KR101310169B1 - Distributing board including seismic isolation bearing - Google Patents

Abstract

PURPOSE: A switchgear is provided to improve structural stability by installing a seismic isolation support with excellent vibration damping power at the lower part. CONSTITUTION: A pad plate (10) is placed on the bottom surface (1). A cover plate (20) is combined with the lower surface of a main body (200). A moving block (30) moves horizontally between the pad plate and cover plate. A lower guide rail (11) is comprised in the pad plate to guide the movement of the moving block. A top guide rail (21) is comprised in the cover plate to guide the movement of the moving block. A reconstruction spring (12) restores the moving block to the initial position.

Description

Switchgear with vibration isolation base {DISTRIBUTING BOARD INCLUDING SEISMIC ISOLATION BEARING}

The present invention relates to a switchgear, and more particularly, to a switchgear structure is configured by the base plate is configured to minimize the occurrence of adverse effects due to the transmission of external vibration by forming an earthquake support to the bottom of the switchgear to maximize the vibration damping force during the earthquake.

In general, a switchgear, a switchgear, a distribution board, a motor control panel (MCC) is a device that receives a high-voltage or extra-high voltage electricity supplied by the power company and converts it into a voltage used by the customer to distribute the load to the load facility.

The water distribution panel has a partition structure called cubicles on the surface.Inside the control panel, it protects and monitors power devices such as high voltage switchgear, current transformer, high voltage circuit breaker, transformer, low voltage circuit breaker and magnet. Electrical components such as relays and instruments are mounted. Inside the cubicle, in addition to the power devices, busbars connecting the power devices according to the power system and wirings for the measurement and monitoring of the power devices are arranged, and the outside of the cubicle is installed on the floor, and between the power devices on the floor. Holes for monitoring wiring and load facility wiring are formed. If external vibrations or shocks due to earthquakes occur due to the reason why the control panel is installed on the ground, damage or breakage of the power devices inside the control panel, the wirings interconnecting these power devices, and electrical components such as protection relays, etc. It is easy to do so, and the interruption generated may cause interruption of power supply and fire.

As a prior art of the applicant for solving this problem, Patent Registration No. 1139226 (earthquake-proof and dustproof switchboard) has a technology that can reduce the transmission of external vibration such as an earthquake by installing an elastic bearing under the switchboard. It has been proposed.

However, the above prior art is effective for earthquakes of weak magnitude (magnitude 1 to 4), but when an earthquake of strong magnitude (magnitude 5 or more) occurs, breakage of elastic rubber occurs, causing the switchgear to fall down, thus more effectively preventing the shockproof of the switchgear. There is a demand for technology development to secure the system.

The present invention has been proposed to improve the above-described conventional problems, by mounting a base support structure that can attenuate the vibration transmitted from the floor more quickly in the lower part of the switchgear so that the switchgear does not fall even when a strong earthquake occurs. There is a purpose.

The present invention for achieving the above object, in the switchgear is coupled to the base plate to reduce the vibration transmission from the bottom surface of the main body of the switchgear, wherein the base plate, the base plate is placed on the bottom surface; An upper plate coupled to the bottom surface of the switchboard body; A moving block coupled between the support plate and the upper plate; A lower guide rail configured on the support plate to guide the movement of the moving block; An upper guide rail configured on the upper plate to guide the movement of the movable block; It characterized in that the configuration comprising a restoring spring that is connected to the support plate or the upper plate to restore the movable block to the original position.

The present invention, by installing the base plate bearing having excellent vibration damping force in the lower part of the switchgear, even if an external shock caused by a strong earthquake, etc. can be quickly attenuated vibration to prevent the occurrence of rapid horizontal vibration and structural safety of the switchgear It shows an effect that can be improved.

In particular, since a restoring spring having a restoring function forms a double structure in which a resistive steel is formed therein, a sudden elastic restoring force can be prevented to maximize vibration damping effect.

1 is a front structure diagram of the switchgear installed the base isolation support of the present invention.
Figure 2 is a base isolation plan and front cross-sectional structure diagram of the present invention.
3 is a cross-sectional view of the AA portion of FIG.
4 is a sectional view taken along the line BB of FIG.
Figure 5 is a side view of the isolation base isolation of the present invention.
6 is a plan view and a front sectional structure of the base isolation bearing operation state of the present invention.
7 is a detailed structural diagram of the restoration spring in the present invention.

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

First, look at the installation structure of the base isolation support of the switchgear according to an embodiment of the present invention.

In the present embodiment, the base isolation support 100 is coupled to the lower part of the switchgear switchgear main body 200 in order to reduce vibration transmission from the bottom surface 1, and a support plate placed on the bottom surface 1 ( 10); The upper plate 20 coupled to the bottom of the switchboard main body 200, the movable block 30 coupled between the support plate 10 and the upper plate 20, and the movement of the movable block 30 are guided. In order to guide the movement of the lower guide rail 11 and the movable block 30, which is configured in the support plate 10 to the upper guide rail 21 is configured in the upper plate 20, and the movable block ( It is composed of a restoring spring 12 that is connected to the backing plate 10 or the upper plate 20 to restore the original position 30.

In particular, the lower guide rails 11 and the upper guide rails 21 are provided with a pair of three rail rods, respectively, it can be seen that the upper, lower rails are configured in the form perpendicular to each other.

In addition, the upper and lower portions of the moving block 30 are formed so that the rolling rollers 31 and 32 cross each other at right angles to allow movement along the lower guide rails 11 and the upper guide rails 21, respectively. However, each of the roller rollers (31, 32) is provided in a symmetrical form to form a predetermined inclination angle in a pair forming two mutually constant interval (d), the separation distance (d) between the roller rollers (31, 32) Since the upper and lower guide rails 11 and 21 are configured to be smaller than the diameter D, the moving block 30 can be prevented from being separated from the support plate 10 and the upper plate 20.

In addition, the restoring spring 12 is composed of a low yield steel (LYS) or a carbonaceous spring (12a) made of stainless steel, which is a resistive steel having a tensile strength of 250 Mpa or more, an item strength of 80 Mpa or more and an elongation rate of 30% or more for vibration damping. In addition, it is preferable to form a double structure of the shape as shown in FIG. 9 outside the elastic spring 12b made of carbon steel for restoring function.

On the other hand, as an application example, the diaphragm film layer 12c made of carbon nanotubes (CNT) may be provided between the plastic spring 12a and the elastic spring 12b to prevent direct contact between carbon steel and resistive steel. When the diaphragm film layer 12c is formed as described above, the inner and outer springs 12a and 12b are prevented from contacting each other, thereby preventing the occurrence of interference and preventing corrosion from occurring during the operation.

In the drawings, reference numerals 33 and 34 denote auxiliary rollers.

As described above, the present invention isolating base 100 is configured to look at the effect of the effect in the state installed in the lower switchboard.

In the present embodiment, the switchboard main body 200 is fixed to the bottom surface 1 by the base isolation base 100 of the present invention in a fixed height while being installed in a fixed state. Vibration transmitted through 1) is attenuated by the base isolation 100 so that a sudden flow can be prevented.

That is, in the four base isolation bearings 100 installed at each corner, as the bottom surface 1 vibrates, the support plate 10 is horizontally vibrated together with the bottom surface 1, but such a support plate 10. The flow of is not transmitted to the upper plate 20, the movable block 30 is coupled to the lower switchboard main body 200 by flowing in the free direction along the upper and lower guide rails (11, 21) as shown in FIG. Flow transfer to the upper plate 20 can be minimized.

In particular, the movable block 30 is applied to the force to be quickly restored to the original position due to the elastic restoring action of the restoring spring 12, minimizing the amplitude of vibration, and it can be seen that the rapid restoring action can be made. Can be.

Therefore, when the base isolation base 100 of the present invention is installed in the lower part of the switchboard main body 200, even if external vibration is generated due to a strong earthquake, rapid vibration attenuation can be prevented, thereby preventing rapid horizontal vibration generation. Accordingly, it can be seen that the structural safety of the switchgear can be improved.

In addition, although specific embodiments of the present invention have been described and illustrated above, it is obvious that the structure of the base isolation apparatus of the present invention can be variously modified and implemented by those skilled in the art.

It should be understood, however, that such modified embodiments are not to be understood individually from the spirit and scope of the invention, and such modified embodiments are intended to be included within the scope of the appended claims.

10: support plate 11: lower guide rail
12: restoring spring 12a: elastic spring
12b: elastic spring 12c: diaphragm film layer
20: upper plate 21: upper guide rail
30: moving block 31: lower cloud roller
32: upper roller roller 33,34: auxiliary roller
100: base isolation 200: switchboard main body

Claims (5)

In the switchgear is coupled to the base plate 100 to reduce the vibration transmission from the bottom surface (1) in the lower part of the main switchboard body 200,
The base isolation base 100, the support plate 10 placed on the bottom surface (1);
An upper plate 20 coupled to a bottom of the switchboard main body 200;
A moving block 30 connected to the supporting plate 10 and the upper plate 20 to allow horizontal movement;
A lower guide rail 11 configured on the support plate 10 to guide the movement of the movable block 30;
An upper guide rail 21 configured on the upper plate 20 to guide the movement of the movable block 30;
A restoring spring 12 connected to the support plate 10 or the upper plate 20 to restore the movable block 30 to its original position;
Switchgear consisting of a base isolation base, characterized in that the configuration comprising a. The method according to claim 1,
The lower guide rail (11) and the upper guide rail (21) is a switchgear configured with a base isolation base, characterized in that formed in a cross shape in a direction perpendicular to each other. The method according to claim 1 or 2,
At the upper and lower portions of the moving block 30, rolling rollers 31 and 32 are respectively configured to move along the lower guide rails 11 and the upper guide rails 21, respectively, respectively. ) Is provided in a symmetrical form of two in a pair forming a predetermined interval (d) to form a predetermined angle of inclination, and the rolling distance (d) between the rolling rollers (31, 32) is the upper, lower guide rails (11, 21) The switchgear is configured to be smaller than the diameter (D) of the base plate is characterized in that the movable block 30 is prevented from being separated from the support plate 10 and the upper plate 20. The method according to claim 1,
The restoring spring 12 has an elastic spring 12a made of a resistive steel for vibration damping therein, and an elastic spring 12b made of carbon steel for restoring function is formed therein. Switchgear consisting of a base isolation, characterized in that to form a double structure of the wrapping form. The method of claim 4,
A seismic isolator is characterized in that between the plastic spring (12a) and the elastic spring (12b) is provided with a diaphragm film layer (12c) of carbon nanotube (CNT) material for preventing direct contact between carbon steel and resistive steel. Switchboard.

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