KR101721887B1 - Soundproof wall structure for tunnel - Google Patents

Abstract

The present invention relates to a soundproof wall structure for a tunnel, which comprises: a frame in which a space is formed by a longitudinal frame and a transverse frame; a sound absorbing material inserted into the frame; an external finishing plate formed in a tunnel external direction in the frame, wherein a plurality of pressure emitting holes are formed; and an alleviation fiber plate formed in a tunnel internal direction in the frame, and having a pair of weaving fiber plates forming a clearance and clearance fiber having a twisted shape to form a clearance between the weaving fiber plates.

Description

BACKGROUND OF THE INVENTION Field of the Invention [0001] The present invention relates to a soundproof wall structure,

The present invention relates to a sound barrier structure in which explosion is minimized when a tunnel is blown up, durability is enhanced by multiple sound-absorbing structures, and sound-absorbing functions are doubled.

Generally, a tunnel is a passage formed through an obstacle such as a mountain by constructing a road or a railroad so that it can pass through a straight line in a short time without bypassing a mountain or a hill. Thus, in order to construct the tunnel, it is essential to perform blasting work using explosives.

Here, the tunnel blasting is performed by filling the explosive in a plurality of charge holes perforated on the free surface of the tunnel, and then digging the tunnel in a chain explosion manner, so that the explosive sound and explosion pressure generated when the explosive is blasted are discharged to the outside In addition, explosive sounds, explosive pressure, and monumental rocks cause noise pollution and dust pollution around the construction site, and in particular, people around the tunnel construction site , And livestock.

For example, Korean Patent Registration No. 0401809 discloses a soundproof explosion-proof device for a tunnel installed in a tunnel, wherein the tunnel soundproof explosion-proof device comprises: A front grating plate and a rear grating plate which are installed in the tunnel to block the tunnel and have an opening and an opening and are formed in a lattice structure and are spaced apart from each other in parallel to each other and a front grating plate and a rear grating plate which are respectively disposed in the gratings between the front grating plate and the rear grating plate, A blocking wall having a first soundproofing member mutually isolated by a connecting portion interconnecting the grating plates; A first soundproofing material separation preventing member on the mesh that blocks the respective lattice openings of the front lattice plate and the rear lattice plate; And a door opening and closing the opening and closing part and provided with a second soundproofing member.

However, even in the case of the above-mentioned technique, there is a problem that the load due to the storm pressure and the zeolite generated during the explosion can not be sufficiently mitigated, and the durability is lowered, and the explosion sound can not be sufficiently absorbed.

Korea Patent No. 0401809

SUMMARY OF THE INVENTION The present invention has been made in order to solve the problems of the conventional art as described above, and it is an object of the present invention to provide a tunnel capable of sounding explosive sounds by mitigating load caused by explosion pressure, It is intended to provide a soundproofing structure.

A tunnel soundproof wall structure of the present invention comprises: a frame for forming a space therein by a longitudinal frame and a transverse frame; A sound absorbing material embedded in the frame; An outer finishing plate formed on the frame in an outer direction of the tunnel and having a plurality of pressure sink holes; And a relaxed fiberboard comprising a pair of woven fiber boards formed in the tunnel inner direction of the frame and forming a gap and spaced apart fibers twisted to form a gap between the woven fiber boards between the woven fiber boards.

As one example, the mitigation fiberboard is disposed on a pair of perforated plates formed with perforations, wherein a pair of perforated plates and a mitigated fiberboard plate are fixed by a fastening channel attached to the frame, and the perforated plate positioned outwardly of the frame is fastened And is fixed.

As one example, the transverse frame is characterized in that two or more transverse frame units are made of an elastic material and the receiving part is formed in a groove shape on both sides, and each transverse frame unit is connected to the receiving part by a cut- .

For example, in the outer finishing plate, the pressure diverging hole may include a plurality of flow holes formed in the transverse direction of the outer finishing plate, an elastic material which is tightened at the upper end of the flow hole and is opened and closed by the storm pressure in the flow hole And an opening / closing plate.

In addition, the open / close board is configured to cover the upper end of the open / close board having the lower end located at the lower portion, and a cutout is formed at the upper end of the open / close board.

As described above, the present invention improves the structural soundness of a soundproof door by absorbing storm pressure, zeolite, and the like generated during blasting in a relaxed state by the mitigation fiberboard, So that the sound insulation efficiency is doubled.

1 is a schematic view showing a state where the present invention is mounted on a tunnel.
2 is a side cross-sectional view showing the structure of the sound insulation door of the present invention.
Fig. 3 is a schematic view showing a woven fiberboard in a mitigating fiberboard as an embodiment of the present invention. Fig.
Fig. 4 is an operational state diagram of the mitigating fiberboard of the present invention. Fig.
5 is a schematic view showing an embodiment of a transverse frame which is an embodiment of the present invention;
6 is an operational state view of an embodiment of an outer finishing plate that is an embodiment of the present invention;

Hereinafter, preferred embodiments of the present invention will be described.

1 and 2, the tunnel soundproof wall structure 1 of the present invention comprises a frame 2 for forming a space therein by the longitudinal frame 21 and the transverse frame 22; A sound absorbing material (4) contained in the frame (2); An outer finishing plate (3) formed in the frame (2) in the outer side of the tunnel and formed with a plurality of pressure sinks (31); A pair of woven fiber boards 51 which are formed in the inner direction of the tunnels in the frame 2 and form a gap therebetween and twisted spaced fibers 52 to form a gap between the woven fiber boards 51 between the woven fiber boards 51 (5) comprising a light-absorbing fiber sheet (5).

That is, according to the present invention, the mitigation fiberboard 5 in the tunnel inner direction in the tunnel is first passed through the sound absorbing material 4 of the frame 2 in a state of being absorbed by the explosion pressure, And the sound absorbing material 4 is allowed to pass through the relaxed fiberboard 5 in a state where there is no sound transmission structure in the lateral direction so that the sound absorbing material 4 is primarily absorbed, thereby doubling the sound absorbing efficiency.

First, the frame 2 is formed by the longitudinal frame 21 and the transverse frame 22 to form a skeleton in the tunnel t of FIG. 1. In the inner side, the door m is formed by the hinge coupling, t) inside and outside. Such a frame 2 can be realized by various methods (structure) such as constituting a basic skeleton of the soundproof door 1 according to the present invention and assembling it as a unit, and therefore, a description thereof will be omitted.

Since the sound absorbing material 4 is contained in the frame 2, various known materials can be used for the sound absorbing material 4, and a description thereof will be omitted.

The outer finishing plate 3 is formed in the outer side of the tunnel 2 in the frame 2 so as to form a plurality of pressure dissipating holes 31. The outer finishing plate 3 is configured to discharge the explosion pressure passing through the sound absorbing material 4 to the outside Thereby preventing the load from being generated inside.

The frame 2, the sound absorbing material 4 and the outer finishing plate 3 correspond to a known structure in the conventional soundproofing technology. In the conventional soundproofing technology, as described above, the explosion pressure And the stones are directly received in the frame 2, the structural integrity such as breakage of the soundproof doors is lowered. The frame 2 has a structure in which the longitudinal frames 21 are supported by the transverse frames 22 The explosive sound transmitted in the lateral direction is transmitted through the transverse frame 22, and thus there is a problem that sound absorption is not properly performed even if the sound-absorbing material 4 is present.

In the present invention, in the frame 2, the mitigation fiberboard 5 is constructed in the inner side of the tunnel so that the explosion pressure, the zeolite, and the like generated at the time of the explosion strike the mitigation fiberboard 5 first, The first sound absorption efficiency is increased and the sound absorption function is doubled in the absence of the sound transmission structure in the lateral direction.

Characterized in that the relaxed fiberboard (5) comprises twisted spaced fibers (52) to form a spacing between a pair of woven fiberboard (51) and the woven fiberboard (51).

As shown in FIG. 3, the woven fiberboard 51 is formed by weaving a plurality of meshes 511 by fiber weaving. Is formed by weaving to strengthen the tensile strength and to form a plurality of meshes 511 so that explosive sound and explosion pressure are transmitted through the mesh 511.

The spacing fibers 52 are disposed between the pair of woven fiber boards 51 and are formed in a twisted shape. The reason why the spacing fibers 52 are formed is that the load due to explosion pressure, Is transferred to the spacing fibers 52 through the woven fiberboard 51 and is relaxed by the elasticity of the spaced fibers 52 due to the twisted shape so that the load transferred to the frame 2 through the inner woven fiberboard 51 is reduced. A plurality of sound absorbing spaces are formed by the twisted spacing fibers 52 between the woven fiber boards 51 so that the explosive sound that is primarily absorbed is absorbed by the sound absorbing material 4, The loosened fiberboard 5 is not made of a material having a high hardness such as iron and having a high sound transmission rate so as to form a space between the pair of woven fiber boards 51, A pair of weave islands To ensure that the space formed between the plate (51) to increase the absorption efficiency ever block the transmission of sound in the horizontal direction.

The woven fiberboard 51 and the spacing fibers 52 may be formed by various fiber yarns. In the case of the spacing fibers 52, it is appropriate to sufficiently relieve the impact by using a material having high elasticity.

This mitigation fiberboard 5 is mounted on the frame 2 by means of a fastening channel 6 mounted on the frame 2 as shown in Fig. 2 in order to maximally block the sound transmission rate in the transverse direction It is reasonable.

2, the pair of piercing plates 7 and the mitigation fiberboard 5 are mounted on a pair of piercing plates 7 formed with piercing holes 71, And in particular, the perforated plate 7, which is located outwardly of the frame 2, is fixed to the fastening channel 6 by non-attachment.

As shown in FIG. 2, a pair of piercing plates 7 and a loosened fiberboard 5 disposed thereon are attached to a fastening channel 6 having a bending structure such that a fastening channel 6 of a bent structure is attached to the frame 2 .

As shown in FIG. 4, the load F due to the blast pressure and the zeolite during the explosion is transmitted to the outer perforated plate 7, and the transmitted load F is transmitted to the mitigation fiber board 5 And the load F1, which is relaxed by the sound absorbing material 4 in the frame 2, is transmitted.

When the load is released, the relief fiberboard 5 is restored by the elasticity of the spacing fibers 52, and the perforated plate 7 located outside is in contact with the fastening channel 6 again. That is, the moderating fibrous sheet 5 is not fixed to the frame 2 by a bolt having a large hardness, so as to block the sound transmission in the transverse direction to the maximum, and the load F1 relaxed by the shock absorption is transmitted, And to improve the structural integrity.

The perforated plate 7 corresponds to the structure in which the perforated plate 71 is formed to transmit the explosion pressure and the explosion sound and to block the foreign substance such as zeolite to protect the perforated fiberboard 5. When the releasable fibrous sheet 5 is exposed to a monument or the like generated during the explosion, it is protected by the perforated plate 7 that the function of the releasable fibrous sheet 5 may not be developed due to tearing.

The detonation pressure and the explosion sound relaxed by the mitigating fiberboard 5 are transmitted to the sound absorbing material 4. The explosion pressure and the explosion sound are transmitted to the frame 2 in the lateral direction by the transverse frame 22, In the present invention, as shown in FIG. 5, the transverse frame 22 includes two or more transverse frame units 221 made of an elastic material, The receiving portion 222-1 is formed in a concave shape and each transverse frame unit 221 is connected to the receiving portion 222-1 by a cutoff coupler 222 having a cavity 222-2 formed at the center thereof, As shown in FIG.

5, the transverse frame 22 is supported and connected between the longitudinal frames 21. The transverse frame 22 includes a transverse frame unit 221 having one end attached to the longitudinal frame 21, And a cutoff coupler 222 for connecting the transverse frame units 221. [

The blocking coupler 222 is made of an elastic material such as rubber to relieve the transmission from the transverse frame unit 221 to the transverse frame unit 221 due to the elasticity of the blocking coupler 222 itself in case of explosion pressure, (222-2) of the blocking coupler (222) to block transmission from one transverse frame unit (221) to another transverse frame unit (221).

With this configuration, in the present embodiment, the transmission structure of the load and sound is structurally transversely blocked by the mitigation fiberboard 5 and the cutoff coupler 222 at the front, thereby doubling the sound absorption efficiency and transmitting the explosion pressure It will double the structural integrity.

If the explosion pressure is high during the explosion, a large amount of energy can be transmitted to the outer finishing plate 3 by the above-mentioned structure. In this case, the outer finishing plate 3 attached to the frame 2 is detached, There is a problem that the pressure is not sufficiently dissipated, a load is applied to the internal structure such as the frame 2, and an explosion pressure discharged to the pressure diverging hole 31 is too large to exert influence on the outside. 6 shows an example in which the above problem is solved by increasing the dissipation efficiency of the explosion pressure.

In this embodiment, the outer finishing plate 3 is an example of the pressure dissipating hole 31. In the present embodiment, the outer finishing plate 3 has a plurality of flow holes 311 Of the outer finishing plate 3 form a predetermined clearance therebetween.

In this embodiment, an opening / closing plate 312 of an elastic material, which is fastened to the upper end of the flow hole 311 and is opened / closed by the storm pressure in the flow hole 311, is included.

That is, the opening / closing plate 312 is made of an elastic material such as rubber, and is installed in the flow hole 311 to close the flow hole 311 when there is no explosion pressure. However, when the explosion pressure Closing plate 312 is opened by striking the opening / closing plate 312 through the flow hole 311. In this striking process, when the explosion pressure is relieved by the opening / closing plate 312, It is divergent.

By this action, even when the explosion pressure is large, the explosion pressure of the opening / closing plate 312 of the elastic material is absorbed to relieve the explosion pressure from being transmitted to the outer finishing plate 3 itself, And is emitted to the outside through the plate 312.

In particular, in this embodiment, the open / close board 312 is configured to cover the upper end of the open / close board 312 having the lower end located at the lower portion, and the cutout 312-1 is formed at the upper end of the open / .

The storm pressure P is blown through the flow hole 311 to strike the opening and closing plate 312 so that the storm pressure P flows downward along the inner periphery of the opening and closing plate 312, The storm pressure P is relieved once again by the elasticity of the cut-off portion 312-1 as the cut-off portion 312-1 formed at the upper end of the open / close plate 312 located below is hit, And the storm pressure mitigated by the section 312-1 is diverted to the outside. That is, by the structure of the cutout 312-1, the storm pressure radiated to the outside is relieved to the maximum, and the problem caused by the external divergence of the large storm pressure is controlled as much as possible.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification, but should be defined by the claims.

2: Frame 3: Outside finishing plate
4: Sound absorbing material 5:
6: fastening channel 7: perforated plate
21: longitudinal frame 22: transverse frame
31: abscissa 51: woven fiberboard
52: spacing fiber 71: perforation
221: transverse frame unit 222: cut-off coupler
222-1: receptacle 222-2: joint
311: Flow hole 312: Open / close plate
312-1:

Claims (5)

A frame for forming a space therein by the longitudinal frame and the transverse frame;
A sound absorbing material embedded in the frame;
An outer finishing plate formed in the outer side of the tunnel in the frame and having a plurality of pressure sink holes; And
And a relaxed fiberboard comprising a pair of loosely spaced fibers formed in the tunnel inner direction and spaced apart from each other and twisted fibers spaced between the loosely spaced fiber plates,
Characterized in that the transverse frame is connected by a cut-off coupler in which two or more transverse frame units are made of an elastic material and the receiving part is formed in a groove shape on both sides thereof and each transverse frame unit is fastened to the receiving part and a cavity is formed in the center part Tunnel sound barrier structure.
The method according to claim 1,
Wherein the pair of perforated panels and the perforated fiberboard panels are fixed by a fastening channel attached to the frame and the perforated panel located outwardly of the frame is fixed to the fastening channel by non- Features a tunnel sound barrier structure.
delete The method according to claim 1,
In the outer finishing plate,
And a plurality of flow holes formed on the outer finishing plate in a transverse direction, and an opening / closing plate of an elastic material fastened to the upper end of the flow holes and opened / closed by the storm pressure in the flow holes.
5. The method of claim 4,
Wherein the opening / closing plate is configured to cover an upper end portion of the open / close board having a lower end located at a lower portion, and a cutout is formed at an upper end of the open / close board.

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