KR20220149998A - Anti-vibration device integrated type seismic anchor bracket - Google Patents

Abstract

The present invention relates to an anti-vibration device-integrated seismic anchor bracket, capable of preventing noise and vibration from being transmitted to a wall surface, which comprises: a base plate (1); a device fixing plate (2) on which a device is fixedly installed; a pair of first elastic members (3); and a first elastic member fixing means (4) for fixing the first elastic members (3).

Description

Anti-vibration device integrated type seismic anchor bracket

The present invention relates to an earthquake-resistant anchor bracket to which a vibration-proof device is integrally coupled.

In general, in order to fix the wall-mounted device to the wall, a fixing means is required, and an anchor bolt and a fixing nut are mainly used as the fixing means.

One end of the anchor bolt is inserted and fixed into the wall, the other end is coupled to a fixing bracket provided in a wall-mounted device, and a nut is fastened to the other end of the anchor bolt protruding outside the fixing bracket.

Wall-mounted devices, such as wall-mounted fans and wall-mounted boilers, generate vibration and noise during operation. It could cause damage to neighbors.

On the other hand, ground devices such as transformers and switchgear are installed on a concrete base that is formed at a certain height, and as an installation method, an 'L'-shaped bracket is fixed to the side of the enclosure of the ground device and the upper part of the concrete base, respectively.

However, in this method, the shock caused by an earthquake or external factors is transmitted to the 'L'-shaped bracket as it is, and as a result, the 'L'-shaped bracket is broken or separated, causing the ground equipment to fall and cause personal or property damage. There was a problem that there is a problem that there is a problem that there is a problem that the mechanical structure or electrical and electronic devices inside the ground device may be damaged during an earthquake or an external shock because the bracket does not have a buffer function capable of buffering the shock.

In addition, as in the embodiment shown in FIG. 15 , when the vibration-proof rubber is disposed on the wall in a right angle direction and the wall-mounted device is connected to the bolt, the vibration-proof rubber is stretched when a long time elapses or by the load of the wall-mounted device. There was a problem in that the vibration-proof rubber was sheared.

On the other hand, as the prior art of the present invention, "seismic device for mechanical structure" of application number "10-2017-0108873" has been filed and registered, and the earthquake resistant device for mechanical structure is fixed and supported at the lower part of the mechanical structure, but It is an invention that has a cushioning function by itself only in the form of a bracket due to an earthquake or an external impact.

Korean Patent Registration No. "10-2033825" (2019.10.18)

Accordingly, in order to solve the above problems, the present invention is to fix a wall-mounted device generating noise and vibration to the wall surface, and to absorb or buffer the noise and vibration generated from the wall-mounted device in the middle, thereby preventing the noise and vibration from being transmitted to the wall surface. It is to provide an anti-vibration device-integrated seismic anchor bracket that can do this.

In addition, another object of the present invention is to prevent an earthquake, vibration, or shock generated from external factors from being transmitted to the ground device when the ground device in which the mechanical structure or electrical and electronic devices are installed is installed on the ground or a structure on the ground. It is to provide an anti-vibration device-integrated seismic anchor bracket.

In addition, another object of the present invention is that when the wall-type device is installed at a right angle to the vibration-proof device using the vibration-proof rubber, as the load of the wall-type device acts on the vibration-proof device for a long period of time, the vibration-proof rubber provided in the vibration-proof device is deflected. As a result, the wall-type device relaxes with the wall, or the vibration-proof rubber provided in the vibration-proof device is sheared and destroyed.

Another object of the present invention is to provide an anti-vibration device-integrated earthquake-resistant anchor bracket that can prevent the vibration-proof rubber provided in the vibration-proof device from being easily sheared and destroyed by the horizontal seismic force when the self-contained device is installed on the vibration-proof device using the vibration-proof rubber. will provide

The anti-vibration device-integrated seismic anchor bracket according to the present invention for achieving the above object has both sides fixed to the ground or a structure or wall fixed on the ground, the center is formed to protrude, and a pair of first inclined surfaces 11 ) and the second inclined surface 12 is formed symmetrically with the base plate (1); It is disposed on the upper portion of the base plate 1 with a predetermined height interval therebetween, and a pair of third inclined surfaces 21 and fourth inclined surfaces 22 are symmetrically formed on both sides, and the ground surface or a device fixing plate (2) on which the device (B) to be fixed to a structure or wall fixed on the ground is fixedly installed; The first inclined surface 11 of the base plate 1, the third inclined surface 21 of the device fixing plate 2, and the second inclined surface 12 of the base plate 1 and the device fixing plate 2 ) a pair of first elastic members (3) each fitted between the fourth inclined surface (22); and a pair of the first elastic members 3 respectively on the first inclined surface 11 of the base plate 1 and the third inclined surface 21 of the device fixing plate 2 , and the base plate 1 , respectively. and a first elastic member fixing means (4) for fixing to the second inclined surface (12) of the device fixing plate (2) and the fourth inclined surface (22) of the device fixing plate (2), and vibration or impact is applied from the ground or the device fixing plate (2). When noise or vibration is generated from the device (B) fixedly installed in (2), a pair of first elastic members (3) mounted between the device fixing plate (2) and the base plate (1) are elastically contracted Buffers or absorbs vibrations, shocks, or noises while being restored or restored. A first long hole 23 is penetrated through the third inclined surface 21 and the fourth inclined surface 22 of the device fixing plate 2, and the first elastic member fixing means 4 is provided in the first long hole 23. The first bolt 41 provided in the is fitted, and one end of the first long hole 23 is opened. The first bolt through hole 13 is inserted into the first inclined surface 11 and the second inclined surface 12 of the base plate 1 so that the first bolt 41 provided in the first elastic member fixing means 4 is fitted. ) through, the inner diameter of the first bolt through hole 13 is formed to be larger than the outer diameter of the first bolt 41 provided in the first elastic member fixing means 4, so that the first bolt 41 is It flows while being fitted in the first bolt through hole 13 . The front center of the base plate 1 protrudes forward of the base plate 1 to increase the shear resistance and to minimize the height space between the base plate 1 and the device fixing plate 2 compared to a horizontal plane of 30 A front extension piece 18 inclined at an angle of 80 degrees to 80 degrees is mounted, and the rear center of the base plate 1 protrudes to the rear of the base plate 1 to increase the shear resistance and the base plate 1 ) and the base plate-side rear extension 19 formed symmetrically with the base plate-side front extension 18 around the center of the base plate 1 in order to minimize the height space of the device fixing plate 2 . ) is mounted, and in the center of the front of the device fixing plate 2, it protrudes forward of the device fixing plate 2 to increase the shear resistance and the height space between the base plate 1 and the device fixing plate 2 A front extension piece 24 is mounted on the device fixing plate side inclined at 30 to 80 degrees relative to the horizontal plane to minimize In order to increase the shearing resistance and minimize the height space between the base plate 1 and the device fixing plate 2, the device fixing plate side front extension piece 24 with the center of the device fixing plate 2 as the center and A symmetrically formed device fixing plate side rear extension piece 25 is mounted, and between the base plate side front extension piece 18 and the device fixing plate side front extension piece 24, and the base plate side rear extension piece A second elastic member (5) is sandwiched between the piece (19) and the rear extension piece (25) on the device fixing plate side, and the second elastic member (5) is secured by a second elastic member fixing means (6). Between the base plate side front extension piece 18 and the device fixing plate side front extension piece 24, and the base plate It is fixed between the side rear extension piece 19 and the device fixing plate side rear extension piece 25, respectively. A second long hole 26 passes through the device fixing plate-side front extension 24 and the device fixing plate-side rear extension 25, and the second elastic member fixing means ( The second bolt 61 provided in 6) is fitted, and one end of the second long hole 26 is opened. A second bolt through hole ( 1S1) penetrates, and the inner diameter of the second bolt through hole 1S1 is formed to be larger than the outer diameter of the second bolt 61 provided in the second elastic member fixing means 6, so that the second bolt 61 flows while being fitted in the second bolt through hole 1S1. A third fixing plate 181 extending from the end of the base plate-side front extension 18 to the front of the base plate 1 is mounted at an end of the base plate-side front extension 18 in the form of a flat plate, , A fourth fixing plate 191 extending from the end of the base plate-side rear extension 19 to the rear of the base plate 1 in the form of a flat plate is mounted at the end of the base plate-side rear extension piece 19 . The third fixing plate 181 and the fourth fixing plate 191 have a second fixing plate so that the third fixing plate 181 and the fourth fixing plate 191 can be bolted to the ground or a structure or wall fixed on the ground. The bolt through hole 1S2 is penetrated.

The anti-vibration device-integrated seismic anchor bracket according to the present invention having such a structure reduces noise and vibration by absorbing or buffering the noise and vibration generated from the wall-mounted device in the middle when fixing the wall-mounted device that generates noise and vibration to the wall. It can be prevented from being transmitted to the wall.

In addition, the present invention can prevent an earthquake, vibration, or shock generated from external factors from being transmitted to the ground device when the ground device in which the mechanical structure or electrical and electronic devices are installed is installed on the ground or a structure on the ground.

In addition, according to the present invention, when the wall-type device is installed at a right angle to the vibration-proof device using the vibration-proof rubber, as the load of the wall-type device acts on the vibration-proof device for a long period of time, the vibration-proof rubber provided in the vibration-proof device is deflected. As a result, it is possible to solve the problem that the wall-type device is relaxed with the wall or the vibration-proof rubber provided in the vibration-proof device is sheared.

In addition, the present invention can prevent the vibration-proof rubber provided in the vibration-proof device from being easily sheared and destroyed by the horizontal seismic force when the self-supporting device is installed on the vibration-proof device using the vibration-proof rubber.

In addition, the present invention provides a first elastic member fitted between the first inclined surface and the third inclined surface and between the second inclined surface and the fourth inclined surface, and between the base plate-side front extension piece and the device fixing plate-side front extension piece. And, by installing the installation angle of the second elastic member sandwiched between the base plate-side rear extension piece and the device fixing plate-side rear extension piece at an inclination angle of 30 degrees to 80 degrees, the load of the wall-hanging device may be supported, It is also possible to resist by implementing the horizontal support force and the compressive force at the same time, and the height of the present invention may be reduced to a minimum.

1 is a perspective view of a first embodiment of the present invention;
2 is an exploded perspective view of a first embodiment of the present invention;
3 is an embodiment in which a wall fixing device such as a boiler is fixed to the first embodiment of the present invention fixed to the wall;
4 is a perspective view of a second embodiment of the present invention;
5 is an exploded perspective view of a second embodiment of the present invention;
6 is a view for explaining the bottom surface of the second embodiment of the present invention,
7 is a perspective view of a third embodiment of the present invention;
8 is an exploded perspective view of a third embodiment of the present invention;
9 is a view for explaining a bottom surface of a third embodiment of the present invention;
10 is a perspective view of a fourth embodiment of the present invention;
11 is an exploded perspective view of a fourth embodiment of the present invention;
12 is a view for explaining a bottom surface of a fourth embodiment of the present invention;
13a is a plan view of a fourth embodiment of the present invention;
Figure 13b is a cross-sectional view taken in the direction AA of Figure 13a,
14 is an embodiment in which a fourth embodiment of the present invention is installed at the four corners of the lower cubicle;
Figure 15 is an embodiment of a seismic anchor bracket of a conventional wall-type device.

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

As shown in Figures 1 to 2, the anti-vibration device-integrated seismic anchor bracket according to the present invention is fixed to the ground or a structure or wall fixed on the ground on both sides, the center is formed to protrude, and a pair of left and right about the center a base plate 1 on which the first inclined surface 11 and the second inclined surface 12 are symmetrically formed; It is disposed on the upper portion of the base plate 1 with a predetermined height interval therebetween, and a pair of third inclined surfaces 21 and fourth inclined surfaces 22 are symmetrically formed on both sides, and the ground surface or a device fixing plate (2) on which the device (B) to be fixed to a structure or wall fixed on the ground is fixedly installed; The first inclined surface 11 of the base plate 1, the third inclined surface 21 of the device fixing plate 2, and the second inclined surface 12 of the base plate 1 and the device fixing plate 2 ) a pair of first elastic members (3) each fitted between the fourth inclined surface (22); and a pair of the first elastic members 3 respectively on the first inclined surface 11 of the base plate 1 and the third inclined surface 21 of the device fixing plate 2 , and the base plate 1 , respectively. and a first elastic member fixing means (4) for fixing to the second inclined surface (12) of the device fixing plate (2) and the fourth inclined surface (22) of the device fixing plate (2), and vibration or impact is applied from the ground or the device fixing plate (2). When noise or vibration is generated from the device (B) fixedly installed in (2), a pair of first elastic members (3) mounted between the device fixing plate (2) and the base plate (1) are elastically contracted Buffers or absorbs vibrations, shocks, or noises while being restored or restored.

As shown in FIG. 2, the first elastic member fixing means 4 includes a first group consisting of a sequentially stacked first inclined surface 11, a first elastic member 3, and a third inclined surface 21; , a first bolt 41 through-coupled to a second group consisting of a second inclined surface 12, a first elastic member 3, and a fourth inclined surface 22; A first upper nut 42 fastened to the screw portion of the first bolt 41 exposed to the upper portion of the device fixing plate 2 so that the device fixing plate 2 does not come off from the first bolt 41 , include

The first bolt 41 is a threaded bolt, and the first lower nut 43 is fastened to the threaded portion of the threaded bolt exposed to the lower part of the base plate 1 so that the base plate 1 is not separated from the threaded bolt. make sure not to

A first long hole 23 is penetrated through the third inclined surface 21 and the fourth inclined surface 22 of the device fixing plate 2, and the first elastic member fixing means 4 is provided in the first long hole 23. The first bolt 41 provided in the is fitted, and one end of the first long hole 23 is opened.

The first bolt through hole 13 is inserted into the first inclined surface 11 and the second inclined surface 12 of the base plate 1 so that the first bolt 41 provided in the first elastic member fixing means 4 is fitted. ) through, the inner diameter of the first bolt through hole 13 is formed to be larger than the outer diameter of the first bolt 41 provided in the first elastic member fixing means 4, so that the first bolt 41 is It may flow while being fitted in the first bolt through hole 13 .

As shown in Figure 2, the base plate (1) includes an upper spacer plate (14) arranged in a plate shape in parallel to the ground or wall on which the base plate (1) is installed; a first inclined surface 11 bent from the left end of the upper separation plate 14 toward the ground or wall on which the base plate 1 is installed; a second inclined surface 12 bent from the right end of the upper separation plate 14 toward the ground or wall on which the base plate 1 is installed; a first fixing plate 15 extending from the end of the first inclined surface 11 in the opposite direction of the upper separation plate 14 and fixedly installed on the ground or wall where the base plate 1 is installed; and a second fixing plate 16 that extends from the end of the second inclined surface 12 in the opposite direction of the upper separation plate 14 and is fixedly installed on the ground or wall on which the base plate 1 is installed.

A first fixing bolt passes through the first fixing plate 15 and the second fixing plate 16 so that the first fixing plate 15 and the second fixing plate 16 can be bolted to the ground or a structure or wall fixed on the ground. A hole 17 is penetrated.

Figure 3 is an embodiment in which a wall fixing device (B) such as a boiler is fixed to the first embodiment of the present invention fixed to the wall.

4 and 5, the front center of the base plate 1 protrudes forward of the base plate 1 to increase shear resistance, and the base plate 1 and the device fixing plate 2 ), a front extension piece 18 inclined at 30 to 80 degrees relative to the horizontal plane is mounted to minimize the height space of the base plate, and the rear center of the base plate 1 protrudes backward of the base plate 1 . However, in order to increase the shear resistance and minimize the height space between the base plate 1 and the device fixing plate 2, it is symmetrical with the base plate side front extension piece 18 around the center of the base plate 1 A rear extension piece 19 on the side of the base plate formed in a manner is mounted.

In addition, at the front center of the device fixing plate 2, it protrudes forward of the device fixing plate 2 to increase the shear resistance and minimize the height space between the base plate 1 and the device fixing plate 2 A front extension piece 24 on the side of the device fixing plate inclined at 30 to 80 degrees relative to the horizontal plane is mounted in the rear center of the device fixing plate 2 to protrude to the rear of the device fixing plate 2 to increase the shear resistance. To increase and minimize the height space between the base plate 1 and the device fixing plate 2, symmetrically with the device fixing plate side front extension 24 around the center of the device fixing plate 2 The formed device fixing plate side rear extension piece 25 is mounted.

Further, between the base plate side front extension piece 18 and the device fixing plate side front extension piece 24, and between the base plate side rear extension piece 19 and the device fixing plate side rear extension piece 25 A second elastic member 5 is sandwiched between It is fixed between the front extension pieces 24 and between the base plate side rear extension pieces 19 and the device fixing plate side rear extension pieces 25, respectively.

As shown in FIG. 5, the second elastic member fixing means 6 includes the base plate-side front extension piece 18, the second elastic member 5 and the device fixing plate-side front extension piece stacked sequentially. A third group consisting of (24), and a fourth group consisting of the base plate side rear extension piece (19), the second elastic member (5), and the device fixing plate side rear extension piece (25) through-coupled 2 bolts 61 and; and a second upper nut 62 fastened to the screw portion of the second bolt 61 exposed to the upper portion of the device fixing plate-side front extension 24 and the device fixing plate-side rear extension 25 .

As shown in Figure 6, the second bolt 61 is a threaded part of the threaded bolt exposed to the lower part of the base plate-side front extension piece 18 and the base plate-side rear extension piece 19 as a threaded bolt. 2 The lower nut 63 is fastened.

As shown in FIG. 5, a second long hole 26 is penetrated through the device fixing plate-side front extension 24 and the device fixing plate-side rear extension 25, and the second long hole 26 has A second bolt 61 provided in the second elastic member fixing means 6 is fitted, and one end of the second long hole 26 is opened.

A second bolt through hole ( 1S1) penetrates, and the inner diameter of the second bolt through hole 1S1 is formed to be larger than the outer diameter of the second bolt 61 provided in the second elastic member fixing means 6, so that the second bolt 61 flows while being inserted into the second bolt through hole 1S1.

At the end of the base plate-side front extension piece 18, as shown in FIGS. 7 to 8, in the form of a flat plate, from the end of the base plate-side front extension piece 18 to the front of the base plate 1 An extended third fixing plate 181 is mounted, and at the end of the base plate side rear extension piece 19, as shown in FIG. 8, from the end of the base plate side rear extension piece 19 in the form of a flat plate. A fourth fixing plate 191 extended to the rear of the base plate 1 is mounted.

A second fixing bolt passes through the third fixing plate 181 and the fourth fixing plate 191 so that the third fixing plate 181 and the fourth fixing plate 191 can be bolted to the ground or a structure or wall fixed on the ground. A hole 1S2 is penetrated.

As shown in FIGS. 10 to 13B, a first bush insertion hole BH1 is penetrated through the center of the base plate 1 so that the bush 7 is inserted, and the upper surface of the first bush insertion hole BH1 has an upper surface. and a bush 7 with an open bottom is fitted, and a shaft 8 that is inserted into the bush 7 and ascends and descends through the open top of the bush 7 is mounted inside the bush 7 , the upper surface of the shaft (8) is fixed to the center of the lower surface of the device fixing plate (2) and moves along the device fixing plate (2).

The bush 7 may be configured as a ball bush in which a rolling ball is mounted.

The bush 7 is accommodated in the lower part of the base plate 1 and the bush housing 9 having an upper surface fixed to the lower surface of the base plate 1 is mounted.

A second bush insertion hole BH2 passes through the center of the upper surface of the bush housing 9 so that the bush 7 is inserted, and the lower edge of the bush 7 extends over the inner circumferential surface of the second bush insertion hole BH2. The annular jaw 95 is machined to be fixed.

The shaft 8 and the bush 7 equipped in the present invention are installed to resist shearing due to seismic force.

In the center of the shaft 8, as shown in FIGS. 10 to 13b, a fixing bar F protruding from the shaft 8 in the upper direction of the shaft 8 is mounted, and the device fixing plate 2 ), a fixing bar passing hole (H) passes through the center of the fixing bar (F), and the fixing bar (F) exposed to the upper portion of the device fixing plate (2) has the ground or a structure or wall fixed on the ground. The device (B) to be fixed is mounted on the .

14 is an embodiment in which the fourth embodiment of the present invention is installed at the four corners of the lower cubicle.

The anti-vibration device-integrated seismic anchor bracket according to the present invention having such a structure reduces noise and vibration by absorbing or buffering the noise and vibration generated from the wall-mounted device in the middle when fixing the wall-mounted device that generates noise and vibration to the wall. It can be prevented from being transmitted to the wall.

In addition, the present invention can prevent an earthquake, vibration, or shock generated from external factors from being transmitted to the ground device when the ground device in which the mechanical structure or electrical and electronic devices are installed is installed on the ground or a structure on the ground.

In addition, the present invention includes a first elastic member 3 sandwiched between the first inclined surface 11 and the third inclined surface 21 and between the second inclined surface 12 and the fourth inclined surface 22, The product is inserted between the base plate side front extension piece 18 and the device fixing plate side front extension piece 24, and between the base plate side rear extension piece 19 and the device fixing plate side rear extension piece 25. 2 By installing the installation angle of the elastic member 5 at an inclination angle of 30 degrees to 80 degrees, the load of the wall hanging device can be supported, and the horizontal support force and the compressive force can be implemented at the same time to resist it, and to increase the height of the present invention. It can also be lowered to a minimum.

1. Base plate 11. First inclined plane
12. Second inclined surface 13. First bolt through hole
14. Upper Separator BH1. 1st bush insertion hole
15. First fixing plate
16. Second fixing plate 17. First fixing bolt through hole
18. Base plate side front extension 181. Third fixing plate
19. Base plate side rear extension 191. Fourth fixing plate
1S1. 2nd bolt through hole 1S2. 2nd fixing bolt through hole
2. Instrument fixing plate 21. Third inclined plane
22. 4th slope 23. 1st long hole
24. Front extension on the device fixing plate side
25. Rear extension on the device fixing plate side
26. Second long hole 3. First elastic member
4. First elastic member fixing means 41. First bolt
42. First upper nut 43. First lower nut
5. Second elastic member 6. Second elastic member fixing means
61. Second bolt 62. Second upper nut
63. 2nd lower nut 7. Bush
8. Shaft 9. Bush Housing
BH2. 2nd bush insertion hole 93. Lower plate
931. Shaft through hole 95. Annular jaw

Claims (7)

A base plate (1) having both sides fixed to the ground or a structure or wall fixed on the ground, a center protruding, and a pair of first and second inclined surfaces (11) and second inclined surfaces (12) symmetrically formed on the left and right around the center )Wow;
It is disposed on the upper portion of the base plate 1 with a predetermined height interval therebetween, and a pair of third inclined surfaces 21 and fourth inclined surfaces 22 are symmetrically formed on both sides, and the ground surface or a device fixing plate (2) on which the device (B) to be fixed to a structure or wall fixed on the ground is fixedly installed;
The first inclined surface 11 of the base plate 1, the third inclined surface 21 of the device fixing plate 2, and the second inclined surface 12 of the base plate 1 and the device fixing plate 2 ) a pair of first elastic members (3) each fitted between the fourth inclined surface (22);
and a pair of the first elastic members 3 respectively on the first inclined surface 11 of the base plate 1 and the third inclined surface 21 of the device fixing plate 2 , and the base plate 1 , respectively. and a first elastic member fixing means (4) for fixing to the second inclined surface (12) of the and the fourth inclined surface (22) of the device fixing plate (2),
When vibration or shock is applied from the ground or noise or vibration is generated from the device B fixedly installed on the device fixing plate 2, a pair mounted between the device fixing plate 2 and the base plate 1 Anti-vibration device-integrated seismic anchor bracket for buffering or absorbing vibration, shock or noise while the first elastic member 3 of the elastically contracted or restored.
The method of claim 1,
A first long hole 23 is penetrated through the third inclined surface 21 and the fourth inclined surface 22 of the device fixing plate 2,
A first bolt 41 provided in the first elastic member fixing means 4 is fitted into the first long hole 23,
One end of the first long hole 23 is an anti-vibration device-integrated earthquake-resistant anchor bracket, characterized in that it is open.
The method of claim 1,
The first bolt through hole 13 is inserted into the first inclined surface 11 and the second inclined surface 12 of the base plate 1 so that the first bolt 41 provided in the first elastic member fixing means 4 is fitted. ) is penetrated,
The inner diameter of the first bolt through hole 13 is formed to be larger than the outer diameter of the first bolt 41 provided in the first elastic member fixing means 4 , so that the first bolt 41 passes through the first bolt Anti-vibration device-integrated seismic anchor bracket, characterized in that it flows while being fitted in the hole (13).
The method of claim 1,
The front center of the base plate 1 protrudes forward of the base plate 1 to increase the shear resistance and to minimize the height space between the base plate 1 and the device fixing plate 2 compared to a horizontal plane of 30 The base plate side front extension piece 18 inclined at 80 degrees is mounted,
In the center of the rear surface of the base plate 1, the base plate protrudes to the rear of the base plate 1 to increase shear resistance and minimize the height space between the base plate 1 and the device fixing plate 2 A base plate-side rear extension 19 formed symmetrically with the base plate-side front extension 18 is mounted around the center of (1),
At the center of the front of the device fixing plate (2), it protrudes forward of the device fixing plate (2) to increase the shear resistance and to minimize the height space between the base plate (1) and the device fixing plate (2). The front extension piece 24 on the side of the device fixing plate inclined at 30 degrees to 80 degrees in contrast is mounted,
At the rear center of the device fixing plate 2, it protrudes backward of the device fixing plate 2 to increase shear resistance and minimize the height space between the base plate 1 and the device fixing plate 2 A device fixing plate side rear extension 25 formed symmetrically with the device fixing plate side front extension 24 is mounted around the center of the device fixing plate 2,
Between the base plate side front extension piece 18 and the device fixing plate side front extension piece 24, and between the base plate side rear extension piece 19 and the device fixing plate side rear extension piece 25 The second elastic member (5) is fitted,
The second elastic member 5 is disposed between the base plate side front extension piece 18 and the device fixing plate side front extension piece 24 by means of a second elastic member fixing means 6 and on the base plate side. Anti-vibration device-integrated seismic anchor bracket, characterized in that it is respectively fixed between the rear extension piece (19) and the rear extension piece (25) on the device fixing plate side.
5. The method of claim 4,
A second long hole 26 is penetrated through the device fixing plate-side front extension 24 and the device fixing plate-side rear extension 25,
A second bolt 61 provided in the second elastic member fixing means 6 is fitted into the second long hole 26,
One end of the second long hole (26) is an anti-vibration device-integrated earthquake-resistant anchor bracket, characterized in that it is open.
5. The method of claim 4,
A second bolt through hole ( 1S1) is penetrated,
The inner diameter of the second bolt passing hole 1S1 is formed to be larger than the outer diameter of the second bolt 61 provided in the second elastic member fixing means 6 so that the second bolt 61 passes through the second bolt Anti-vibration device-integrated seismic anchor bracket, characterized in that it flows while being fitted in the hole (1S1).
5. The method of claim 4,
A third fixing plate 181 extending from the end of the base plate-side front extension 18 to the front of the base plate 1 is mounted at an end of the base plate-side front extension 18 in the form of a flat plate, ,
A fourth fixing plate 191 extending from the end of the base plate-side rear extension 19 to the rear of the base plate 1 in the form of a flat plate is mounted at the end of the base plate-side rear extension piece 19, ,
A second fixing bolt passes through the third fixing plate 181 and the fourth fixing plate 191 so that the third fixing plate 181 and the fourth fixing plate 191 can be bolted to the ground or a structure or wall fixed on the ground. The anti-vibration device-integrated seismic anchor bracket, characterized in that the hole (1S2) is penetrated.

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