KR20210146751A - The vibration damping device by the seismic wave - Google Patents

Abstract

The present invention relates to a vibration damping device by a seismic wave which safely protects a mechanical object (an incoming/distributing board, a machine room, an air-conditioning room, a wire cable, etc.) installed on a floor or a ceiling of a building by damping vibration even if a longitudinal wave of a seismic wave is applied. An objective of the present invention is to improve the structure to firmly support a mechanical object without separating a vibration damping device on a floor slab layer of a building even if a P-wave which is a longitudinal wave reaches the inside of the building by an occurrence of an earthquake. To this end, the vibration damping device by a seismic wave comprises: a housing (51) fixed and installed on the upper surface of a slab layer (50) by a fixing member, and provided with a polygonal hole (51a) formed at the center of an upper portion thereof; an upper and a lower cap (52, 53) installed in the housing (51), and provided with flanges (52a, 53a) and through holes (52b, 53b) formed in the middle thereof; an elastic member (54) installed between the upper and lower caps (52, 53) to absorb an applied impact; a sleeve (56) inserted into and installed in the hole (51a) of the housing to be lifted and lowered, and inserted into the through hole (52b) formed on the upper cap (52); a T-bolt (57) inserted through the through hole (53b) formed on the lower cap (53) to be screwed to the sleeve (56); a support bolt (59) screwed to the center of the sleeve (56) to support a frame (58); and a height adjustment nut (60) screwed to the support bolt (59) to adjust the installation height of the frame (58).

Description

The vibration damping device by the seismic wave

The present invention relates to a vibration damping device by seismic waves that safely protects appliances installed on the floor or ceiling of a building (switchboard, machine room, air conditioning room, wire cable, etc.) even when longitudinal waves of seismic waves are applied. Specifically, it relates to a vibration damping device by seismic waves that improves its structure so that even if a longitudinal P wave, which is a longitudinal wave, arrives in the building due to an earthquake, the vibration damping device is not separated from the floor slab layer of the building and can firmly support the equipment. will be.

In general, in the event of an earthquake, when the building itself is sound against the vibrations (shaking) of the building, indoor objects may fall over, or internal furniture or equipment may be damaged due to collision with each other, and the original function cannot be performed properly. is occurring frequently.

In recent years, medical-related facilities, semiconductor-related facilities, computer centers of financial institutions, disaster prevention and command centers, and computer exchange offices of telecommunication companies are insufficient in seismic design of the building itself, and internal appliances or equipment accommodated therein are damaged by natural disasters such as earthquakes. It is of utmost importance to maintain its original function even in the event of a disaster.

For example, in high value-added facilities such as semiconductor factories, production management such as pressure management, cleanliness maintenance, temperature control and humidity control, and design drawings, which are important intellectual property, are controlled and controlled in the central computer room, and buildings The seismic design itself is made.

However, in the event of an earthquake, even if the damage to the seismically-designed building itself is minor, the large computer in the central computer room or other expensive inspection equipment accommodated therein has a large seismic response, so it is overturned or damaged by shock, etc. There was a problem that the data was damaged or the original function of the equipment was lost.

Accordingly, there is a need for a device that protects expensive equipment or objects accommodated therein from vibrations generated by earthquakes, etc., apart from the earthquake-resistant design of the building itself.

1 is a longitudinal sectional view of a conventional device, and FIG. 2 is a longitudinal sectional view showing the operation state of the horizontal vibration isolator of the conventional device. Consists of an earthquake-resistant part (S1), and the vibration-proof and earthquake-resistant part (S1) has a flat shape, such as a round or square shape, and can be installed in a corner or at a predetermined interval at the bottom of the switchboard (S) in several places, and if necessary It can be installed in the center of the bottom surface of the switchgear by increasing the volume accordingly, and is composed of a vertical vibration prevention unit 10 , a horizontal vibration vibration prevention unit 20 , and a ground change response unit 30 .

The vibration-proof and vibration-proof part 10 of the vibration-proof part S1 is composed of a mounting plate 11 , a first support plate 12 , a coil spring 13 , and an elastic support member 14 , the mounting plate 11 and the first support plate 12 are vertically arranged at regular intervals, and a coil spring 13 is installed at an edge between them and an elastic support member 14 is installed in the center so that the mounting plate 11 is supported. cushions are provided.

Here, the elastic support member 14 is preferably a rubber member capable of safely supporting the weight switchgear, but may be a coil spring or a plate spring equivalent to the action of the rubber member above.

And when the upper and lower surfaces of the coil spring 13 and the elastic support member 14 are fitted into the grooves formed on the bottom surface of the mounting plate 11 and the top surface of the first support plate 12, the standing state can be stably maintained. It is possible to firmly support the mounting plate 11 .

In addition, the horizontal vibration and vibration isolating part 20 of the vibration and vibration resistant part S1 includes the first support plate 12 of the vertical vibration and vibration damping part 10, and a second A support plate 21 is provided, such that a narrow gap 22 is created between the bottom surface of the first support plate 12 and the upper surface of the second support plate 21, and the gap 22 includes the first and second support plates ( 12 and 21 so as to be maintained on the sliding member 23 placed between the first and second support plates 12 and 21 so that the sliding occurs.

The sliding member 23 may be made of a conventional seismic isolating rubber, but it may also be a ball. It is accommodated between the grooves 121 and 211 facing each other to prevent separation, and the grooves 121 and 211 are preferably formed in a donut shape when the support plate is viewed in a plan view, but the groove ( After forming the 121) and 211 themselves in a circle, a plurality of them may be radially disposed.

The anti-vibration and earthquake-resistant part (S1) of the ground change response unit 30 includes a second base plate 21 of the horizontal vibration-proof unit 20 and a base plate 31 fixed to the ground (G). As such, a space 33 is secured between the second support plate 21 and the base plate 31, and a hemispherical groove 212 in the form of a hemisphere is formed in the center of the bottom surface of the second support plate 21 to form the base plate 31 ) By connecting the upper end of the hemispherical surface 311 formed in the center of the upper surface, the second support plate 21 is supported by the base plate 31 .

In addition, at the edges of the second support plate 21 and the base plate 31, a plurality of elastic bodies 32 are arranged radially along the outer periphery of the hemispherical surface 311, so that any one of the hemispherical surfaces 311 is the basis. It allows the edge of the part to elastically support the edge of the second support plate 21 that can be inclined.

In the above, the ground (G) may be concrete poured on the ground, and the elastic body 32 has a cushion up and down such as a coil spring, a plate spring, or a buffer rubber, etc. When the base plate 31 rotates horizontally by an earthquake, the It is satisfactory if the rotation can be restored, and the mounting method of the elastic body 32 is to fit the upper and lower ends of the elastic body 32 into the lower groove formed on the lower surface of the second support plate 21 and the upper groove formed on the upper surface of the base plate 31 . It is preferable to mount, and although the number may be three or more, it is ideal to set eight or more for stable horizontal maintenance of the second support plate 21 .

That is, a lower groove into which the upper end of the elastic body 32 is inserted is formed at the edge of the second support plate 21 at a position where the elastic body 32 is positioned, and the elastic body 32 is formed at the edge of the base plate 31 . An upper groove into which the lower end of the elastic body 32 is inserted is formed at the position.

Therefore, when an earthquake occurs and vertical vibration is applied to the switchgear (S), the vertical vibration is canceled by the coil spring 13 and the elastic support member 14 of the vertical vibration isolator 10 and is vibration-proofed, so that the vertical vibration of the switchgear (S) is generated. Flow is prevented, and when horizontal vibration is applied to the switchboard (S), even if the base plate (31) and the second support plate (21) shake horizontally by the horizontal vibration of the ground (G), the first support plate (12) and The horizontal flow of the first support plate 12 is prevented by offsetting by the sliding member 23 placed between the second support plates 21 .

And when the ground level is tilted due to a change in the ground due to horizontal and vertical vibrations generated from an earthquake, the hemispherical surface ( 311) rotates in a state connected to the hemispherical groove 212 of the second support plate 21, so that the horizontal and vertical vibration dampers 10 and 20 of the upper portion of the base plate 31 can be maintained horizontally without being inclined. The switchgear (S) can be protected from the inclined ground change.

At this time, one side of the elastic body disposed on the edge between the second support plate 21 and the base plate 31 is compressed, and the other side elastic body is stretched to keep the switchboard (S) level and the ground (G) is in its original shape. Even when returning, it is possible to elastically support the switchboard (S) horizontally.

The inclination angle of the ground (G) in the above can be adjusted by the width of the space (33).

Next, when a change such as twisting of the ground (G) in the horizontal direction occurs, the hemispherical surface 311 rotates horizontally with the hemispherical groove 212 as the center, so the switchgear (S) can be protected from distortion of the ground. have.

In this case, since the elastic body 32 of the second support plate 21 and the base plate 31 is twisted, elasticity is generated, so a variable action such as twisting of the structure on the upper part of the second support plate 21 due to the ground change of the twisting occurs. is minimized

On the other hand, when the sliding member 23 placed on the bottom surface of the first support plate 12 and the upper surface of the second support plate 21 in the horizontal vibration-proof part 20 of the vibration-proof and vibration-proof part S1 is a ball, the first and second support plates When the bottom of the grooves 121 and 211 formed in (12) (21) are formed to be curved, the grooves 121 and 211 are not returned after moving horizontally on the ground (G) and the moving state is maintained. Through the curvature of the first support plate 12 is automatically returned to be able to return to the initial state.

At this time, the first support plate 12 may rise due to the curvature of the bottom of the grooves 121 and 211 , and this rise is caused by the coil spring 13 of the vertical vibration isolator 10 and the elastic support member 14 . It is achieved without obstacles by contractile force.

In addition, when the elastic body 32 between the base plate 31 and the second support plate 21 is mounted at an angle, the support structure of the elastic body 32 between the second support plate 21 and the base plate 31 is narrow at the top and at the bottom. Since it has a wide shape, when the base plate 31 is inclined, the elasticity of the elastic body 32 is exerted in a direction opposite to the angle of inclination, so that the action of the ground change response unit 30 can be made more efficiently, and further The supporting force of the second support plate 21 is also improved.

That is, the ground change response unit 30 based on the hemispherical surface 311 is configured on the base plate 31 fixed to the ground G, and based on the hemispherical surface 311 of the base plate 31 Thus, by sequentially implementing the horizontal vibration isolator 20 and the vertical vibration isolator 10, even the switchgear (S) of weight can be firmly supported and all seismic vibrations including horizontal and vertical vibrations can be vibration-proofed, and The ability to respond to changes in the ground is also excellent, so that the switchgear (S) can be protected from overturning and damage to perfection.

Republic of Korea Patent Publication No. 10-1870779 (Registered on June 19, 2018)

However, in this conventional device, the coil spring and the elastic support member of the vertical vibration isolator for suppressing vertical vibration caused by earthquakes are simply inserted into the grooves respectively formed between the mounting plate and the first support plate, so that the first support plate supports the switchgear. Since the mounting plate was separated, a fatal defect occurred in which the switchboard installed on the mounting plate was damaged.

The present invention has been devised to solve such problems in the prior art, and by improving its structure, even if a longitudinal P wave, which is a longitudinal wave, arrives in the building due to the occurrence of an earthquake, the vibration damping device is not separated from the floor or ceiling of the building. The purpose is to make it possible to firmly support the switchgear, machine room, air conditioning room, wire cable, etc.).

Another object of the present invention is to set the load applied to the elastic member according to the weight of the mechanism placed on the mount.

According to the aspect of the present invention for achieving the above object, the housing is fixedly installed by a fixing member on the upper surface of the slab layer and has a polygonal hole formed in the upper central portion, and is installed inside the housing and each flange is formed and the central portion is formed. an upper and lower cap each having through holes; an elastic member installed between the upper and lower caps to absorb an applied shock; a sleeve inserted into the hole of the housing and fitted into the through hole formed in the upper cap; A T bolt inserted through a through hole formed in the lower cap and screwed to the sleeve, a support bolt screwed to the center of the sleeve to support the mount, and a height adjustment screwed to the support bolt to adjust the installation height of the mount There is provided a vibration damping device, characterized in that consisting of a nut.

In the present invention, even if longitudinal waves are generated in buildings due to earthquakes, etc., elastic members such as coil springs or rubbers that absorb the generated longitudinal waves from noise and vibrations generated from equipment do not separate from the housing and absorb longitudinal waves while compressing upwards. It is possible to fundamentally solve the phenomenon that the equipment installed on the pedestal is damaged.

In addition, since the setting value of the elastic member can be set in an appropriate state, the effect of more effectively attenuating the generated longitudinal wave can be expected.

1 is a longitudinal cross-sectional view of a conventional device;
Figure 2 is a longitudinal cross-sectional view showing the operation state of the horizontal vibration damping unit of the prior art device;
3 is a longitudinal cross-sectional view showing an embodiment of the present invention;
4 is a longitudinal cross-sectional view showing another embodiment of the present invention;

Hereinafter, with reference to the accompanying drawings, embodiments of the present invention will be described in detail so that those of ordinary skill in the art can easily implement them. The present invention may be implemented in several different forms and is not limited to the embodiments described herein. It is noted that the drawings are schematic and not drawn to scale. Relative dimensions and proportions of parts in the drawings are shown exaggerated or reduced in size for clarity and convenience in the drawings, and any dimensions are illustrative only and not limiting. And the same reference numerals are used to denote like features to the same structure, element, or part appearing in two or more drawings.

Figure 3 is a longitudinal cross-sectional view showing an embodiment of the present invention, the present invention is a housing 51 formed with a polygonal (such as a quadrilateral or pentagonal) hole 51a in the upper center of the upper surface of the slab layer 50 It is fixedly installed by a fixing member (not shown) such as anchor bolts, and flanges 52a and 53a are formed in the inside of the housing 51, respectively, and through holes 52b and 53b are formed in the center, The lower caps 52 and 53 are installed, and between the upper and lower caps 52 and 53, an elastic member 54 such as a coil spring or rubber for absorbing an applied shock is installed.

At this time, it is preferable to further install a shock absorbing member 55 such as rubber between the slab layer 50 and the housing 51 to absorb the shock more advantageously.

In addition, in the polygonal hole 51a formed in the housing 51, a sleeve 56 fitted into the through hole 52b formed in the upper cap 52 in the same shape as the hole is inserted and installed so as to move up and down. A T-bolt 57 is inserted and screwed through the through hole 53b formed in the lower cap 53 in the 56, and a support bolt 59 for supporting the stand 58 is provided at the center of the sleeve 56. It is screwed, and a height adjustment nut 60 for adjusting the installation height of the mount 58 is screwed to the support bolt 59 .

The operation of the present invention will be described as follows.

First, in the state in which the device of the present invention is installed on the slab layer 50 as shown in FIG. 3 shown as an example, when noise or vibration is generated in the equipment such as a switchboard, a machine room, an air conditioning room, and a wire cable installed on the mount 58 Since noise or vibration is transmitted to the upper cap 52 through the sleeve 56 , it is attenuated by the elastic member 54 .

However, when a longitudinal wave is applied to the building due to the occurrence of an earthquake, the lower cap 53 moves upward, so that when the longitudinal wave is attenuated by the damping force of the elastic member 54, the sleeve 56 is screwed to the T bolt 57. Since the elastic member 54 is not separated from the housing 51 because it is coupled, it is possible to safely maintain the mechanism installed on the mount 58 .

However, in the state shown in FIG. 4 shown in another embodiment, the mount 58 on which the appliance (cable, etc.) is installed is placed on the support 62 fixed to the ceiling 61, and between the support 62 and the mount 58. is equipped with the device of the present invention.

Therefore, when noise or vibration is generated in a mechanism such as a switchboard, a machine room, an air conditioning room, a wire cable, etc. installed on the mount 58, the generated noise or vibration is transmitted to the upper cap 52 through the sleeve 56, so the elastic member 54 is attenuated by

However, when a longitudinal wave is applied to the building due to the occurrence of an earthquake, the lower cap 53 moves upward, so that when the longitudinal wave is attenuated by the damping force of the elastic member 54, the sleeve 56 is screwed to the T bolt 57. Since the elastic member 54 is not separated from the housing 51 because it is coupled, it is possible to safely maintain the mechanism installed on the mount 58 .

Although the embodiments of the present invention have been described with reference to the accompanying drawings, those of ordinary skill in the art to which the present invention pertains will understand that the present invention may be implemented in other specific forms without changing the technical spirit or essential features. will be.

Therefore, the embodiments described above are to be understood as illustrative and not restrictive in all respects, and the scope of the present invention described in the above detailed description is indicated by the following claims, meaning and All changes or modifications derived from the scope and its equivalents should be construed as being included in the scope of the present invention.

50: slab layer 51: housing
52: upper cap 53: lower cap
54: elastic member 55: shock absorbing member
56: sleeve 57: T bolt
58: mount 59: support bolt
60: height adjustment nut

Claims (2)

The housing 51 is fixedly installed on the upper surface of the slab layer 50 by a fixing member and has a polygonal hole 51a in the upper central portion, and is installed inside the housing 51 and is provided with flanges 52a and 53a, respectively. is formed and is installed between the upper and lower caps 52 and 53 each having through holes 52b and 53b in the center thereof, and the upper and lower caps 52 and 53 to absorb the applied shock. The member 54, the sleeve 56 which is inserted and installed in the hole 51a of the housing 51 so as to be able to ascend and descend and fit into the through hole 52b formed in the upper cap 52, and the lower cap 53 ) inserted through the through hole 53b formed in the T-bolt 57 screwed to the sleeve 56, and the support bolt 59 screwed to the center of the sleeve 56 to support the mount 58, and , Vibration damping device, characterized in that it is screwed to the support bolt (59) is composed of a height adjustment nut (60) for adjusting the installation height of the mount (58). The method according to claim 1,
A vibration damping device, characterized in that a shock absorbing member (55) is further installed between the slab layer (50) and the housing (51).

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