KR101806492B1 - Earthquake-proof safety soundproof wall for and, method for constructing this same - Google Patents

Abstract

The present invention relates to a seismic reinforcing secure soundproofing facility (a soundproof wall, a soundproof tunnel, etc.) and a construction method thereof; and aims to safely protect soundproofing facilities such as soundproof walls and soundproof tunnels by absorbing vibrations transmitted from the ground by reducing a shaking of pillars and soundproof plates during movement of the ground caused by an earthquake by increasing a composite force between the pillar and the soundproof plate. A seismic reinforcing secure soundproofing facility in accordance with the present invention comprises: a plurality of pillars (10); a soundproof plate (20); a soundproof plate fixed angle (30); a seismic adjustment box (60); and first and second seismic reinforcing steel bars (40, 50).

Description

FIELD OF THE INVENTION [0001] The present invention relates to a soundproof reinforcement safety soundproofing facility and an earthquake-

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a soundproofing facility such as a soundproof wall and a soundproofing tunnel, and more particularly, to an earthquake-proofing and soundproofing facility for protecting a soundproofing facility from the earthquake caused by an earthquake.

Generally, soundproofing (soundproof walls, soundproof tunnels) are installed as a means to protect and improve the living environment of the residents around the roads where noise due to the vehicle operation occurs, or noise sources such as construction sites or factories.

These soundproofing facilities are usually H-beams or I-beams installed on a concrete foundation with a soundproof plate (a sound-absorbing type with a sound absorbing material, a sound insulation type of a transparent plate) The walls are formed with a certain area by the joining structure which is sequentially stacked in the longitudinal direction so that both side ends are supported by the same steel pillar.

In the soundproofing system according to the related art, it is general to install the soundproofing plate on the support by attaching the soundproofing plate to the support through the bracket. According to such an installation structure, when an external force is applied to the support, The soundproof plate and the support are not fixed to each other, but the soundproof plate is only adhered to the support by the bracket. Therefore, when the support is collapsed, the soundproof plate is separated from the support when it goes out from the minimum installation position. There is a problem that a secondary accident such as a soundproof plate bounces on the vehicle or bounces on the surrounding residence.

Patent Document 10-1359395 discloses a structure in which a first flange and a second flange facing each other are formed and a soundproof panel is fixed to an H-shaped steel support having a web connecting the first flange and the second flange to each other A soundproof panel fixing apparatus for a soundproof panel, comprising: a base frame for pressing a vertical side surface of the soundproof panel to the first flange; A boss formed integrally in a central portion of the upper surface of the base frame in a direction perpendicular to the base frame and having a hollow portion on an inner circumferential surface thereof, a slot having a vertical direction in a vertical direction and a male screw on an outer circumferential surface; A pressing rod having one side inserted axially into the hollow portion of the boss, a fastening hole formed vertically and vertically, and a pressure plate pressed against the second flange at the other side; A fastening pin vertically penetrating the fastening hole of the boss and the pressing rod to fasten the boss and the pressing rod; And a press nut formed on the left side of the long hole of the boss and screwed to the outer circumferential surface of the boss to press the upper and lower portions of the fastening pin to the right to tightly press the pressing rod and the pressing plate against the second flange, , The soundproof panel is brought into close contact with the support, and when the earthquake is caused by the earthquake, the connection between the support and the soundproof plate is broken and the soundproof wall is collapsed.

Patent No. 10-1359395

The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide an anti-seismic safety soundproofing facility for absorbing vibrations transmitted from the ground by reducing the shaking of the support pillars and soundproofing plates, The purpose of this project is to provide a construction method.

An anti-seismic safety soundproofing facility according to the present invention comprises: a plurality of columns; A soundproof plate installed at one or more stages between the struts; A soundproof plate fixed angle fixed to the strut and fixing the sound insulation plate to one side web of the strut; An earthquake-proof control box installed on the sound insulation plate via a fixing bracket installed at a center of one side of the sound insulation plate; One side of which is fixed to the other web of the strut or the fixed angle of the soundproof plate and the other side of which is connected to the seismic control box via a strut connecting means, A first and a second internal adjustment nuts screwed into the outer circumferential surfaces of the first and second internal progressive steel rods penetrating into the box body, 2 built-in adjusting nut and first and second built-in coil springs interposed between the box body and buffering an impact due to an earthquake.

An anti-seismic safety soundproofing facility according to the present invention comprises: a plurality of columns; A soundproof plate installed at one or more stages between the struts; A soundproof plate fixed angle fixed to the strut and fixing the sound insulation plate to one side web of the strut; The first and second bolts are screwed to the opposite ends of the first and second bolts, respectively. The first and second bolts are screwed to the opposite ends of the first and second bolts. And a stretch-type seismic strengthening means comprising a nut body for stretching and contracting the first and second bolt bodies, and a fixing bracket fixed to the sound insulation plate and supporting the nut body.

According to the seismic reinforcing safety soundproofing facility and its construction method according to the present invention, in addition to the conventional fixing method of the support and the soundproofing plate, the support and the soundproofing plate are connected to each other so that the support and the soundproofing plate are integrally combined, The soundproofing facility is protected because the shaking of the soundproofing facility is small. In addition, since both the support and the soundproofing plate can be tightly bound and adjusted in both Embodiment 1 (Seismic Control Box) and Embodiment 2 And it is effective to protect the soundproofing facility more safely by reducing the vibration of the support and the soundproofing plate due to the earthquake through the buffering means (buffer ring, buffer pad).

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a plan view of an anti-seismic safety soundproofing facility according to Embodiment 1 of the present invention; FIG.
2 is a perspective view of an anti-seismic adjustment box and a first and second anti-vibration steel rod assembly applied to a seismic-strengthening safety soundproofing system according to Embodiment 1 of the present invention.
3 is a plan view of an anti-seismic safety soundproofing facility according to Embodiment 2 of the present invention.
4 is a perspective view of an anti-seismic safety soundproofing facility according to Embodiment 2 of the present invention.
5 is a perspective view of a stretch type seismic strengthening means applied to an anti-seismic safety soundproofing facility according to Embodiment 2 of the present invention.

≪ Example 1 >

As shown in FIGS. 1 and 2, the anti-seismic safety soundproofing facility according to the present embodiment includes a support 10 erected on the ground, a soundproofing plate 20 installed between the support posts 10, A first and a second inner reinforcing steel rods 40 and 50 connected to the adjacent support pillars 10 (or the soundproof plate fixing angles) via the pillars connecting means, the soundproof plate fixing angles 30, And an earthquake-proof adjustment box 60 to which the other end of the first and second endurance-progressive steel rods 40 and 50, which are installed via a fixing bracket 70, is connected to one side (preferably a rear side)

The strut 10 is constituted by H beams (first and second webs 11 and 12 and a connecting portion 13 connecting them) which are commonly used as a structure having a groove into which the edge of the soundproofing plate 20 is inserted on one side or both sides ] Means all structures having grooves without being limited thereto, and of course, they are constructed with a certain distance from each other along the periphery of a road or a jar, and the bottom is inserted into the ground and then fixed by a mortar or the like or anchored to the ground It is fixed and installed through the base plate.

The post 10 is not limited to the H beam, but it is also possible that the first and second webs 11 and 12 are short and the connecting part 13 is long.

The soundproofing plate 20 can prevent noise transmitted from the roadside from being transmitted to the opposite side of the road, and can be both a soundproofing type (such as a transparent plate) and a sound absorption type (a sound absorbing material is embedded in the case) The edge portions of both sides are inserted and installed in the groove of the support 10.

The soundproof plate fixing angle 30 is bent at a right angle and one side is fixed to the support 10 by a fastening hole 31 (bolt and nut) and the other side is fixed by fixing the soundproofing plate 20 to the first web of the support .

The soundproof plate fixing angles 30 are provided on both left and right sides of the connecting portion 13 of the struts 10 and may be installed on the struts 10 through one fastener 31.

The first and second endurance steel bars 40 and 50 are respectively disposed on the left and right sides of the earthquake-proof adjustment box 60 and are connected to adjacent struts 10.

Therefore, all of the pillars 10 are connected in series through the first and second endurance steel bars 40 and 50, so that the pillars 10 and the soundproofing plates 20 are integrally combined. As a result, It will reduce the collapse of soundproofing because it will exert a large supporting force.

Each of the first and second endurance steel bars 40 and 50 is connected to the second web 12 of the column 10 via a column connecting means, The heads 41 and 51 and the heads 41 and 51 and the second webs 12 and 12 of the struts 10 are formed on one side (supporting side) of the support 10 and the second web 12 of the support 10, , One or more buffer rings (43, 53) coupled to the peripheries of the bolt-type connectors (42, 52) and buffering shocks transferred to the heads (41, 51) And cushioning pads 44 and 54 installed inside the heads 41 and 51 to cushion shocks transferred to the heads 41 and 51.

The sockets 41 and 51 are supported on both the front and rear surfaces of the second web 12 so as to surround the second web 12. The sockets 41 and 51 are welded to the first and second endbreaking steels 40 and 50, And can be fixed by screw fastening through the structure.

The socket 41 or 51 may have a circular hole through which the bolt-type connectors 42 and 52 pass, and may have a long elongated hole or bolt-type connectors 42 and 52 It is possible to use a hole having an inner diameter larger than the outer diameter.

The bolt-type connectors 42 and 52 are composed of the sockets 41 and 51, the bolts passing through the second web 12 inserted in the sockets 41 and 51, and the nuts fastened at the opposite sides of the bolts.

The cushioning rings 43 and 53 are fitted in the circumferential portion of the bolt of the bolt-type connectors 42 and 52 and preferably between the front and rear walls of the sockets 41 and 51 and the second web 12 inserted therebetween So as to buffer the forward and backward impact transferred from the column 10, respectively.

The buffer pads 44 and 54 are mounted on the inner surfaces of the sockets 41 and 51 so that the ends of the second web 12 are supported and buffer shocks in the lateral direction transferred from the pillars 10 are absorbed.

The other end of the first and second endurance steel bars 40 and 50 is connected to the seismic adjustment box 60, and the threads 45 and 55 are formed on the outer circumferential surface thereof.

The thread lines 45 and 55 of the first and second endurance steel bars 40 and 50 are formed to have a length sufficient to allow for the expansion and contraction of the first and second endurance steel bars 40 and 50, Respectively.

The earthquake-proof adjustment box 60 includes a box body 61 having a space formed therein and hinged to one side of the fixed bracket 70, first and second inner steel reinforcing bars 40 and 50 The first and second built-in adjusting nuts 62 and 63 and the box body 61, which are screwed to the threads 45 and 55 of the box body 61, And first and second built-in coil springs 64 and 65 for absorbing impact.

The first and second built-in coil springs 64 and 65 are elastically deformed by an external force to protect the soundproofing plate 20 by buffering shocks transferred from the first and second endurance resilient steel rods 40 and 50, So that the soundproof plate 20 can be protected.

The first and second built-in adjusting nuts 62 and 63 function to adjust the elastic force of the first and second built-in coil springs 64 and 65. Particularly, the first and second built-in adjusting nuts 62 and 63 adjust the elastic force of the first and second built-in coil springs 64 and 65, respectively, .

In addition, the first and second external coil springs 66 (see FIG. 1) which are fitted to the first and second internal strengthening steel rods 40 and 50 from the outside of the earthquake-proof adjustment box 60 and are supported on the outer surface of the earthquake- 67, and first and second external adjusting springs 68, 69 for adjusting the elastic force of the first and second external coil springs 66, 67.

The box body 61 of the earthquake-proof adjustment box 60 is formed integrally with the sound insulation plate 20 by being fixed to the stationary bracket 70 via a fastener,

The fixing bracket 70 covers both the left and right sides of the connection portion of the seismic control box 60. For example, two bent pieces bent at right angles are fixed to the sound insulation plate 20 through bolting or the like, do.

Further, the present invention is applied to a warning light 60-1 to know when the behavior of a soundproofing facility is large due to a high-intensity earthquake.

The switch 60-2 is connected to the first and second built-in control nuts 62 and 63. The switch 60-2 is powered by the on- That is, when the first and second built-in adjustment nuts 62 and 63 move to the switch 60-2, the beacon light 60-1 operates.

The construction method of the seismic reinforced safety soundproofing facility according to the present embodiment is as follows.

1. Installation of the holding.

A plurality of pillars (10) are installed at a distance from each other along the road side.

2. Install soundproofing board.

The soundproof plate 20 is stacked by one or more stages between adjacent pillars 10 and the soundproof plate 20 is supported by the soundproof plate fixing angle 30 while the soundproof plate fixing angle 30 is fixed to the support 10 10).

3. Installation of seismic reinforcement means.

The fixing bracket (70) is installed on the soundproofing plate (20).

An earthquake-proof adjustment box (60) is provided on the fixing bracket (70).

One side of the first and second endurance steel bars 40 and 50 is installed on the adjacent struts 10 through the support connection means while the other side is inserted into the seismic adjustment box 60 and the first and second built- 64 and 65 and the first and second built-in adjustment nuts 62 and 63 are installed to complete the construction of the soundproofing facility. The first and second external coil springs 66 and 67 and the first and second external adjustment nuts 68 and 69 are also installed.

≪ Example 2 >

3 to 5, the support 10, the soundproofing plate 20, and the soundproofing plate fixing angle 30 are the same as those of the first embodiment, and the reinforced seismic reinforcement The means 80 differs from the first embodiment.

The stretch type seismic strengthening means 80 is fixed to the pillars 10 (or the soundproof plate fixing angles 30) on both sides of the left and right sides through the column connecting means 83 and 84, A nut body 85 which is screwed to the opposite end of the first and second bolt bodies 81 and 82 to expand and contract the first and second bolt bodies 81 and 82, And a fixing bracket 70 which is fixed to the main body 20 and supports the nut body 85.

The nut body 85 includes a support bar 86 extending from the periphery and fixed to the fixing bracket 70 through a fastener.

In the present embodiment, the first and second bolt bodies 81 and 82 are expanded or contracted by bi-directional rotation of the nut member 85, and the support bar 86 also functions as a handle.

The fixing bracket 70 is formed in a curved shape conforming to the rotation locus of the support bar 86 of the nut body 85 so that the support bar 86 can rotate in the fixing bracket 70 when the nut body 85 rotates And a guide slot 71. The fixing bracket 70 is the same as the fixing bracket 70 of the first embodiment except for the guide slot 71.

The pillar connecting means 83 and 84 are constituted of the same structure as that of the pillar connecting means of the first embodiment, that is, a socket, a bolt-type connector, a buffer ring and a buffer pad.

The installation method of the seismic reinforcing safety soundproofing facility according to the present embodiment includes a step of installing a pillar installation-a soundproof plate-installing a stretchable seismic strengthening means, One side of each of the first and second bolts 81 and 82 is provided to the adjacent struts 10 through the connecting means 83 and 84 and the nut member connected to the opposite end of the first and second bolts 81 and 82 85 by fixing the support rod 86 to the fixing bracket 70.

10: column, 20: soundproofing plate
30: Soundproof plate fixed angle, 40,50: 1st and 2nd advanced steel bars
41, 51: socket, 42, 52:
43, 53: cushion ring, 44, 54: cushion pad
45,55: thread, 60: seismic control box
61: box body, 62, 63: first and second built-
64, 65: first and second built-in coil springs,
66, 67: first and second external coil springs,
68, 69: first and second external adjustment nuts,
70: Fixing bracket, 80: Retractable type Seismic strengthening means
81, 82: first and second bolt bodies, 83, 84:
85: nut body, 86: support rod

Claims (9)

A plurality of struts which are erected at a distance from each other;
A soundproof plate installed at one or more stages between the struts;
A soundproof plate fixed angle fixed to the strut and fixing the sound insulation plate to one side web of the strut;
An earthquake-proof control box installed on the sound insulation plate via a fixing bracket installed at a center of one side of the sound insulation plate;
One side of which is fixed to the other side web of the strut or the soundproof plate fixing angle and the other side of which is connected to the seismic control box via the strut connecting means,
Wherein the seismic adjustment box comprises a box body having a space formed therein and one end thereof hinged to the fixing bracket, a first and a second built-in adjustable screw that is screwed to an outer circumferential surface of the first and second inner- A first and a second built-in coil springs interposed between the first and second built-in adjusting nuts and the box body to buffer an impact due to an earthquake, a movement path of the first and second built- A first external coil spring installed outside the box body and a second external coil spring connected to the first and second internal steel reinforcing bars outside the box body, And first and second external adjustment nuts connected to the first and second internal strengthening bars to adjust an elastic force of the first and second external coil springs. Installed. delete [Claim 2] The apparatus according to claim 1, wherein the strut connecting means comprises: a head formed on one side of the first and second endurance steel bars and surrounding the other side web of the strut; a bolt type connecting hole for fastening to the other side web of the strut; And a shock absorbing ring coupled to a periphery of the connector and cushioning an impact transferred to the head, and a cushioning pad installed inside the head to cushion an impact transferred to the head. . delete A plurality of struts which are erected at a distance from each other;
A soundproof plate installed at one or more stages between the struts;
A soundproof plate fixed angle fixed to the strut and fixing the sound insulation plate to one side web of the strut;
The first and second bolts are screwed to the opposite ends of the first and second bolts, respectively. The first and second bolts are screwed to the opposite ends of the first and second bolts. And a stretch type seismic strengthening means comprising a nut body for stretching and contracting the first and second bolt bodies, and a fixing bracket fixed to the sound insulation plate and supporting the nut body,
Wherein the nut body includes a support rod extending from the periphery of the nut body, and the fixing bracket includes a curved guide slot adapted to a rotation locus of the support rod of the nut body, Which is capable of controlling the expansion and contraction of the body. delete [Claim 6] The method of claim 5, wherein the strut connecting means comprises: a head formed on one side of the first and second bolts and surrounding the other side web of the strut; a bolt type connecting hole that is fastened to the other side web of the strut; And a shock absorbing ring coupled to a periphery of the connector and cushioning an impact transferred to the head, and a shock absorbing pad installed inside the head to absorb an impact transferred to the head. A method of installing an anti-seismic safety soundproofing facility according to claim 1,
A first step of installing a plurality of struts at a predetermined distance from each other;
A second step of stacking the sound insulation plates in one or more stages between the struts;
A third step of fixing the soundproof plate to the strut by the soundproof plate fixing angle while fixing the soundproof plate fixed angle to the strut;
And the other end of the first and second endurance-strengthening rods is installed on the adjacent support through the support connection means, while the other end is installed on the seismic adjustment box And a fourth step of,
Wherein the seismic adjustment box comprises a box body having a space formed therein and one end thereof hinged to the fixing bracket, a first and a second built-in adjustable screw that is screwed to an outer circumferential surface of the first and second inner- A first and a second built-in coil springs interposed between the first and second built-in adjusting nuts and the box body to buffer an impact due to an earthquake, a movement path of the first and second built- A first external coil spring installed outside the box body and a second external coil spring connected to the first and second internal steel reinforcing bars outside the box body, And a fourth step of adjusting the elastic force of the first and second external coil springs and the first and second external adjustment nuts coupled to the first and second anti- Gene construction method of reinforcing safety soundproofing. A method of installing an anti-seismic safety soundproofing facility according to claim 5,
A first step of installing a plurality of struts at a predetermined distance from each other;
A second step of stacking the sound insulation plates in one or more stages between the struts;
A third step of fixing the soundproof plate to the strut by the soundproof plate fixing angle while fixing the soundproof plate fixed angle to the strut;
Wherein the first and second bolt bodies of the expansion and contraction type seismic strengthening means are connected to the adjacent support pillars via the pillar connection means by installing a fixing bracket on the soundproofing plate and by installing a telescopic type seismic strengthening means on the pillars and the fixing bracket, And a fourth step of securing and installing a nut body connected to an opposite end of the first and second bolts to the fixing bracket, respectively.

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