000 cuts off the power supply from the power supply unit 800 and sends an earthquake signal to the manager terminal 900. Sends an alarm message to be output. In contrast, the control unit 1000 may determine that an earthquake has not occurred if the shock value measured by the shock detection sensor 730 is less than the standard shock value.

As shown in FIG. 15, the control unit 1000 replaces and inspects the administrator terminal 900 if the measured frequency exceeds the standard frequency and one or more of the measured movement value and the measured impact value do not exceed the standard range. An alarm message can be output. In detail, the control unit 1000 can measure frequency, movement, and impact state quantity by the vibration detection sensor 710, movement detection sensor 720, and shock detection sensor 730.

And, if the measured frequency exceeds the reference frequency, the control unit 1000 can determine whether one or more of the measured movement value and impact value are outside the reference range. At this time, the control unit 1000 may transmit an earthquake alarm to the manager terminal 900 if one or more of the measured movement value and impact value is outside the standard range. Here, the control unit 1000 transmits an earthquake alarm to the manager terminal 900 so that the manager can recognize the occurrence of an earthquake and is equipped to quickly respond to it.

In addition, the control unit 1000 may transmit a replacement and inspection alarm to the manager terminal 900 if at least one of the measured movement value and impact value does not exceed the reference range. In this way, the control unit 1000 can determine the normal operating state of the seismic unit 400 and the fixed unit 500 when an earthquake occurs, and transmits a replacement and inspection alarm to the manager terminal 900 so that the manager can recognize it. can do.

A person skilled in the art to which the present invention pertains will understand that the present invention can be implemented in a modified form without departing from the essential characteristics of the present invention. Therefore, the disclosed embodiments should be considered from an illustrative rather than a restrictive perspective. The scope of the present invention is indicated in the claims rather than the foregoing description, and all differences within the equivalent scope should be construed as being included in the present invention.

100: Switchboard body
200: upper base
300: lower base
400: Earthquake-resistant unit
410: Movable plate
411: Multiple mounting holes
411a: groove of set shape
411b: fixed jaw
412: Mounting protrusion
420: Fixed plate
430: Movement guidance unit
431: Upper mounting hole
431-1: Fixing screw groove
431a: Insertion guidance surface
431b: Fixed elevation
431c: fixed seating surface
432: Idongji district
432a: wrinkle protrusion
432b: wrinkle groove
432c: fixing protrusion
432c': fixed groove
433: Movement guidance tool
433a: fixed groove
433a': fixing protrusion
440: Vibration damping unit
441: elastic body
442: magnetic material
443: connector
500: fixed unit
510: Moving area
511: moving space
512: Movement guide surface
513: Movement limitation protrusion
520: Movement restriction zone
521: Fixed body
522: moving protrusion
523: Movement restricted home
524: fixed base
600: Earthquake-proof device for shelves
610: Earthquake-resistant body
620: Earthquake-resistant member
700: Sensor unit
710: Vibration detection sensor
720: Movement detection sensor
730: Impact detection sensor
800: Power supply unit
900: Administrator terminal
1000: Control unit

Claims (5)

A switchboard body in which electrical devices are stored;
An upper base installed on the lower surface of the switchboard body;
a lower base spaced downward from the switchboard body and installed on the ground;
A plurality of movement guide parts disposed between the upper base and the lower base, arranged on the outside in a vertical wrinkled shape and having fixed upper ends, and disposed in the center of the plurality of movement guide parts and connecting the upper base and the lower base. A seismic unit equipped with a vibration damping unit to attenuate movement;
A sensor unit mounted within the earthquake-resistant unit and measuring a state quantity;
a control unit that controls power supply to the electric device by comparing and determining the state quantity measured by the sensor unit and a reference value;
A moving member disposed between the upper base and the lower base and installed on the inner edge of the switchboard body, mounted on the upper base and having a lower part recessed, and a movement that limits the movement of the moving member when inserted into the lower part of the moving member. Fixed unit equipped with a restrictor;
A power supply unit that supplies power to the electric device; and
It includes a manager terminal that receives an earthquake alarm signal from the control unit,
The sensor unit,
It includes a vibration detection sensor that measures the frequency within the seismic unit, a movement detection sensor that measures a movement value, and an impact detection sensor that measures the impact value of collision between a moving member and a movement limiting member in the fixed unit,
The control unit,
When the shock value measured by the shock detection sensor exceeds the standard shock value, power supply is cut off from the power supply unit and an earthquake alarm message is output to the manager terminal,
An electric switchboard with a modular earthquake-resistant structure that outputs a replacement and inspection alarm message to the manager terminal if the measured frequency exceeds the standard frequency and one or more of the measured movement value and measured impact value do not exceed the standard range. . delete According to paragraph 1,
The control unit,
An electric switchboard with a modular earthquake-resistant structure that cuts off power supply from the power supply unit when the frequency measured by the vibration detection sensor exceeds the reference frequency and outputs an earthquake alarm message to the manager terminal. According to paragraph 1,
The control unit,
An electric switchboard with a modular earthquake-resistant structure that cuts off power supply from the power supply unit when the movement value measured by the movement detection sensor exceeds the reference movement value and outputs an earthquake alarm message to the manager terminal. delete