KR20200094969A - Generator with vibration isolation and anti-resonance function - Google Patents

Abstract

The present invention relates to a distribution board with a vibration isolation and resonance prevention function. An objective of the present invention is to provide a distribution board with a resonance prevention function which can effectively absorb or alleviate vibration generated when operating a distribution board, and prevent resonance in vibration by an earthquake to prevent damage to the distribution board. To achieve the objective, the distribution board comprises: a power device to control electricity; a busbar connected to the power device to supply electricity to the power device or connected to allow electricity controlled by the power device to flow to another power device or to the outside; and a case to accommodate the power device. The distribution board with a vibration isolation and resonance prevention function comprises: a plurality of linear vibration-proof modules installed on the lower surface of the case to be positioned between the case and the ground, and arranged to be dispersed in a horizontal direction; a fixed module installed to be fixed on the ground inside a formation formed by the plurality of linear vibration-proof modules; and a plurality of twisting elastic members connecting the fixed module and the linear vibration-proof modules, wherein one end thereof is fixed on the linear vibration-proof modules, and the other end thereof is fixed on the fixed module to be twisted and alleviate vibration when the distribution board operates or an earthquake occurs.

Description

Switchgear with vibration isolation and anti-resonance function {Generator with vibration isolation and anti-resonance function}

The present invention relates to a switchboard, and more particularly, a combination of a linear elastic material and a torsional elastic material, as well as vibrations generated during operation of the switchboard, as well as various types of vibrations due to earthquakes, and damage due to the occurrence of resonance. It relates to a switchboard having a seismic isolation and a resonance prevention function to prevent this.

Such a switchboard includes a case made of an empty box structure, a power device such as a circuit breaker or a transformer that controls the supplied electricity, and is connected to the power device so that electricity is supplied to the power device or the electricity controlled by the power device. It includes a bus bar that is connected to flow to other power devices or to the outside.

On the other hand, since the power device is fixedly installed inside the case, and the case is fixedly installed on the ground, the case constituting the switchboard is deformed by the vibration of the seismic wave when an earthquake occurs, or various power devices installed inside the case are There is a problem that it may be damaged, and thus, not only cannot normally supply electricity to a place requiring electricity, but also increases the risk of fire and electric shock due to a short circuit.

Moreover, in recent years, large and small earthquakes are frequently occurring in many regions of the world as well as in Korea, so the seismic structure to protect the switchboard from vibrations caused by earthquakes is recognized as an essential component of the switchboard.

On the other hand, Patent Document 1 discloses an example of a switchboard including a seismic structure.

The seismic switchboard according to the patent document 1 includes a main body having a plurality of panels, a power device installed in the main body and for controlling electricity supplied to the main body, and transmitting electricity supplied to the main body, or The busbar that transmits electricity controlled by the power device to the outside of the main body and a pair of busbars arranged spaced apart from each other are electrically connected, or the busbar and the terminal of the power device are electrically connected to absorb the vibration of the ground. And a busbar connecting member formed of a flexible material, and an elastic support part installed on the panel of the main body and elastically supporting the power device so as to absorb the vibration of the ground.

In the case of the seismic switchboard configured as described above, the elastic support part absorbs the vibration transmitted to the power device when the vibration occurs due to the earthquake, thereby preventing the power device from being damaged or malfunctioning due to the vibration, and the busbar connecting member is It has the advantage of reducing damage to the switchboard due to an earthquake by preventing the connection part of the busbar from being broken while being flexibly deformed in response.

However, since earthquakes may last for a certain period of time and aftershocks are generally repeated, the power device must also vibrate at some point, and when the natural frequency of the power device matches the frequency of the seismic wave when the power device vibrates, There is a problem in that the vibration of the power device is amplified, causing great damage.

On the other hand, in the elastic support part, it is preferable that the elastic modulus is small in order to reduce the propagation of vibration, but when the elastic modulus is small, the absorption of vibration energy is delayed, and the compression displacement by the vibration is large, resulting in unsafe operation.

In addition, since the center of gravity of the switchboard is not in the center and is skewed to either side, eccentric vibration occurs during operation of the switchboard. In addition, when combined with various types of vibrations caused by earthquakes, resonance occurs and the switchboard operation becomes impossible. There is this.

Registered Patent Publication No. 1253774 (announcement on April 11, 2013)

The present invention has been made in consideration of the above problems, and an object of the present invention is not only to be able to effectively absorb or mitigate vibrations generated during operation of the switchboard, but also to prevent the occurrence of resonance during vibrations caused by earthquakes. It is to provide a switchboard having a resonance prevention function to prevent damage.

The present invention, which achieves the above object and performs the task to eliminate the conventional drawbacks, provides a power device that controls electricity, and is connected to the power device to supply electricity to the power device or controlled by the power device. In a switchboard including a busbar connected to allow electricity to flow to other power devices or to the outside, and a case accommodating the power device, it is installed on the bottom of the case so as to be located between the case and the ground, and distributed in a horizontal direction. A plurality of linear anti-vibration modules arranged to be arranged; A fixed module installed to be fixed to the ground from the inside of a large size formed by the plurality of linear vibration-proof modules; And a plurality of connecting the fixed module and each of the linear vibration isolating modules, wherein one end is fixed to the linear vibration isolating module, and the other end is fixed to the fixed module, so as to mitigate vibration while twisting when the switchboard is operated or an earthquake occurs. It provides a switchboard having a seismic isolation and resonance prevention function comprising;

Meanwhile, in the switchboard having the seismic isolation and resonance prevention function, the torsional elastic material may be formed to be bent, including one or more bent portions, so as to mitigate or absorb vibration while twisting when vibration occurs.

Meanwhile, in the switchboard having the seismic isolation and resonance prevention function, both ends of the torsion elastic member are processed flat in the form of a flat plate, and a bolt for coupling with a linear vibration isolating module or a fixed module passes through the center of the flat plate. It may consist of a ball formed.

In addition, a rubber block installed to surround the torsion elastic material at the connection portion between the torsion elastic material and the case; And a fixing means made of a fixing bracket that is fixedly installed on the bottom surface of the case while surrounding the rubber block.

According to the present invention having the above characteristics, vibration energy due to linear displacement is absorbed by the compression of the linear vibration isolating module and is converted into torsional energy of the torsional elastic material during vibration due to the operation of the switchboard or earthquake. The absorbing seismic isolating effect is great, and as the torsional elastic material and the linear vibration isolating module are combined to absorb vibrations by different behaviors, there is an effect of suppressing the occurrence of resonance and preventing damage to the switchboard.

1 is a front view of a switchboard according to a preferred embodiment of the present invention,
2 is a perspective view showing a connection structure of a linear vibration-proof module, a fixed module, and a torsional elastic material according to the present invention;
3 is a plan view showing a connection structure between a linear vibration-proof module, a fixed module, and a torsional elastic material according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail in connection with the accompanying drawings. In describing the present invention, when it is determined that detailed descriptions of related known functions or configurations may unnecessarily obscure the subject matter of the present invention, detailed descriptions thereof will be omitted.

1 is a front view of a switchboard according to a preferred embodiment of the present invention, FIG. 2 is a perspective view showing a connection structure of a linear vibration-proof module according to the present invention, a fixed module, and a torsional elastic material, and FIG. 3 is a linear vibration-proof module according to the present invention. And a plan view showing the connection structure of the fixing module and the torsional elastic material.

The switchboard according to the present invention is composed of a power device 110, a bus bar 120, a case 130, a linear vibration-proof module 140, a fixed module 150, and a torsional elastic material 160.

The power device 110 controls electricity supplied to the switchboard from a power company, and may be, for example, a wiring breaker (MCCB), an air breaker (ACB), a vacuum breaker (VCB), a current transformer, etc., and can be used as a switchboard. One or more power devices 110 may be installed inside the switchboard for appropriate control of the supplied electricity.

On the other hand, the power device 110 is provided with a terminal 111 through which electricity is drawn in or out.

The bus bar 120 is installed to be connected to the power device 110 so that electricity supplied to the switchboard can be introduced into the power device 110, and the electricity controlled by the power device 110 is transferred to another power device ( It may be installed in a structure that connects the two power devices 110 to be transmitted to 110, or may be installed to extend from the power device 110 so that electricity controlled by the power device 110 can be withdrawn to the outside. Meanwhile, in the case of FIG. 1, since only one power device 110 is installed inside the case 130, the structure of a bus bar connecting the two power devices 110 is not shown.

Meanwhile, the bus bar 120 is fixed to the case 130 by the insulator 121.

The case 130 is configured to form a space in which parts constituting the switchboard are installed by combining a plurality of panels, and a base frame 131 in the form of a beam to which the linear vibration isolating module 140 is coupled is provided at the lower end. do.

Since the case 130 may have various structures and shapes, a more detailed description of the case 130 will be omitted.

The linear vibration isolating module 140 absorbs vibration while being compressed during operation of the switchboard, and a plurality of the linear vibration isolating modules are arranged to be distributed between the case 130 and the ground 180, and in FIGS. 2 and 3, four linear vibration isolating modules ( A structure in which 140 is disposed to be distributed under the case 130 is shown.

Meanwhile, each of the linear anti-vibration modules 140 includes an upper sheet 141 fixed to the case 130, a lower sheet 142 fixed to the ground and supporting the upper sheet 141 to be movable, and the upper sheet It may be composed of a linear elastic material 143 installed between the 141 and the lower sheet 142.

Meanwhile, the linear elastic material 143 may be composed of a compression spring or a rubber spring, and a hole or a bracket for coupling the torsion elastic material 160 may be formed in the upper sheet 141.

The linear vibration isolation module 140 is installed under the case 130 to absorb or mitigate vibration.

The fixing module 150 supports one end of the torsion elastic material 160 and is installed to be fixed to the ground from the inside of the large size formed by the plurality of linear vibration-proof modules 140.

For example, as shown in Figs. 2 and 3, when the four linear vibration-isolating modules 140 are arranged in a square shape, the fixed module 150 is located in the center of the quadrangular shape formed by the four linear vibration-isolating modules 140 It is installed on the ground to do so.

A plurality of holes or a plurality of brackets to which the torsional elastic material 160 is coupled may be formed at the upper end of the fixing module 150.

The torsion elastic material 160 is to mitigate vibration while twisting when the switchboard is operated or an earthquake occurs, and one end is fixed to the linear vibration-proof module 140, and the other end is fixed to the fixed module 150 to prevent linear vibration. It is configured to connect the module 140 and the case 130 to each other.

These torsion elastic members 160 are composed of a plurality of linear vibration isolating modules 140 composed of a plurality of each to connect to the fixed module 150, each of the torsion elastic member 160 is twisted when the vibration occurs, and alleviates the vibration. Or bend to be absorbed.

More specifically, the torsion elastic material 160 according to the present invention is formed to be bent, including one or more bent portions 161.

On the other hand, Figure 2 shows the structure of the torsion elastic member 160 bent in the shape of a letter including one bent portion 161, but the torsion elastic member 160 according to the present invention comprises two or more bent portions It may be formed to be bent in a three-dimensional three-dimensional shape including (161).

Such a torsion elastic member 160 may be formed by bending a spring steel material in the form of a rod having a predetermined length to have a required shape, and both ends are processed flat in the form of a flat plate, and at the center of the flat plate portion A fastening hole through which a bolt for coupling with the linear vibration isolation module 140 or the fixed module 150 passes is formed.

The torsion elastic member 160 formed as described above is fixed at one end to the upper sheet 141 of the linear vibration isolation module 140 and the other end is fixed to the fixing module 150.

In this way, the torsion elastic material 160, which is installed to connect the linear vibration-proof module 140 and the fixed module 150, is smoothly twisted in response to the behavior of the switchboard and absorbs or alleviates the vibration. Fixing means 170 for fixing the central portion to the case 130 may be further included.

The fixing means 170 is made of a rubber block 171 and a fixing bracket 172.

At this time, the rubber block 171 is installed on the torsion elastic material 160 so as to have a structure surrounding a part of the torsion elastic material 160 including a hole through which the torsion elastic material 160 passes, and the fixing bracket 172 ) Is fixedly installed on the bottom of the case 130 while wrapping the rubber block 171 installed on the torsion elastic material 160.

Meanwhile, the fixing bracket 172 may be fixed to the case 130 by bolts fastened to the case 130 while penetrating both ends thereof.

The switchboard according to the present invention configured as described above absorbs or mitigates the vibration by the compression and relaxation operation of the linear vibration-isolating module 140 and the torsional operation of the torsional elastic member 160 when the operation of the switchboard or vibration occurs due to an earthquake. do.

That is, the linear vibration isolating module 140 absorbs or mitigates the vibration while repeating the compression and relaxation operation by the vibration of the vertical component.

Meanwhile, the torsional elastic member 160 having one end fixed to the fixing module 150 reacts to both the vibration of the vertical direction component and the vibration of the horizontal direction component, and absorbs or mitigates the vibration while being twisted.

As such, since the linear vibration isolation module 140 and the torsional elastic member 160 behave in different forms and absorb or mitigate the vibration, the eccentricity generated as the center of gravity of the switchboard is located away from the center of gravity of the case 130 Vibration and various types of vibrations caused by earthquakes can be combined to effectively suppress resonance.

The present invention is not limited to the specific preferred embodiments described above, and various modifications can be implemented by anyone who has ordinary skill in the art to which the present invention pertains without departing from the gist of the present invention as claimed in the claims. Of course, such changes are within the scope of the claims.

<Explanation of reference numerals for main parts of drawings>
110: power equipment 120: busbar
130: case 140: linear vibration isolation module
143: linear elastic material 150: fixed module
160: torsion elastic material 170: fixing means
171: rubber block 172: fixing bracket

Claims (4)

A power device 110 that controls electricity, and a bus bar connected to the power device 110 to supply electricity to the power device or to allow electricity controlled by the power device to flow to other power devices or to the outside. In the switchboard including the case 130 accommodating the 120) and the power device 130,
A plurality of linear anti-vibration modules 140 installed on the bottom of the case 130 so as to be positioned between the case 130 and the ground, and disposed to be distributed in a horizontal direction;
A fixed module 150 installed to be fixed to the ground from the inside of the large size formed by the plurality of linear anti-vibration modules 140; And
The fixed module 150 and each of the linear vibration isolating modules 140 are connected, but one end is fixed to the linear vibration isolating module 140, and the other end is fixed to the fixed module 150, so that the switchboard operation or earthquake A switchboard having a seismic isolation and a resonance preventing function comprising; The method according to claim 1,
The torsion elastic material 160 is a switchboard having a seismic isolation and resonance preventing function, characterized in that the bent formed by including at least one bent portion 161 to reduce or absorb the vibration while twisting when the vibration occurs. The method according to claim 1,
Both ends of the torsion elastic member 160 are processed to be flat in the form of a flat plate, and a fastening hole through which a bolt for coupling with the linear vibration isolating module 140 or the fixing module 150 is formed is formed in the center of the flat plate. A switchboard with seismic isolation and resonance prevention functions. The method according to claim 1,
A rubber block 171 installed to surround the torsion elastic material 160 at the connection portion between the torsion elastic material 160 and the case 130; And
A switchboard having a seismic isolation and resonance prevention function, characterized in that it further comprises a fixing means (170) consisting of; a fixing bracket (172) fixedly installed on the bottom of the case (130) while surrounding the rubber block (171).

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