KR102332531B1 - The vibration detection and control device of the Enclosure - Google Patents

Abstract

The present invention relates to a vibration detection and control device for an enclosure such as a distribution board, a motor control center, a panel board and the like and, more specifically, to a vibration detection and control device for an enclosure configured to detect whether an earthquake occurs, identify an earthquake magnitude when the earthquake occurs, and display and warn of information on the identified earthquake magnitude outside.

Description

The vibration detection and control device of the Enclosure

The present invention relates to a vibration sensing and control device of a housing such as a switchboard, an electric motor control panel, a distribution panel, an automatic control panel, a measuring instrument control panel, and a solar connection panel. More specifically, it relates to a vibration detection and control device of the enclosure configured to detect the presence or absence of an earthquake to determine the magnitude of an earthquake when an earthquake occurs, and to display and warn the outside of information about the detected earthquake magnitude.

In general, housings such as switchboards, distribution boards, and motor control panels, automatic control panels, instrument control panels, and photovoltaic connection panels are devices that must be stably protected against disasters caused by earthquakes or typhoons.

Various power-related parts such as insulators, electric power devices, circuit breakers, etc. are included in the inside of the enclosure, including a bus-bar for transmitting power. When vibration is applied to the enclosure due to an earthquake, etc. As it is generated by torsional stress, internal components are affected.

In more detail, the shape of the enclosure such as the existing switchgear is a closed enclosure with an iron frame assembled in a rectangular parallelepiped shape and then made of a painted steel plate and a door on the front, rear or front of the enclosure, The housing is fixed to the ground in order to prevent overturning and overturning, and this external structure is twisted or distorted when external force or vibration, such as an earthquake, is applied, resulting in a high risk of an accident.

Since earthquake damage occurs in a very short period of time, it is not easy to reduce the damage through evacuation, etc.

Therefore, research on seismic sensors that can be installed in housings such as switchboards are continuously being conducted so that earthquakes can be recognized immediately and damage can be minimized. There is a type earthquake detector.

As shown in (a) of FIG. 1, in the prior art earthquake detector, a hole 14 having a constant gradient g toward the bottom is formed in the central portion, and the first conductor ( 18) is attached to the supporting disk (4) of the insulator; a metal ball 12 inserted into the hole of the support disk 4; and a cylindrical cover (2) in close contact with the end of the support disk (4) and having a second conductor (20) attached to the lower end along the circumference, and an electric wire (16) to the pair of conductors (18, 20). It consists of these interconnected components. The wire 16 is connected to an alarm circuit.

Therefore, when the metal sphere 12 is separated out of the hole 14 by the vibration force of the earthquake as in FIG. It is positioned across the first and second conductors 18 and 20 to make an electrical connection, and this electrical connection is configured so that a warning sound is sounded by the alarm device of the alarm generating circuit.

In this prior art earthquake detector, the method of controlling the degree of vibration of the alarm target is to change the gradient (g) of the hole 14 formed in the central part of the support disk 4, so that the metal sphere 12 is more easily separated The earthquake intensity is controlled by making it so that it is made or more difficult to escape, and when the metal sphere 12 is separated out of the hole 14 by the vibration force of the earthquake, it is an alarm method.

Therefore, such an earthquake detector cannot know what the magnitude of the current earthquake is, and only when the metal sphere 12 departs from the gradient of the seismic designed hole 14, an alarm sound is generated. There is a problem in that it is impossible to provide a customized warning according to the intensity of an earthquake of an actual magnitude.

Patent Document 1: Publication No. Room 1996-029506 (published on September 17, 1996) Patent Document 2: Registration No. 10-2039589 (Announcement Date: 2019.11.01) Patent Document 3: Registration No. 10-2150899 (Announcement Date: 2020.09.02)

In order to solve the above problems, the present invention is installed inside or outside a housing such as a switchboard, a motor control panel, and a distribution board when an earthquake occurs, and detects the presence or absence of an earthquake and determines the magnitude of the earthquake that has occurred at the same time, The purpose of the present invention is to provide a vibration detection and control device of the enclosure configured to display information about the scale externally and to give appropriate warnings and actions.

In order to achieve the above object, the present invention relates to a vibration sensing and control device of a housing such as a switchboard, an electric motor control panel, a distribution panel, an automatic control panel, a measuring instrument control panel, and a solar connection panel. a vibration sensing unit including a contact unit electrically connected to the conductor pair when the metal sphere moving according to the vibration of the housing in the curved frame arranged in the conductor pair is located on the conductor pair; a connector electrically connected to the contact portion and configured to be energized to generate a sensing signal when the contact portion is electrically connected to the conductor pair; and a controller electrically connected to the connector, receiving a sensing signal transmitted from the connector, determining the earthquake magnitude, and generating a control signal according to the determined earthquake magnitude to perform a control operation through the connector; including It provides a vibration sensing and control device of the enclosure, characterized in that configured.

The vibration sensing unit may include: a frame configured to have a curved inner surface, and a plurality of conductor pairs having an insulator interposed therebetween are arranged at regular intervals on the inner surface; a metal ball located in the frame and moving along the inner surface of the frame according to the vibration of the housing; and a contact portion electrically connected to the conductor pair when the metal ball is positioned on the conductor pair of the frame.

A plurality of contact pairs are configured in the contact portion, and each contact pair is configured to match a pair of conductors arranged in the frame, respectively.

The connector includes: a sensing terminal part electrically connected to the contact pair of the contact part and conducting electricity with the contact pair of the contact part when the contact part is electrically connected to the conductor pair; a communication module unit connected to the sensing terminal unit and generating a sensing signal while the sensing terminal unit is energized; and a control terminal unit for receiving the control signal generated by the controller.

The communication module unit includes a time delay element for transmitting the detected signal by delaying the time.

In addition, the controller may include: an earthquake magnitude determination unit electrically connected to the connector and configured to receive a sensing signal transmitted from the connector to determine an earthquake magnitude; an earthquake magnitude display unit for displaying the earthquake magnitude determined by the earthquake magnitude determination unit with a display lamp unit and a voice alarm unit; an operation command unit for generating a control signal for controlling the circuit breaker in the enclosure according to the earthquake magnitude determined by the earthquake magnitude determination unit and a status signal for the earthquake magnitude determined by the earthquake magnitude determination unit; and a communication unit for transmitting the status signal generated by the operation command unit to a remote monitoring and control panel.

The following effects can be achieved through the vibration sensing and control device of the present inventor's enclosure.

As the vibration detection and control device of the present invention is installed in a housing such as a switchboard, a motor control panel, a distribution panel, an automatic control panel, a measuring instrument control panel, and a solar panel, it is possible to grasp the magnitude of the earthquake as well as the presence or absence of an earthquake at the time of an earthquake. It has the effect of displaying information on the magnitude of an earthquake to the outside and giving appropriate warnings and actions according to the detected earthquake magnitude.

1 shows a seismic sensor according to the prior art.
Figure 2 is an installation state diagram of the vibration detection and control device installed in the housing according to the present invention.
3 is a block diagram of an earthquake sensing unit according to the present invention.
4 is an operation state diagram of the vibration sensing and control device installed in the housing according to the present invention.
5 is an operation flowchart of the vibration sensing and control device according to the present invention.
6 shows a front display lamp unit and a voice alarm unit of the controller according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings for the vibration sensing and control device of the enclosure.

The present invention is installed in a housing such as a switchgear, a motor control panel, a distribution board, and detects the presence or absence of an earthquake through a controller to determine the magnitude of the earthquake, and displays and warns information on the detected earthquake magnitude to the outside. It relates to sensing and control devices.

Figure 2 is an installation state diagram of the vibration detection and control device installed in the housing according to the present invention. 3 is a block diagram of an earthquake sensing unit according to the present invention. 4 is an operation state diagram of the vibration sensing and control device installed in the housing according to the present invention.

As shown, the vibration sensing and control device 10 of the present invention is largely configured to include a vibration sensing unit 100 , a connector 200 , and a controller 300 .

The vibration sensing and control device 10 of the present invention may be installed in a housing 20 such as a switchboard, a motor control panel, a distribution panel, an automatic control panel, a measuring instrument control panel, and a solar connection panel.

Referring to FIG. 2 , the vibration sensing and control device 10 is installed on the bottom surface of the housing 20 . As shown, the vibration sensing and control device 10 is illustrated to be installed on the inner bottom surface of the housing 20 , but may be separately installed outside the housing 20 .

Referring to FIG. 3 , the configuration of the vibration sensing unit 100 of the present invention is shown. In the vibration sensing unit 100, a plurality of conductor pairs arranged at regular intervals are arranged on the inner surface of the curved frame 110. is composed

In other words, in the frame 110 , a pair of circular-shaped conductors (conductor 1, conductor 2) and an insulator between the pair of conductors form a conductor pair.

In addition, a plurality of conductor pairs (conductor pair normal, conductor pair n, conductor pair n+1, conductor pair n+2) are arranged in the frame 110 at regular intervals, and conductors arranged on the curved surface of the frame 110 . The pair may consist of four pairs of conductors. Of course, the number of the conductor pairs can be changed freely from the standpoint of a person skilled in the art.

In addition, the vibration sensing unit 100 is configured with a metal sphere 120 that moves according to the vibration of the housing 20 . The metal sphere 120 is located on the inner surface of the curved frame 110, and is configured to move freely in up, down, left, and right directions along the inner surface of the frame 110 according to the vibration of the housing.

In other words, referring to FIG. 4 , the metal sphere 120 is located in the conductor pair (conductor pair_normal position) in a normal state where there is no vibration or vibration is weak because no earthquake occurs.

When the metal sphere 120 is in the conductor pair (the top of the conductor pair), it is configured to have a size that can be in contact with all the conductors constituting the conductor pair (top of the conductor pair).

Similarly, even when the metal sphere 120 moves in a conductor pair (conductor pair n, conductor pair n+1, conductor pair n+2), the moving metal sphere 120 is an individual conductor pair (conductor pair n, conductor pair). Each of the conductors constituting the pair n+1 and the conductor pair n+2) can all be in contact.

In addition, in the vibration sensing unit 100, the metal sphere 120 is any one of a plurality of conductor pairs (conductor pair normal, conductor pair n, conductor pair n+1, conductor pair n+2) of the frame 110 . When located in the conductor pair (conductor pair normal, conductor pair n, conductor pair n+1, conductor pair n+2), the contact part 130 electrically connected to the conductor pair is configured.

A plurality of contact pairs 130a are configured in the contact portion 130, and each contact pair 130a is configured to match a conductor pair arranged in the frame 110, respectively, and each contact pair 130a The location of the earthquake means the location according to the magnitude of the earthquake, and it means the normal location from the center to the outskirts, the location of magnitude n, magnitude n+1, and magnitude n+2.

In the present invention, the vibration sensing unit 100 is electrically connected to and interlocked with the contact unit 130 , and when the contact unit 130 is electrically connected to the conductor pair of the frame 100 , electricity is sensed. A connector 200 for generating a signal is configured.

In other words, the connector 200 is electrically connected to the contact unit 1300 , and when the metal sphere 120 is positioned on a conductor pair of the frame 110 , the contact unit 130 is a conductor of the frame 100 . While being electrically connected to the pair, the connector 200 is energized to generate a sensing signal.

In more detail, as the metal sphere 120 moving the frame 110 moves any one of the arranged conductor pairs (conductor pair n, conductor pair n+1, conductor pair n+2), the metal The conductor pair through which the sphere 120 moves and the contact pair 130a of the contact unit 130 matching the conductor pair are electrically connected by the metal sphere 120 .

That is, any one of the contact pair 130a of the contact unit 130 is electrically connected to any one conductor pair by the metal sphere 120, and the connector 200 is energized to generate a detection signal. am.

In other words, the connector 200 includes a sensing terminal portion 210a electrically connected to the contact pair of the contact portion, and is formed as many as the number of contact pairs 130a of the contact portion 130 , Wires are connected so as to match each of the contact pairs 130a.

When the metal sphere 120 moves any one of the conductor pairs arranged on the frame 110 , the contact pair 130a of the contact unit 130 is electrically connected to the corresponding conductor pair, and the The corresponding sensing terminal unit 210a electrically connected to the contact pair 130a is configured to be energized.

The terminal unit 210 configured in the connector 200 includes a sensing terminal unit 210a, a control terminal unit 210b for receiving a control signal generated from the controller 300, and a status signal generated from the controller 300 A state terminal unit 210c for receiving and a power terminal unit 210d for supplying power to the controller 300 are configured.

In addition, the connector 200 includes a communication module unit 220 connected to the sensing terminal unit 210a and generating a sensing signal while the sensing terminal unit 210a is energized.

The communication module unit 220 includes a communication module 220a for generating a detection signal and a time delay element 220b for transmitting the detection signal generated by the communication module 220a with a time delay.

In addition, the controller 300 configured in the present invention is electrically connected to the connector 200, receives a detection signal transmitted from the connector 200, determines the earthquake magnitude, and transmits a control signal according to the determined earthquake magnitude. generated to perform a control operation through the connector 200 .

When vibration occurs due to an earthquake, the metal sphere 120 is guided along the curved surface of the frame 110 and moves as much as the magnitude of the earthquake in the forward, backward, left, and right directions of any one of the conductor pairs arranged in plurality in the frame 110 . Conductor 1 and Conductor 2 constituted for each pair of conductors are instantaneously connected to close conductor 1 and conductor 2, and then they move to another place. Therefore, the time delay element 220b is configured in the communication module unit 220 so that the controller 300 can recognize the short time that the conductor 1 and the conductor 2 are closed by an appropriate time delay.

In the controller 300 of the present invention, an earthquake magnitude determination unit 310 that is electrically connected to the connector 200 and receives a sensing signal transmitted from the connector 200 to determine an earthquake magnitude is configured.

In addition, the earthquake magnitude display unit 320 is configured to display the earthquake magnitude determined by the earthquake magnitude determination unit 310 by a display lamp unit and a voice alarm unit configured on the front of the controller.

In addition, the controller 300 includes an operation command unit 330 that generates a control signal for controlling the circuit breaker in the housing 20 according to the earthquake magnitude determined by the earthquake magnitude determination unit 310 .

The control signal generated by the operation command unit 330 opens the circuit breaker in the housing through the control terminal 210b of the connector 200 .

In addition, the operation command unit 330 generates a status signal for the earthquake magnitude determined by the earthquake magnitude determination unit 310, and the controller 300 transmits the status signal generated from the operation command unit to the remote monitoring and control panel. The communication unit 350 for transmitting to is configured.

In addition, the power supply unit 350 for receiving power supplied to the controller 300 through the power terminal unit 210d of the connector is configured.

5 shows a front display lamp unit and a voice alarm unit of the controller according to the present invention.

As shown, a display lamp unit and a voice alarm unit are configured in the front part of the controller 300, and the LED lamp for displaying the earthquake magnitude in the display lamp unit is 4 types including normal, scale n, scale n+1, and scale n+2. is provided

When a detection signal is input to the controller 300 as a specific conductor pair is closed among the conductor pairs arranged in the frame 110 as the metal sphere 120 moves as the metal sphere 120 moves due to the vibration generated by the earthquake, the earthquake magnitude display unit 320 displays the corresponding size Turn on the LED Lamp and maintain that state. For example, when an earthquake of magnitude n+2 occurs, the LED lamp corresponding to magnitude n, magnitude n+1, and magnitude n+2 is turned on, and the status is communicated by the communication unit 350 to the remote monitoring and control panel. is sent to

In addition, after the earthquake is finished, the metal sphere 120 reaches the "conductor pair_normal" position among the conductor pairs of the frame 110, and the "conductor pair_normal" is closed by the metal sphere, and the earthquake magnitude display unit 320 to turn on the normal lamp.

Hereinafter, a detailed operation flow of the present invention will be described.

6 is an operation flowchart of the vibration sensing and control device according to the present invention. Referring to the figure, the metal sphere 120 is located on the curved surface of the frame 110, and in a normal state in which an earthquake does not occur, the metal sphere 120 is " It is located in the “conductor pair_normal” position, and in this case, the conductor 1 and conductor 2 constituting the “conductor pair_normal” are closed by the metal sphere 120, and the detection signal is transmitted to the controller ( 300) is sent.

In this case, when the earthquake magnitude is determined by the earthquake magnitude determination unit 310 of the controller 300, the earthquake magnitude display unit 320 causes only the normal display LED lamp to be turned on in the display lamp part configured on the front side of the controller, LED lamps corresponding to scale n, scale n+1, and scale n+2 should be turned off, and the voice alarm should not be operated.

Next, when vibrations caused by earthquakes occur, the metal sphere 120 opens the conductors 1 and 2 of “conductor pair_normal” while leaving the conductor pair at the “conductor pair_normal” position, and the corresponding detection A signal is generated by the connector 200 and transmitted to the controller 300 .

In this case, the earthquake magnitude determination unit 310 of the controller 300 determines which contact pair 130a is connected to the sensing terminal unit 210a connected to the sensing signal generated, and the position of the metal sphere 120 is which conductor It is determined whether the pair (conductor pair normal, conductor pair n, conductor pair n+1, conductor pair n+2) has moved.

As shown, in the earthquake magnitude determination unit 310, the position of the metal sphere 120 is determined by determining which position is among the conductor pair n, the conductor pair n+1, and the conductor pair n+2, and the metal When the position of the sphere 120 is the conductor pair n, the earthquake magnitude display unit 320 turns off the normal indication LED lamp, turns on the LED lamp corresponding to the magnitude n in the display lamp unit, and issues a voice warning through the voice alarm unit. The operation command unit 320 generates a status signal and transmits the status signal generated from the communication unit 340 to the monitoring control panel through the status terminal 210c of the connector 200 .

In addition, when the position of the metal sphere 120 is the conductor pair n+1, the controller 300 causes the earthquake magnitude display unit 320 to turn on the LED lamp corresponding to the magnitude n+1 in the display lamp unit, and the voice alarm unit The occupant evacuation broadcast is performed through the occupant evacuation broadcast, and the operation command unit 320 transmits the status to the monitoring and control panel through the communication unit 340 .

In addition, when the position of the metal sphere 120 is the conductor pair n + 2, the controller 300 causes the earthquake magnitude display unit 320 to turn on the LED lamp corresponding to the scale n + 2 in the display lamp unit, and the voice alarm unit to broadcast the main breaker opening and voice warning through In this case, the operation command unit 320 generates a control signal to open the circuit breaker inside the housing through the control terminal 210b of the connector 200, and generates a status signal to the connector 200 through the communication unit 340 ) to transmit the status to the monitoring control panel using the status terminal 210c.

Next, when the earthquake magnitude is determined by the earthquake magnitude determination unit 310 in the controller 300, the position of the metal sphere 120 is in the "conductor pair_normal" position again among the conductor pairs arranged in the frame 110 When it is determined, the earthquake magnitude display unit 320 again causes only the normal indication LED lamp to be turned on in the display lamp unit configured on the front part of the controller, and the LED lamps corresponding to the scale n, scale n+1, and scale n+2 are Turn off the lights and make sure that the voice alarm does not work.

Although preferred embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements by those skilled in the art using the basic concept of the present invention as defined in the following claims are also provided. is within the scope of the

10: vibration detection and control device 20: enclosure
100: vibration sensing unit 110: frame
120: metal sphere 130: contact part
130a: contact pair
200: connector 210: terminal part
210a: sensing terminal unit 210b: control terminal unit
210c: status terminal unit 210d: power terminal unit
220: communication module unit 220a: communication module
220b: time delay element
300: controller 310: earthquake magnitude determination unit
320: earthquake magnitude display unit 330: operation command unit
340: communication unit 350: power unit

Claims (6)

In the vibration sensing and control device of a housing such as a switchboard, a motor control panel, a distribution panel, an automatic control panel, a measuring instrument control panel, and a solar connection panel,
In a curved frame in which a plurality of conductor pairs arranged at regular intervals are arranged on the inner surface, a sense of vibration including a contact part electrically connecting to the conductor pair when a metal sphere moving according to the vibration of the housing is located on the conductor pair chapter;
a connector electrically connected to the contact portion and configured to be energized to generate a sensing signal when the contact portion is electrically connected to the conductor pair; and
A controller electrically connected to the connector, receiving a sensing signal transmitted from the connector, determining an earthquake magnitude, and generating a control signal according to the determined earthquake magnitude to perform a control operation through the connector; and becomes,
The vibration sensing unit,
a frame having a curved inner surface, wherein a plurality of conductor pairs with an insulator interposed therebetween are arranged at regular intervals on the inner surface;
a metal ball located in the frame and moving along the inner surface of the frame according to the vibration of the housing; and
and a contact portion electrically connected to the conductor pair when the metal ball is positioned on the conductor pair of the frame;
A plurality of contact pairs are configured in the contact unit, and each contact pair is configured to match a pair of conductors arranged in the frame, respectively. According to claim 1, wherein the connector,
a sensing terminal part electrically connected to the contact pair of the contact part and conducting electricity with the contact pair of the contact part when the contact part is electrically connected to the conductor pair;
a communication module unit connected to the sensing terminal unit and generating a sensing signal while the sensing terminal unit is energized; and
Vibration sensing and control device of the enclosure, characterized in that it includes; a control terminal unit for receiving the control signal generated by the controller. 3. The method of claim 2,
Vibration sensing and control device of the enclosure, characterized in that the communication module unit includes a time delay element for transmitting the detected signal by delaying the time. The method of claim 2, wherein the controller comprises:
an earthquake magnitude determination unit electrically connected to the connector and receiving a sensing signal transmitted from the connector to determine an earthquake magnitude;
an earthquake magnitude display unit for displaying the earthquake magnitude determined by the earthquake magnitude determination unit with a display lamp unit and a voice alarm unit;
an operation command unit for generating a control signal for controlling the circuit breaker in the enclosure according to the earthquake magnitude determined by the earthquake magnitude determination unit and a status signal for the earthquake magnitude determined by the earthquake magnitude determination unit; and
and a communication unit for transmitting the status signal generated by the operation command unit to a remote monitoring and control panel. delete delete

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