KR101759489B1 - Switching board with power shut off system - Google Patents

Abstract

The present invention relates to a switchboard having an electric power cut-off system connected to an earthquake-based vibration sensor, in which the vibration intensity of a top sensing sensor and a bottom sensing sensor in a switchgear is measured and compared to determine a relatively large value of the vibration intensity, In order to ensure accident safety of the switchgear by generating corresponding signals sequentially according to the set value, it is possible to inform the user when to prepare for evacuation and when to evacuate. (10) installed on the ground surface (2) with electric power facilities installed therein so as to prevent a safety accident; A dustproof portion 20 installed between the lower surface of the switchboard 10 and the ground 2 to alleviate the vibration of the switchboard 10; An upper end detection sensor 31 is provided at the upper end of the inner side wall portion 12 of the switchboard 10 and a lower end portion of the lower end portion of the inner side wall portion 12, A vibration sensing part 30 provided with a sensing sensor 35 and sensing vibration of the upper sensing sensor 31 and the lower sensing sensor 35; The upper and lower sensing sensors 31 and 35 receive the vibration sensing values of the upper sensing sensor 31 and the lower sensing sensor 35 included in the vibration sensing unit 30, A determination unit (40) for determining a vibration strength of a relatively large value among the vibration strengths of the plurality of vibration members; When the vibration sensing unit 30 is driven and a comparatively large vibration intensity reaches a first reference setting value through the determination unit 40, a first alarm signal is generated, And a power supply line (55) connected to the power supply unit (52), and generates a second incoming power cutoff signal for the power input unit (51) when the vibration intensity reaches a second reference set value, When the vibration intensity reaches the fourth reference set value, a fourth power supply cutoff signal to the power supply unit 52 is generated to sequentially generate an alarm signal and an escape signal The upper and lower sensing sensors 31 and 35 are connected to the seating groove portion 12 formed in the side wall portion 12 of the switchgear 10, 17), and the seating groove A fitting recess portion 19 is formed in the inside of the fitting recess portion 17 and a fitting projection portion 31 formed at each end of the upper detection sensor 31 and the lower end detection sensor 35 facing the fitting recess portion 17 in the fitting recess portion 19, (37) is inserted.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a switching board with a power shut-

[0001] The present invention relates to a switchboard having a power cut-off system connected to an earthquake vibration sensor, and more particularly, to a system for measuring and comparing a vibration intensity of a top sensor and a bottom sensor inside a switchboard, It is possible to secure the accident safety of the power and control panel by generating corresponding signals successively in accordance with the reference set value of the vibration intensity and to inform the user of the evacuation preparation time and the evacuation time point, And a power interception system connected to an earthquake vibration sensor for preventing a safety accident.

In recent years, large and small earthquakes in many parts of the world have caused a lot of human and national damage, and this phenomenon has also occurred in Korea, which has been classified as a relatively safe zone. Therefore, there is a tendency to thoroughly prepare for this, to check the national disaster system and to strengthen the seismic design of buildings in order to minimize the damage in case of emergency.

However, existing buildings and old buildings are not reflected in earthquake-resistant design. Even if a small earthquake occurs instead of a great earthquake, it can cause great damage due to the collapse of the building, gas and leakage, Even if it is a building, it is a reality that the damage of an earthquake can not be completely avoided.

In addition, since the earthquake warning system of the Meteorological Agency's earthquake notification system, which is issued to prompt people to evacuate the building in case of an earthquake, is issued about 4 minutes after the earthquake, people inside the building are aware of the earthquake, There is no room to spare.

In addition, a large capacity electric power such as a factory or a building is basically equipped with a switchboard for receiving and converting high-voltage power supplied from KEPCO to low voltage, and a substation in which a switchboard is installed, It is difficult to quickly evacuate to the outside because the earthquake warning is issued after a certain period of time after the occurrence of the earthquake because the supervisors are located in a remote place such as a basement or a roof of a rare building.

In addition, the transmission and distribution panels should be constructed and installed in accordance with the earthquake-proofing guide such as the earthquake-resistant design and construction guidelines of the construction equipment, reflecting the earthquake-proof measures such as basic design, power facility arrangement, use of high- It is difficult to apply the effective seismic design method due to the structural change of the switchboard according to the customer and the difficulty of the verification of the seismic performance, especially due to the increase in the cost required for the application of the seismic design. The earthquake-resistant design is not applied to the switchboards in most buildings except for the same part, and earthquake damage occurs due to secondary damage such as stoppage of power supply function and fire due to movement and dropping of power equipment during earthquake. Lt; / RTI >

Such a switchboard is a device for receiving high-voltage or extra-high voltage electricity supplied from a power plant or substation and converting it to a voltage used in the customer and distributing it to the load facility. Such a switchboard is a cubicle structure called a cubicle on the surface, Power devices such as high-voltage switchgear, instrumental current transformers, high-voltage circuit breakers, transformers, and low-voltage distribution circuit breakers, and electrical components such as protective relays and instruments for power system protection and surveillance. Inside the cube clamp, a bus bar connecting the power devices to each other according to the power system, and wiring for measuring and monitoring the power device are arranged in addition to the power device.

If the earthquake-induced vibrations or shocks are generated due to earthquake, the electrical components such as the power equipment inside the switchgear, the wires connecting the power equipment to each other, and the protection relays are likely to be damaged or damaged, This may cause interruption of power supply and fire due to the fault that occurs. In addition, when an external vibration equal to or greater than a certain level, such as an earthquake, is generated, electric power should be shut off to prevent electric shock or fire.

Patent No. 10-1035647

SUMMARY OF THE INVENTION Accordingly, the present invention has been made in an effort to solve the above-mentioned problems, and it is an object of the present invention to provide a method and apparatus for measuring the vibration intensity of a top sensing sensor and a bottom sensing sensor, By generating appropriate signals successively, it is possible to secure the accident safety of the switchboard, and to inform the user when to prepare for evacuation and when to evacuate. This system has been completed as a technical problem with a focus on a power distribution system with an electric power cut-off system connected to an earthquake vibration sensor that can prevent the earthquake.

According to an aspect of the present invention, there is provided a power plant comprising: a power switchboard (10) installed on a surface (2) of a power plant; A dustproof portion 20 installed between the lower surface of the switchboard 10 and the ground 2 to alleviate the vibration of the switchboard 10; A plurality of top detection sensors 31 are provided at the upper end of the inner side wall portion 12 of the switchboard 10 and a lower end portion of the inner side wall portion 12 of the switchgear 10, A vibration detection unit 30 having a plurality of bottom detection sensors 35 corresponding to the top detection sensors 31 to detect vibrations of the top detection sensor 31 and the bottom detection sensor 35; The upper and lower sensing sensors 31 and 35 receive the vibration sensing values of the upper sensing sensor 31 and the lower sensing sensor 35 included in the vibration sensing unit 30, A determination unit (40) for determining a vibration strength of a relatively large value among the vibration strengths of the plurality of vibration members; When the vibration detection unit 30 and the determination unit 40 are driven and the vibration intensity of the relatively large value determined by the determination unit 40 reaches the first reference setting value, the primary alarm signal s1 And is connected to the power line 55 connected to the power input unit 51 and the power supply unit 52. When the vibration intensity reaches the secondary reference set value, the secondary cutoff power cutoff signal s2 and generates a tertiary evacuation signal s3 if the oscillation intensity reaches a tertiary reference setpoint and provides a third evacuation signal s3 when the oscillation intensity reaches a fourth reference setpoint, (S4) to generate an alarm signal and an evacuation signal sequentially to notify the user of the evacuation preparation time and the evacuation time, thereby securing the evacuation time in a sequential manner And to block power sequentially. The upper sensing sensor 31 and the lower sensing sensor 35 are inserted and seated in the seating recess 17 formed in the side wall 12 of the power switchboard 10, A fitting groove portion 19 is formed in the seating groove portion 17 so that the upper end detecting sensor 31 and the lower end detecting sensor 35 opposed to the seating groove portion 17 in the fitting groove portion 19 And a detachable type in which the formed projection portion (37) is fitted.

At this time, a plurality of servo detection sensors 39 are additionally provided on the straight line between the upper detection sensor 31 and the lower detection sensor 35 at equal intervals to secure a medium for determining a relatively large vibration intensity .

The upper sensing sensor 31, the lower sensing sensor 35 and the servo sensing sensor 39 may be used as any one of a three-axis sensing sensor, a MEMS sensor, a three-axis gyro sensor, a geomagnetic sensor, .

The present invention also relates to a power plant (10) installed on a ground surface (2) with electric power equipment installed therein; A dustproof portion 20 installed between the lower surface of the switchboard 10 and the ground 2 to alleviate the vibration of the switchboard 10; A plurality of top detection sensors 31 are provided at the upper end of the inner side wall portion 12 of the switchboard 10 and a lower end portion of the inner side wall portion 12 of the switchgear 10, A plurality of bottom sensing sensors 35 corresponding to the top sensing sensors 31 are provided to sense the vibrations of the top sensing sensor 31 and the bottom sensing sensor 35, A vibration detection section 30 in which the X, Y coordinate value provided with the lower detection sensor 35 is set to (0, 0); The vibration sensing value of each of the upper sensing sensor 31 and the lower sensing sensor 35 included in the vibration sensing unit 30 is received and measured and compared with the X and Y coordinate values, A determination unit (40) for determining X, Y displacement values of the X-axis displacement sensor (35); And drives the vibration sensing unit 30 and the determination unit 40 to generate a primary alarm signal s1 when the comparison value determined by the determination unit 40 reaches a first reference set value, Is connected to the power line 55 connected to the lead-in unit 51 and the power supply unit 52 and generates a secondary lead-in cutoff signal s2 for the power lead-in unit 51 when the displacement value reaches the secondary reference set value And generates a third evacuation signal s3 when the displacement value reaches a third reference set value and outputs a third evacuation signal s3 to the power supply unit 52 via the power line 55 if the displacement value reaches the fourth reference set value. And generates an alarm signal and an evacuation signal sequentially by generating a car supply cutoff signal s4 so that the user can be notified of the evacuation preparation time and the evacuation time so that the evacuation time can be secured in a sequential manner And a control unit 50 for sequentially interrupting power And the upper end sensor 31 and the lower end sensor 35 are inserted and seated in the seat recess 17 formed in the side wall 12 of the power transmission 10, The fitting groove portion 19 is formed and the fitting protrusion 37 formed at each end of the upper sensing sensor 31 and the lower sensing sensor 35 facing the seating groove portion 17 is inserted into the fitting groove portion 19 The present invention provides a switchboard having a power cut-off system associated with an earthquake vibration sensor, which is configured to be detachable.

At this time, the deformation angle [beta] of the upper detection sensor 31 is calculated based on the lower detection sensor 35 corresponding to a larger displacement value among the displacement values of X and Y through the X and Y displacement values, and the first reference set value to the fourth reference set value are set according to the degree of deformation of the first reference value?.

delete

Further, the fitting projection 37 and the fitting groove 19 are configured to be closely fixed by a magnetic force.

At least any one or more of the top sensing sensor 31 and the bottom sensing sensor 35 provided with the detachment detecting sensor 81 in the seating recess 17 may be driven by vibration of the earthquake or external shock When the sensor departure signal is generated, the controller 50 continues to determine the intensity of the vibration in the decision unit 40. When the sensor departure signal is generated, the controller 50 determines the first alarm signal s1, Are generated at the same time.

The downward inclined portion 91 is formed on the upper and lower surfaces of the seating groove portion 17 so that the entrance side thereof is inclined downward toward the ground surface 2 so that the upper end detection sensor 31 and / And the lower sensing sensor 35 is slid in and out of the seating groove 17 having the downward inclined portion 91. [

According to the present invention, it is possible to measure and compare the vibration intensity of the upper end sensor and the lower end sensor within the switchgear, to determine a relatively large value of the vibration strength, and sequentially generate corresponding signals according to the reference set value of the vibration intensity There is an effect that the accident safety of the switchboard can be secured.

In addition, since the sequential signal generation allows the user to be notified of the evacuation preparation time and the evacuation time, the safety can be prevented by ensuring that the evacuation time is secured in a sequential manner.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a diagram illustrating an installation configuration of a switchboard having a power shutdown system connected to an earthquake vibration sensor according to the present invention; FIG.
FIG. 2 is a diagram illustrating an example of a power cut-off system associated with a vibration detection sensor according to the present invention.
Figure 3 is a variant embodiment of Figure 1
FIG. 4 is a diagram illustrating another example of a configuration of a switchboard having a power shutdown system associated with an earthquake vibration sensor according to the present invention.
Figs. 5 and 6 are views showing a modification of the installation of the detection sensor according to the present invention

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

In the present invention, the vibration intensity of the upper sensing sensor and the lower sensing sensor in the interior of the switchgear is measured and compared, and a relatively large value of the vibration strength is determined, and corresponding signals are sequentially generated according to the reference setting value of the vibration intensity. It is possible to prevent the occurrence of a safety accident by ensuring the safety and ensuring that the evacuation time and evacuation time of the user are informed so that the evacuation time can be secured in a sequential manner. 1 to 6, the present invention includes a switchboard 10, a dustproof portion 20, a vibration detector 30, a determination portion 40, and a control portion 50.

The power plant is generally defined as including a high-voltage switchboard, a low-voltage switchboard, an electric motor control board, and a distribution board. The power plant installed in the switchboard 10 is a power- For example, a wiring breaker (MCCB), an air circuit breaker (ACB), a vacuum breaker (VCB), or the like, for controlling the electricity supplied to the interior of the switchboard 10. The power plant also has a terminal through which electricity is drawn or drawn, wherein the terminal is generally located at the rear of the power plant.

Between the lower surface of the switchboard 10 and the ground 2 is provided a dustproof portion 20 for absorbing and mitigating the vibration of the switchboard 10 when an earthquake occurs. As shown in FIG. 1, the dust-proofing unit 20 is mainly composed of an elastic spring or a vibration-proof pad, but may be any other structure capable of elastic operation.

The present invention is provided with the dustproof portion 20 to absorb and mitigate the vibration of the switchboard 10 when an earthquake or the like occurs as described above and to prevent the vibration of the switchboard 10 In order to secure the shake of the vehicle. That is, even if minute vibrations occur, the vibration of the transmission / reception section 10 due to the elasticity of the vibration preventing section 20 causes a larger vibration when the vibration preventing section 20 is absent, so that the vibration detecting rate of the vibration detecting section 30 .

In the present invention, as shown in FIG. 1, a plurality of top sensing sensors 31 are provided at the upper end of the inner side wall portion 12 of the switchboard 10, A plurality of lower end detecting sensors 35 corresponding to the upper end detecting sensors 31 are provided at the lower end of the inner side wall portion 12 of the sensor 31 on the straight vertical lower side, A vibration sensing part 30 for sensing the vibration of each of the lower sensing sensors 35 is provided and the vibrating sensing value of each of the upper sensing sensor 31 and the lower sensing sensor 35 included in the vibration sensing part 30 And a determination unit (40) for determining the vibration intensity of a relatively large value among the vibration intensities of the upper sensing sensor (31) and the lower sensing sensor (35).

3, the vibration sensing unit 30 is provided between the upper sensing sensor 31 and the lower sensing sensor 35 so as to further secure a medium in which the determination unit 40 determines a relatively large vibration intensity. A plurality of servo detection sensors 39 may be additionally provided at even intervals on a straight line.

The upper detection sensor 31, the lower detection sensor 35 and the servo detection sensor 39 constituting the vibration detection unit 30 are connected to a three-axis detection sensor or a low frequency (0.1 to 50 Hz (Micro electro mechanical systems) sensor capable of measuring the micro-vibrations due to the micro-vibrations. In the above description, the three-axis sensor can measure acceleration due to vibrations and vibrations not only in the vertical direction but also in the left-right direction and the back-and-forth direction. In addition to this, the three-axis gyro sensor, the geomagnetism sensor, Can be used.

The control unit 50 is connected to the vibration sensing unit 30 and the determination unit 40. 2, the control unit 50 drives the vibration sensing unit 30 and the determination unit 40 including the upper sensing sensor 31 and the lower sensing sensor 35, A first alarm signal s1 is generated when the vibration intensity of the relatively large value determined through comparison is equal to the first reference set value and the first alarm signal s2 is generated in the power line 55 connected to the power inlet portion 51 and the power supply portion 52 And generates a second incoming power cut-off signal s2 for the power inlet unit 51 when the oscillation intensity reaches the second reference set value, and when the oscillation strength reaches the third reference set value, the third evacuation signal s3 And generates a fourth-order supply cutoff signal s4 for the power supply unit 52 when the oscillation intensity reaches the fourth-order reference set value, and generates a corresponding appropriate signal according to the reference set value of the oscillation intensity, that is, Signal and evacuation signal in order to increase the accident safety of the switchboard. It is possible to inform users of the time of preparation and evacuation of evacuation, so that it is possible to prevent accidents by ensuring that the evacuation time is secured and sequential actions are taken.

At this time, the primary alarm signal s1 to the fourth power supply shutoff signal s4 may generate a signal through an alarm sound, an alarm, or a manager's smartphone or a manager PC.

In the present invention, a modified mercury intensity scale (MMI scale) is applied to the first to fourth reference set values. The modified Mercuriality degree class is made up of 12 grades in detail and is reset and applied to the first to fourth reference set values of the present invention. The above grades can be classified as shown in [Table 1] according to the magnitude of earthquake damage. In recent years, including Korea, Japan and other countries are using the modified Mercado Jindo class to predict the intensity and damage of the earthquake. Here, progress is generally expressed as an integer in Roman numeral.

magnitude The reference setting value situation One Primary standard
Setting value
Very small vibration, very few in special conditions 2 Very few feel indoors 3 Second standard
Setting value
Faint feeling inside, suspended objects moving weakly 4 Many feel indoors, not outdoors 5 Tertiary standard
Setting value
The entire building may be shaken, the object may be damaged, flipped, the object may fall, 6 Difficulty walking straight, falling or cracking of weak building walls, heavy objects moving or reversing 7 Fourth Standard
Setting value




Difficult to stand, felt an earthquake while driving, crumbling wall collapsed, loose load and fence collapsed 8 Difficulty driving a car, collapse of some buildings, slope or surface cracks, towers, chimney collapse 9 Damage to or damage to a solid building, cracks in the surface, and damage to underground pipes 10 Most rugged buildings and structures destroyed, surface cracks, massive landslides, asphalt cracks 11 The railway is severely bent, the structure is almost destroyed, and the underground pipe can not be operated 12 The ground moves in the form of a wave, and the object jumps into the air.

On the other hand, as another embodiment of the present invention, a configuration of the vibration detection unit 30, the determination unit 40, and the control unit 50 is modified. In this case, the construction of the switchboard 10 and the dust-proofing unit 20 are the same as those described above, and a description thereof will be omitted.

The vibration detection unit 30 of the present invention shown in FIG. 4 is provided with a plurality of upper detection sensors 31 at the upper end of the inner side wall 12 of the switchboard 10, And a plurality of lower end detecting sensors 35 corresponding to the upper end detecting sensors 31 at the lower end of the inner side wall portion 12 on the vertical straight lower side of the switchboard 10, The X and Y coordinate values of the upper sensing sensor 31 and the lower sensing sensor 35 are set to (0, 0) while the vibration of each of the sensing sensors 35 is detected. Setting the X and Y coordinate values to (0, 0) as described above is intended to compare and measure the X and Y displacement values described later.

The determination unit 40 receives the vibration sensing values of the upper sensing sensor 31 and the lower sensing sensor 35 included in the vibration sensing unit 30 constructed as described above. When vibration due to the earthquake occurs, X, Y The X and Y displacement values of the upper sensing sensor 31 and the lower sensing sensor 35 are respectively measured and compared. The X and Y displacement values of the upper sensing sensor 31 and the lower sensing sensor 35 should be compared with each other when the upper sensing sensor 31 and the lower sensing sensor 35 are arranged in a straight line in the vertical downward direction, And the Y displacement value, it is preferable to select a value having a large difference between the displacement values.

The control unit 50 connected to the determination unit 40 drives the vibration sensing unit 30 and the determination unit 40 to determine whether the displacement value determined by the determination unit 40 is a primary reference The primary alarm signal s1 is generated and connected to the power line 55 connected to the power input unit 51 and the power supply unit 52. When the displacement value reaches the secondary reference set value, 51), and generates a third evacuation signal (s3) when the displacement value reaches a third reference set value, and when the displacement value reaches a fourth reference set value The fourth power supply cutoff signal s4 to the power supply unit 52 through the power line 55 so as to sequentially generate the alarm signal and the escape signal.

In this case, the displacement value corresponding to the first reference set value is 1 to 10 mm, the displacement value corresponding to the second reference set value is 11 to 25 mm, and the displacement value corresponding to the third reference set value is 26 to 45 Mm, and the displacement value corresponding to the fourth reference set value is set to 46 mm or more, and the condition for each reference set value is the same as in Table 1 above.

As another embodiment of the present invention, the deformation angle (X, Y) of the upper sensing sensor 31 may be determined based on the lower sensing sensor 35 corresponding to a larger displacement value among the displacement values of X, beta] and calculate the first to fourth reference set values according to the degree of deformation of the deformation angle [beta].

In this case, the deformation angle (β) corresponding to the first reference setting value is 0.1 to 0.5 °, the deformation angle (β) corresponding to the second reference setting value is 0.6 to 1.5 °, The deformation angle (β) is 1.6 to 3.0 °, and the deformation angle (β) corresponding to the fourth-order reference setting value is set to 3.0 ° or more, and the condition for each reference setting value is the same as in Table 1 Do.

The top sensing sensor 31 and the bottom sensing sensor 35 may be mounted on the side wall 12 of the switchgear 10 as an embodiment of the installation structure of the upper sensing sensor 31 and the lower sensing sensor 35. [ The top sensing sensor 31 and the bottom sensing sensor 35 may be coupled to the seating groove 17 formed in the side wall 12 of the power switchboard 10 as shown in FIG. And an upper end detection sensor 31 and a lower end end detection sensor 35 which face the seating recess 17 in the fitting recess 19 by forming a fitting recess 19 in the seating recess 17, It is possible to constitute a detachable type in which the fitting projections 37 formed at the respective end portions are fitted.

The detachable structure facilitates detachment of the upper and lower sensing sensors 31 and 35. In addition, when a plurality of seating grooves 17 are formed on the side wall 12 in advance in the fabrication of the switchboard 10 Installation is easy wherever the user wants.

The fitting projection 37 and the fitting groove 19 are formed in a manner that a magnetic force (magnetic force) is applied to the fitting projection 37 and the fitting groove 19 of the upper sensing sensor 31 and the lower sensing sensor 35, As shown in Fig. At this time, an electromagnet may be used according to the required structure.

4, at least one of the top sensing sensor 31 and the bottom sensing sensor 35, which is provided with the detachment detecting sensor 81 in the seating groove 17, It is possible to generate a sensor departure signal when the object is separated from the side wall portion 12 by vibration or external impact of an earthquake. At this time, the determination of the strength of vibration in the determination unit 40 is continuously performed. Even if the first alarm signal s1 is not generated by the controller 50 when the sensor deviation signal is generated, It is preferable that the primary alarm signal s1 is simultaneously generated by the control unit 50 in order to prevent a safety accident.

5, a downward inclined portion 91 is formed on the upper and lower surfaces so that the entrance side of the seat groove 17 is inclined downward toward the ground 2, The upper end detecting sensor 31 and the lower end detecting sensor 35 can be configured to be slid in and out of the seating recess 17 having the downward inclined portion 91. [ This is for the purpose of quickly and easily releasing the upper detection sensor 31 and the lower detection sensor 35 when vibration or external shock occurs due to an earthquake.

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 embodiments, but, on the contrary, Should be clarified. Therefore, it is intended that the present invention cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.

2: Ground 10: Switchboard
20: vibration preventing portion 30: vibration detecting portion
31: upper detection sensor 35: lower detection sensor
40: Judgment section 50:
51: power input unit 52: power supply unit
55: Power line

Claims (9)

A switchboard (10) installed on a surface (2) of a power plant; A dustproof portion 20 installed between the lower surface of the switchboard 10 and the ground 2 to alleviate the vibration of the switchboard 10; A plurality of top detection sensors 31 are provided at the upper end of the inner side wall portion 12 of the switchboard 10 and a lower end portion of the inner side wall portion 12 of the switchgear 10, A vibration detection unit 30 having a plurality of bottom detection sensors 35 corresponding to the top detection sensors 31 to detect vibrations of the top detection sensor 31 and the bottom detection sensor 35; The upper and lower sensing sensors 31 and 35 receive the vibration sensing values of the upper sensing sensor 31 and the lower sensing sensor 35 included in the vibration sensing unit 30, A determination unit (40) for determining a vibration strength of a relatively large value among the vibration strengths of the plurality of vibration members; When the vibration detection unit 30 and the determination unit 40 are driven and the vibration intensity of the relatively large value determined by the determination unit 40 reaches the first reference setting value, the primary alarm signal s1 And is connected to the power line 55 connected to the power input unit 51 and the power supply unit 52. When the vibration intensity reaches the secondary reference set value, the secondary cutoff power cutoff signal s2 and generates a tertiary evacuation signal s3 if the oscillation intensity reaches a tertiary reference setpoint and provides a third evacuation signal s3 when the oscillation intensity reaches a fourth reference setpoint, (S4) to generate an alarm signal and an evacuation signal sequentially to notify the user of the evacuation preparation time and the evacuation time, thereby securing the evacuation time in a sequential manner And to block power sequentially. It is made, including,; the controller 50 to register
The upper sensing sensor 31 and the lower sensing sensor 35 are inserted and seated in the seating groove 17 formed in the side wall 12 of the switchgear 10 and are fitted into the fitting groove 19 And a fitting protrusion 37 formed at each end of the upper sensing sensor 31 and the lower sensing sensor 35 facing the seating recess 17 is inserted into the fitting recess 19, And a power interception system associated with the earthquake vibration sensor.
The method according to claim 1,
A plurality of servo detection sensors 39 are additionally provided at regular intervals on a straight line between the upper detection sensor 31 and the lower detection sensor 35 to further secure a medium for determining a relatively large vibration intensity And a power interception system associated with the earthquake vibration sensor.
3. The method of claim 2,
The upper sensing sensor 31, the lower sensing sensor 35 and the servo sensing sensor 39 are used as any one of a three-axis sensing sensor, a MEMS sensor, a three-axis gyro sensor, a geomagnetic sensor, A power distribution system with a power shutdown system associated with an earthquake vibration sensor.
A switchboard (10) installed on a surface (2) of a power plant; A dustproof portion 20 installed between the lower surface of the switchboard 10 and the ground 2 to alleviate the vibration of the switchboard 10; A plurality of top detection sensors 31 are provided at the upper end of the inner side wall portion 12 of the switchboard 10 and a lower end portion of the inner side wall portion 12 of the switchgear 10, A plurality of bottom sensing sensors 35 corresponding to the top sensing sensors 31 are provided to sense the vibrations of the top sensing sensor 31 and the bottom sensing sensor 35, A vibration detection section 30 in which the X, Y coordinate value provided with the lower detection sensor 35 is set to (0, 0); The vibration sensing value of each of the upper sensing sensor 31 and the lower sensing sensor 35 included in the vibration sensing unit 30 is received and measured and compared with the X and Y coordinate values, A determination unit (40) for determining X, Y displacement values of the X-axis displacement sensor (35); And drives the vibration sensing unit 30 and the determination unit 40 to generate a primary alarm signal s1 when the comparison value determined by the determination unit 40 reaches a first reference set value, Is connected to the power line 55 connected to the lead-in unit 51 and the power supply unit 52 and generates a secondary lead-in cutoff signal s2 for the power lead-in unit 51 when the displacement value reaches the secondary reference set value And generates a third evacuation signal s3 when the displacement value reaches a third reference set value and outputs a third evacuation signal s3 to the power supply unit 52 via the power line 55 if the displacement value reaches the fourth reference set value. And generates an alarm signal and an evacuation signal sequentially by generating a car supply cutoff signal s4 so that the user can be notified of the evacuation preparation time and the evacuation time so that the evacuation time can be secured in a sequential manner And a control unit 50 for sequentially interrupting power Made over,
The upper sensing sensor 31 and the lower sensing sensor 35 are inserted and seated in the seating groove 17 formed in the side wall 12 of the switchgear 10 and are fitted into the fitting groove 19 And a fitting protrusion 37 formed at each end of the upper sensing sensor 31 and the lower sensing sensor 35 facing the seating recess 17 is inserted into the fitting recess 19, And a power interception system associated with the earthquake vibration sensor.
5. The method of claim 4,
The deformation angle β of the upper sensing sensor 31 is calculated on the basis of the lower sensing sensor 35 corresponding to a larger displacement value among the displacement values of X and Y through the X and Y displacement values, And the fourth reference set value is set in accordance with the degree of deformation of the first and second reference set values.
delete The method according to claim 1 or 4,
Characterized in that the fitting projection (37) and the fitting groove (19) are closely fixed by a magnetic force.
The method according to claim 1 or 4,
At least any one or more sensors of the top sensing sensor 31 and the bottom sensing sensor 35 provided in the seating groove portion 17 with a plurality of detachment sensors 81 are installed in the side wall portion The sensor output signal is generated and the determination of the strength of vibration in the determination unit 40 is continuously performed. When the sensor departure signal is generated, the controller 50 simultaneously outputs the primary alarm signal s1 And a power interception system associated with the earthquake vibration sensor.
9. The method of claim 8,
The downward inclined portion 91 is formed on the upper and lower surfaces of the seating groove portion 17 so that the entrance side thereof is inclined downward toward the ground surface 2. The upper and lower sensing sensors 31 and 32 Characterized in that the sensor (35) is configured to be slidably disengaged in a seat recess (17) having a downwardly inclined portion (91).

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