KR101011388B1 - The quakeproof pannel and the quakeproof plate pannel - Google Patents

Abstract

PURPOSE: An earthquake-resistance plate and a distribution board using the same are provided to prevent an electrical accident by protecting an internal device from vibration or impact due to an earthquake. CONSTITUTION: A spring(7) and a pad plate(8) are laminated inside a bottom plate(2). A ball(6) is mounted on the pad plate. A top plate(1) is mounted on the ball. An air inlet(5) inhales air to vacuumize a space between the top and bottom plates. The spring buffers vertical vibration due to an earthquake. The ball buffers the right and left vibration due to the earthquake.

Description

Seismic Design Plate and Switchboard {The quakeproof pannel and The quakeproof plate pannel}

The present invention relates to an earthquake-proof plate and a switchgear to which an earthquake-resistant plate is applied. More specifically, the present invention relates to a power device and an electric appliance mounted inside a switchgear due to a twist or tilt of a switchgear due to vibration or shock caused by a crustal change such as an earthquake. A seismic design switchgear having a seismic plate and a control device for preventing breakage of parts.

In general, a switchgear is a device that receives high voltage or extra high voltage electricity supplied by a power company and converts it to a voltage used by a customer to distribute the load to a load facility. The switchgear has a partition structure called cubicles on the surface, and inside the switchgear is a high-voltage switchgear, a current transformer for instrumentation, a high-voltage circuit breaker, a transformer, and a low-voltage switchgear. Parts are mounted. Inside the cubicle, in addition to the power devices, busbars connecting the power devices according to the power system and wiring for measuring and monitoring the power devices are arranged. The outside of the cubicle is installed on the floor, and the power devices are mutually Holes for monitoring wirings and load facility wirings are formed. If external vibration or shock occurs due to the earth's crust due to the above-described switchgear being installed on the ground, the power devices inside the switchgear, the wirings interconnecting these power devices, and electrical parts such as protection relays may be damaged or damaged. It is easy to cause interruptions in the power supply and fires due to the resulting faults.

In order to solve the above problems, there was a case of using a dustproof pad, a seismic plate with a dustproof spring.

However, in case of adopting a vibration pad or vibration spring, when applied to a transformer with self-vibration, it is not fixed to prevent the transformer from vibrating, but instead absorbs the vibration by vibrating according to the vibration of the transformer. Connected connections resulted in loosening over time.

Therefore, the usual purpose of fixing the transformer on the floor, rather than absorbing vibration, and feel the need for earthquake-resistant design to vibrate and absorb the vibration only when an earthquake or the like occurs.

Normally, the transformer is firmly fixed to the floor to reduce the vibration of the transformer. In the event of an earthquake, a new concept of seismic design is developed that can act as a buffer between the floor and the transformer.

When an earthquake occurs by connecting the upper plate and the lower plate with a ball, the upper plate and the lower plate work together actively to absorb shocks such as earthquakes.Usually, the upper plate and the lower plate are firmly combined so that the upper plate vibrates. Even if it is firmly fixed to the floor.

As described above, the earthquake-proof switchgear according to the present invention can prevent damage to the internal equipment of the switchgear by buffering the shock-absorbing shock absorber caused by an earthquake or the like, thereby preventing large-scale accidents caused by power failures and short circuits. On the other hand, if there is a self-vibration such as a transformer, it is normally fixed to the floor to prevent loosening of each device connected to the transformer.

It has a clear distinction from the prior art, and ignores the characteristics that must be firmly fixed to the floor in order to reduce the self-vibration of the transformer, install a vibration pad, a vibration-proof spring, etc. to amplify the vibration of the transformer rather than the equipment connected to the transformer It solves the problem of loosening the connection part and increasing the noise (the upper and lower plate is firmly fixed in the vacuum state and firmly fixed to the floor in normal time), and effectively absorbs vibration in the event of an earthquake (the vacuum state is released and the upper and lower plates are It is separated by a ball and a spring to vibrate and absorb vibration as a result of an earthquake.

1 is a simplified cross-sectional view for understanding the present invention
Figure 2 is a simplified cross-sectional view of the air is stabilized in a vacuum state around the ball so that the upper plate and the lower plate is fixed
Figure 3 is a simplified diagram for one embodiment for understanding the earthquake detection sensor for detecting an earthquake

It will be described in detail with reference to the drawings.

1 is a simplified side cross-sectional view for understanding the present invention.

Figure 2 is a simplified side cross-sectional view of the air is removed between the upper plate and the lower plate and the empty space around the ball is vacuumed so that the upper plate and the lower plate is fixed

Figure 3 is an embodiment for understanding the earthquake detection sensor for detecting earthquake Simple road The simplest and simplest road of the old earthquake detection sensor In the present invention uses an earthquake detection sensor for detecting earthquakes through a detection sensor for detecting an earthquake. There has been a variety of techniques in the prior art earthquake detection sensor, the present invention is not limited to a specific earthquake detection sensor.

After stacking the spring (7), the backing plate (8) in the lower plate (2), put the ball (6) and cover the upper plate (1) to suck the air through the air inlet (5) with a vacuum pump to the upper plate The upper plate 1 and the lower plate 2 are fixed by closing the solenoid valve 4 after making the space 9 between (1) and the lower plate 2 into a vacuum state;

When the earthquake is detected by the earthquake detection sensor, the controller composed of a microprocessor opens the solenoid valve 4 to suck air into the space 9 between the upper plate 1 and the lower plate 2 so that the upper plate 1 And the lower plate (2) is separated and the upper plate (1) and the lower plate (2) vibrate to vibrate the vibration caused by the earthquake with the spring (7) and the left and right vibrations (6) between It is a switchgear to which a seismic design plate and a seismic design plate are absorbed.

According to the present invention, the upper plate and the lower plate are fixed at the bottom of the transformer with vibration in general to minimize the vibration of the transformer, and when an earthquake occurs, the upper plate and the lower plate are separated and the lower plate and the upper plate are vibrated, respectively. It is the first invention to absorb earthquake vibration and to change the seismic response according to the occurrence of earthquake.

Hereinafter, the claims will be described in detail.

(Mainly on claim 1 paragraph)

After stacking the spring (7), the backing plate (8) in the lower plate (2), put the ball (6) and cover the upper plate (1) to suck the air through the air inlet (5) with a vacuum pump to the upper plate The space 9 between the lower plate 2 and the lower plate 2 is made into a vacuum state, and the upper plate 1 and the lower plate 2 are fixed by closing the solenoid valve 4.

When the earthquake is detected by the earthquake sensor, the control unit composed of a microprocessor opens the solenoid valve 4 so that air is sucked into the space 9 between the upper plate 1 and the lower plate 2 to prevent vibration caused by the earthquake. It is possible to vary the seismic response according to the occurrence or absence of earthquakes by buffering the vibration between the upper plate 1 and the lower plate 2 by the spring 7 and the left and right oscillation balls 6. It is a seismic design plate characterized by.

(Mainly on claim 2 Clause)

After stacking the spring (7), the backing plate (8) in the lower plate (2), put the ball (6) and cover the upper plate (1) to suck the air through the air inlet (5) with a vacuum pump to the upper plate The space 9 between the lower plate 2 and the lower plate 2 is made into a vacuum state, and the upper plate 1 and the lower plate 2 are fixed by closing the solenoid valve 4.

The transformer is fixed to the upper plate, and the lower plate is fixed to the bottom of the substation or switchboard.

When the earthquake is detected by the earthquake sensor, the control unit composed of a microprocessor opens the solenoid valve 4 so that air is sucked into the space 9 between the upper plate 1 and the lower plate 2 to prevent vibration caused by the earthquake. It is possible to vary the seismic response according to the occurrence or absence of earthquakes by buffering the vibration between the upper plate 1 and the lower plate 2 by the spring 7 and the left and right oscillation balls 6. Seismic Design Plate Switchgear

(Centering on claim 3)

The earthquake-proof design switchgear according to claim 1, wherein each panel of the switchgear is fixed to the upper plate. Each panel is fixed to the upper plate and the lower plate is fixed to the bottom of the substation chamber.

1: upper plate
2: lower plate
3: Air suction pipe in the lower plate
4: solenoid valve
5: air intake
6: ball
7: spring
8: support plate
9: space between upper plate and lower plate

Claims (3)

After stacking the spring (7), the backing plate (8) in the lower plate (2), put the ball (6) and cover the upper plate (1) to suck the air through the air inlet (5) with a vacuum pump to the upper plate The upper plate 1 and the lower plate 2 are fixed by closing the solenoid valve 4 after making the space 9 between (1) and the lower plate 2 into a vacuum state;
When the earthquake is detected by the earthquake sensor, the control unit composed of a microprocessor opens the solenoid valve 4 so that air is sucked into the space 9 between the upper plate 1 and the lower plate 2 to prevent vibration caused by the earthquake. It is possible to vary the seismic response according to the occurrence or absence of earthquakes by buffering the vibration between the upper plate 1 and the lower plate 2 by the spring 7 and the left and right oscillation balls 6. Earthquake-proof design plate characterized in.
After stacking the spring (7), the backing plate (8) in the lower plate (2), put the ball (6) and cover the upper plate (1) to suck the air through the air inlet (5) with a vacuum pump to the upper plate The upper plate 1 and the lower plate 2 are fixed by closing the solenoid valve 4 after making the space 9 between (1) and the lower plate 2 into a vacuum state;
Securing the transformer to the upper plate;
When the earthquake is detected by the earthquake sensor, the control unit composed of a microprocessor opens the solenoid valve 4 so that air is sucked into the space 9 between the upper plate 1 and the lower plate 2 to prevent vibration caused by the earthquake. It is possible to vary the seismic response according to the occurrence or absence of earthquakes by buffering the vibration between the upper plate 1 and the lower plate 2 by the spring 7 and the left and right oscillation balls 6. Seismic Design Plate Switchgear
The seismic design plate switchgear according to claim 1, wherein each panel of the switchgear is fixed to the upper plate.

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