KR102322653B1 - The earthquake-proof and vibration damping device - Google Patents

Abstract

The present invention relates to a seismic and vibration attenuating device, which can fundamentally solve a phenomenon that an elastic member is separated, comprising: a lower plate (21) fixed with an anchor (22); a housing (23) having upper and lower rebars (34, 35) installed therein; an upper cap (25) having a flange (25a); an elastic member (27) for absorbing shock; an adjusting screw (28) having an opening (28b); a T-bolt (29); and a setting value adjusting screw (36).

Description

The earthquake-proof and vibration damping device

The present invention relates to an earthquake-resistant and vibration damping device that supports devices installed inside a building so that they are not damaged even when a longitudinal wave is generated due to the occurrence of an earthquake, and more specifically, by improving its structure, It relates to a seismic and vibration damping device that allows the device to be firmly supported without separating the seismic and vibration damping device from the floor slab layer of a building even when the phosphorus P wave arrives.

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 in the building are damaged by natural disasters such as earthquakes. It is of utmost importance to ensure that the original function can be maintained 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. 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 earthquake response, so it can be overturned or damaged due to impact, and valuable storage. 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.

1A to 1E are longitudinal cross-sectional views showing the process of constructing a conventional device, with the housing 2 having anchors fixed on both sides installed on the floor slab layer 1 of the building as shown in FIG. 1A and the housing 2 ), after closing the opening (2a) with the cover (3) and then disposing the reinforcing bars (5) in the direction perpendicular to the anchor (4), the concrete mortar is poured as shown in Figure 1b.

After that, after the poured concrete mortar is cured and the concrete mortar layer 6 is formed, the cover 3 is removed and the coil spring 7 is installed inside the housing 2 and the level bolt 8 is When the opening 2a of the housing 2 is closed with the screw-coupled upper cover 9 and the adjusting bolt 10 is locked by screwing the adjusting bolt 10 from both sides of the upper cover 9 as shown in FIG. 1C, FIG. As shown in 1d, the concrete mortar layer 6 poured to the outside of the housing 2 rises together to form an air layer 11 on the top of the slab layer 1, so as shown in FIG. By forming, the construction of the vibration damping device is completed.

Therefore, by installing an air conditioning room or a machine room (not shown) on the upper surface of the plastering finishing layer 12, vibration and noise generated in the air conditioning room or the machine room are prevented.

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

However, these conventional devices expect the effect of preventing vibration and noise generated in the air conditioning room or machine room, but when a P-wave longitudinal wave is generated in the building due to the occurrence of an earthquake, the level bolt screwed to the upper cover is a coil placed on the floor slab layer. Since the upper cover is detached from the housing because it is simply inserted into the spring, a fatal defect has occurred in that the air conditioning room or the machine room installed in the upper cover is damaged.

The present invention has been devised to solve such problems in the prior art, and by improving its structure, a coil spring or rubber that absorbs noise and vibration generated in an air conditioning room or a machine room even when a longitudinal wave of P wave occurs in a building due to an earthquake. An object of the present invention is to fundamentally solve the phenomenon of the elastic member, such as the like, being separated.

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, a lower plate fixed with an anchor on the upper surface of the slab layer, is installed on the upper surface of the lower plate, is integrated with the concrete mortar layer, a female thread is formed in the center, and the side and upper Absorbs shock while preventing separation by a housing in which upper and lower reinforcing bars are installed, an upper cap installed inside the housing and having a flange, and a guide piece installed under the upper cap and fixed to the lower plate an elastic member that is screwed to the female thread of the housing and has an opening in the center, a T bolt fitted through a through hole formed in the lower plate and screwed to the upper cap, and a T through the opening of the adjusting screw The housing consists of a set value adjusting screw that is screwed to the bolt and adjusts the set value of the elastic member, installs upper and lower reinforcing bars in the housing, and then rotates the adjusting screw while the concrete mortar layer poured around the housing is cured. There is provided a seismic and vibration damping device, characterized in that it rises together with the concrete mortar layer to form an air layer between the slab layer, the concrete mortar layer, and the housing and the upper cap, respectively.

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According to the present invention, even if a longitudinal wave is generated in a building due to an earthquake, etc., an elastic member such as a coil spring or rubber that absorbs noise and vibration generated in an air conditioning room or a machine room absorbs the longitudinal wave while compressing upward to absorb the longitudinal wave. It is possible to fundamentally solve this breakage phenomenon.

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.

1a to 1e are longitudinal cross-sectional views showing the process of constructing a conventional device;
2 and 3 are longitudinal cross-sectional views showing an embodiment of the present invention,
Figure 2 is a state diagram in which concrete mortar is poured to surround the housing;
Figure 3 is a state diagram in which the air layer is formed by increasing the concrete mortar layer together with the housing as the adjusting screw is rotated;
4 and 5 are longitudinal cross-sectional views showing another embodiment of the present invention,
4 is a state diagram in which concrete mortar is poured to surround the housing;
5 is a state diagram in which the air layer is formed by increasing the concrete mortar layer together with the housing as the adjusting screw is rotated;

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art to which the present invention pertains can easily implement them. The present invention may be embodied 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. In addition, the same reference numerals are used to indicate like features to the same structure, element, or part appearing in two or more drawings.

2 and 3 are longitudinal cross-sectional views showing an embodiment of the present invention, in which the lower plate 21 is fixed to the upper surface of the slab layer 20 by a plurality of anchors 22, and the lower plate 21 ), the housing 23 having a female thread 23a formed in the center is placed on the upper surface of the housing 23, and as the concrete mortar poured out of the housing 23 is cured, it is configured to be integrated with the concrete mortar layer 24.

In addition, upper and lower caps 25 and 26 each having flanges 25a and 26a are installed inside the housing 23, and between the upper and lower caps 25 and 26, an air conditioning room or a machine room is provided. An elastic member 27, such as a coil spring or rubber, for absorbing noise and vibration generated from the device is installed, and an adjusting screw 28 is screwed to the female thread 23a of the housing 23.

A curved portion 28a is formed on the bottom surface of the adjusting screw 28, and a groove 25b for accommodating the curved portion 28a is formed on the upper cap 25, and grease or the like to minimize frictional resistance on their connection surfaces. of lubricating oil (not shown) is applied.

A T-bolt 29 is screwed to the adjusting screw 28 through the through holes 25c and 26b formed in the upper and lower caps 25 and 26, and the concrete mortar layer poured to surround the housing 23 As (20) is cured, as the adjusting screw (28) is rotated, the housing (23) rises together with the concrete mortar layer (24), and the slab layer (20), the concrete mortar layer (24), and the housing (23) and air layers 30 and 31 are respectively formed between the upper cap 25 and the upper cap 25 .

At this time, a damping member 32 for absorbing vibration is further installed under the T-bolt 29 to be in close contact with the floor. (29) is intended to absorb the impact.

4 and 5 are longitudinal cross-sectional views showing another embodiment of the present invention, wherein the lower plate 21 is fixed to the upper surface of the slab layer 20 by a plurality of anchors 22, and the upper surface of the lower plate 21 A housing 23 having a female thread 23a in the center is placed there, and upper and lower reinforcing bars 34 and 35 are installed on the side and upper sides of the housing 23 and poured out of the housing 23 It is configured to be integrated with the concrete mortar layer 24 as the concrete mortar is cured.

A guide piece 21a is formed on the lower plate 21 , and an upper cap 25 having a flange 25a is installed inside the housing 23 , and the guide piece 21a and the upper cap 25 are provided. An elastic member 27, such as a coil spring or rubber, for absorbing noise and vibration generated in the air conditioning room or machine room is installed between the units.

An adjusting screw 28 having an opening 28b in the center is screwed to the female thread 23a of the housing 23 , and a T-bolt 29 is formed in the lower plate 21 to the upper cap 25 . It is screwed through the through hole 21b, and the T-bolt 29 has a setting value adjusting screw 36 that adjusts the setting value of the elastic member 27 through the opening 28b of the adjusting screw 28 is screwed. has been

A curved portion 28a is formed on the bottom surface of the adjusting screw 28, and a groove 25b for accommodating the curved portion 28a is formed on the upper cap 25, and grease or the like to minimize frictional resistance on their connection surfaces. of lubricating oil (not shown) is applied.

Therefore, after installing the upper and lower reinforcing bars 34 and 35 in the housing 23, the adjusting screw 28 with a screwdriver 33 is tightened while the concrete mortar layer 24 poured to surround the housing 23 is cured. As it rotates, the housing 23 rises together with the concrete mortar layer 24, and the air layer 30, 31 between the slab layer 20 and the concrete mortar layer 24, and between the housing 23 and the upper cap 25. ) is configured to be formed, respectively.

At this time, an isolation member 37 such as vinyl is further installed between the lower plate 21 and the housing 23, which is a slab layer 20 and a concrete mortar layer ( This is to facilitate the separation of the concrete mortar layer 24 from the lower plate 21 when the housing 23 is raised together with the concrete mortar layer 24 so that the space 30 is formed in the 24).

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

First, as shown in Figure 2, the housing 23 is fixedly installed with the lower plate 21 to pour concrete mortar to the outside of the housing 23, and then the concrete mortar is cured to form the concrete mortar layer 24, After that, the adjustment screw 28 is rotated with the driver 33 to raise the concrete mortar layer 24 together with the housing 23 by a predetermined height (about 50 mm).

Therefore, when the adjusting screw 28 is rotated with the driver 33, the adjusting screw 28 rotates idly together with the T bolt 29, but the adjusting screw 28 is screwed to the female thread 23a of the housing 23. 3, the concrete mortar layer 24 is integrated with the housing 23 so that the slab layer 20 and the concrete mortar layer 24, and the housing 23 and the upper cap ( 25) between the air layers 30 and 31 are respectively formed.

On the other hand, in FIG. 4 shown in another embodiment, the housing 23 is installed in close contact with the lower plate 21 , and upper and lower reinforcing bars 34 and 35 are respectively disposed on the side and upper portions of the housing 23 , and then After pouring the concrete mortar to the outside of the housing 23, after the concrete mortar is cured and the concrete mortar layer 24 is formed, the set value adjusting screw 36 screwed to the upper cap 25 is rotated Accordingly, since the upper cap 25 is lowered and the elastic member 27 is compressed, the applied load can be set.

At this time, it is more preferable to adjust the elastic member 27 to be about 70% of the applied load.

When the adjusting screw 28 is rotated with the driver 33 in this state, the adjusting screw 28 screwed to the female thread 23a of the housing 23 idly rotates to raise the housing 23 together with FIG. 5, The concrete mortar layer 24 is integrated with the housing 23 so that the air layers 30 and 31 are formed between the slab layer 20 and the concrete mortar layer 24 and the housing 23 and the upper cap 25, respectively. is formed

Therefore, when minute vibration or noise is generated according to the operation of the air conditioning room or the machine room in the state shown in FIG. 5 which is an embodiment of the present invention and FIG. to prevent vibration or noise.

However, when a longitudinal wave is applied to a building due to an earthquake, etc., the adjustment screw 28 screwed to the housing 23 presses the upper cap 25 and the elastic member 27 is not separated from the housing 23, so the longitudinal wave acting Since the elastic member 27 is attenuated, it is possible to safely maintain the air conditioning room or the machine room.

Although the embodiments of the present invention have been described above 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.

20: slab layer 21: lower plate
23: housing 24: concrete mortar layer
25: upper cap 26: lower cap
27: elastic member 28: adjusting screw
29: T bolt 30, 31: air layer
32: damping member 36: set value adjusting screw

Claims (4)

delete delete The lower plate 21 fixed to the upper surface of the slab layer 20 with an anchor 22 and the lower plate 21 installed on the upper surface of the lower plate 21 are integrated with the concrete mortar layer 24, and the female thread 23a in the center is A housing 23 formed and having upper and lower reinforcing bars 34 and 35 installed on the sides and upper portions, an upper cap 25 installed inside the housing 23 and having a flange 25a, and the upper portion An elastic member 27 installed on the lower part of the cap 25 and absorbing the shock applied while being prevented from being separated by the guide piece 21a formed on the lower plate 21, and the female thread 23a of the housing 23 ) and an adjustment screw 28 having an opening 28b in the center, and a T-bolt 29 that is screwed into the upper cap 25 by being inserted through a through hole 21b formed in the lower plate 21 and , is screwed to the T-bolt 29 through the opening 28b of the adjusting screw 28 and is composed of a set value adjusting screw 36 that adjusts the setting value of the elastic member 27 and is mounted on the housing 23 , After installing the lower reinforcing bars 34 and 35, the housing 23 rotates the adjusting screw 28 while the concrete mortar layer 24 poured to surround the housing 23 is cured. Seismic and vibration damping device. 4. The method according to claim 3,
Seismic and vibration damping device, characterized in that an isolation member (37) is further installed between the lower plate (21) and the housing (23).

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