KR20180011678A - Concrete Structure having Embedded Noise Blocking Building Reinforcement Member that can improve endurance - Google Patents

Abstract

According to the present invention, a concrete structure to which a construction method is applied, wherein the concrete structure includes: a base material; a sound-absorbing material provided on at least a part of a surface of the base material; a sound-insulating material provided on a surface of the base material continuously with the sound-absorbing material; and a wire mesh fixing the sound-absorbing material and the sound-insulating material, wherein the fixed sound-absorbing material and sound-insulating material, and the wire mesh are subjected to mortar treatment so as to form a single layer, wherein the sound-absorbing material is selected from a melamine sheet (20-25T), a polypropylene (PP) ultrafine fiber sheet, expanded polystyrene (EPS), ethylene-vinyl acetate (EVA) (foam rubber), wherein the sound-insulating material is selected from an eco-friendly ceramic composite material and an EVA sheet.

Description

TECHNICAL FIELD [0001] The present invention relates to a concrete structure having an embedded sound-absorbing vibration reinforcement capable of improving the strength of an aged apartment house,

The present invention relates to a concrete structure, and more particularly, to a structure capable of improving the sound insulation effect and the earthquake-proof effect by providing a sound-insulating reinforcing member, in particular, a concrete structure of a house.

Until recently, Korea has been rapidly promoting the construction of apartment houses, mainly apartments, in order to provide comfortable environment and efficient housing by eliminating the housing shortages and increasing the land use rate. As a result, more than 70% of the recent housing construction has been occupied by multi-family houses, which has become a representative type of housing in Korea.

In the 1980s, the majority of the apartments were built in the wall, and then the high - rise apartments and residential complexes in the late 1990s appeared. Nowadays, 20 year old apartment buildings have gradually become structurally obsolete as well as functionally and spatially, resulting in many social problems.

Especially, in aged apartment buildings and apartment buildings, crime cases such as murder and fire due to floor impact noise have been occurred repeatedly. Therefore, there is a growing public opinion to include interlayer noise and vibration in the evaluation items of safety diagnosis during reconstruction.

In addition, the new building requires the floor construction to satisfy both the standard floor structure and the recognized floor structure, which satisfies the certain thickness and the constant breaking performance, but it is a problem because there is no sound insulation provision for the existing building.

The existing reinforcement method is affected by various factors such as the performance of the epoxy bonding the concrete to the concrete rather than the performance of the reinforcement and the construction state. For the sound insulation effect, many researchers and companies have been focusing on floor construction only.

The conventional repair and rehabilitation method uses a fiber sheet and a steel sheet as a reinforcing material and attaches to an existing structure and uses an anchor reinforcing method.

Therefore, a method for solving such problems is required.

Korean Patent Publication No. 10-2006-0021052

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems of the prior art, and it is an object of the present invention to provide a concrete structure which can improve a sound insulation effect as compared with the prior art.

The present invention also provides a concrete structure capable of unifying sound insulation and sound insulation related to interlayer noise.

Also, it is intended to provide a new sound insulation method in which the existing gypsum board is avoided.

In addition, it is intended to provide a method for securing insulation performance at the same time by applying artificial mineral fiber or the like.

The problems of the present invention are not limited to the above-mentioned problems, and other problems not mentioned can be clearly understood by those skilled in the art from the following description.

According to the present invention, there is provided an interlayer noise reduction reinforcement method comprising the steps of: applying a sound absorbing material to at least a part of a surface of a base material of a concrete structure; Constructing a sound insulating material on the surface of the base material continuously with the sound absorbing material; Fixing the sound absorbing material and the sound insulating material by a wire mesh; And the sound absorbing material is selected from a melamine sheet (20-25T), a PP microfiber fiber sheet, EPS, EVA (foam rubber), and the sound insulating material is an environmentally friendly ceramic composite And the EVA sheet, and the step of successively mounting the sound insulating material on the surface of the base material with the sound absorbing material includes the step of forming a plurality of through holes arranged at predetermined intervals in the sound insulating material, Wherein the step of performing the mortar treatment comprises the steps of: forming the sound absorbing material, the sound insulating material, and the wire mesh to fix the sound absorbing material, the sound insulating material, and the plurality of wire meshes, To form a single layer.

The step of performing the mortar treatment of the layer reduction sound reinforcement method includes a step of applying a heat insulating material using artificial mineral fibers, and the heat insulating material may also be integrally formed on the single layer.

The step of installing the sound insulating material may include the steps of (a) surface grinding (b) primer coating, (c) epoxy putty processing, and (d) step of adhering the sound insulating material using an epoxy resin. (e) a step of bonding the wire mesh with the sound insulating material using an anchor bolt, and (f) a step of mortar treatment.

In the layer reduction sound reduction reinforcement method, the sound insulating material is a regenerative rubber plate. In order to improve the adhesion performance between the regenerated rubber plate and the base material, the wire mesh and the regenerated rubber plate can be attached using epoxy.

The refractory mortar having excellent compressive strength can be used in the layer reduction sound reinforcement method.

In the layer reduction sound reinforcement method, the artificial mineral fiber may be a glass wool.

In the layer reduction sound reinforcement method, the artificial mineral fiber may be a mineral wool.

According to another aspect of the present invention, there is provided an interlayer noise reduction reinforcement method comprising: constructing a sound absorbing material on at least a part of a surface of a base material of a concrete structure; Constructing a sound insulating material on the surface of the base material continuously with the sound absorbing material; Fixing the sound absorbing material and the sound insulating material by a wire mesh; And the sound absorbing material is selected from a melamine sheet (20-25T), a PP microfiber fiber sheet, EPS, EVA (foam rubber), and the sound insulating material is an environmentally friendly ceramic composite And the EVA sheet, and the step of successively constructing the sound insulating material on the surface of the base material with the sound absorbing material includes the step of forming a plurality of through holes arranged at predetermined intervals in the sound insulating material, Wherein the sound absorbing material, the sound insulating material, and the wire mesh for fixing the sound absorbing material, the sound insulating material, and the wire mesh are formed as a single layer, and the spacing space between the plurality of through holes and the through holes can separate the base material from the sound insulating material, The embossing can be absorbed.

In the other interlaminar noise reduction reinforcement method, the step of fixing with the wire mesh may include a plurality of wire meshes in which eyes of different sizes are formed or arrangements of eyes formed in the same size are arranged differently from each other.

The step of performing the mortar treatment of the other inter-layer noise reduction reinforcing method includes a step of applying a heat insulating material using artificial mineral fibers, and the heat insulating material may also be integrally formed on the single layer.

In the other layer reduction sound reinforcement method, the artificial mineral fiber may be a glass wool.

In the other layer reduction sound reinforcement method, the artificial mineral fiber may be a mineral wool.

The present invention also provides a method for reducing noise between buildings, comprising the steps of: applying a sound absorbing material to at least a part of a surface of a base material of a concrete structure; Constructing a sound insulating material on the surface of the base material continuously with the sound absorbing material; Fixing the sound absorbing material and the sound insulating material by a wire mesh; A step of detaching the fixed sound absorbing material and the sound insulating material; And a plurality of interference protrusions for widening a contact area with the base material are formed in the base material and a plurality of nuts provided on an outer circumferential surface of the base material are buried in the recesses to fix the space between the sound insulating material and the wire mesh, Wherein the step of forming the sound absorbing material, the sound insulating material, and the wire mesh for fixing the sound absorbing material, the sound insulating material, and the wire mesh is formed into a single layer, and the sound absorbing material is melamine sheet 20 -25T), PP microfiber fiber sheet, EPS, EVA (foam rubber), and the sound insulating material is selected from eco-friendly ceramic composite material and EVA sheet.

In the mortar treatment step of another interlayer noise reduction biping method of the present invention, there is included a step of installing a heat insulating material using artificial mineral fibers, and the heat insulating material is also integrally applied to the single layer. Method.

In the another layer reduction sound reinforcement method, the artificial mineral fiber may be a glass wool.

In the another layer reduction sound reinforcement method, the artificial mineral fiber may be a mineral wool.

The concrete structure to which the method according to the present invention is applied includes: a base material; A sound absorbing material provided on at least a part of the surface of the base material; A sound insulating material provided on the surface of the base material continuously with the sound absorbing material; And a wire mesh for fixing the sound absorbing material and the sound insulating material, wherein the fixed sound absorbing material, the sound insulating material and the wire mesh are subjected to a mortar treatment to form a single layer, and the sound absorbing material comprises a melamine sheet (20-25T) EPS, EVA (foamed rubber), and the sound insulating material is selected from eco-friendly ceramic composite material and EVA sheet.

The concrete structure to which the method according to the present invention is applied may further include a heat insulating material using artificial mineral fibers.

In the concrete structure to which the method according to the present invention is applied, the sound insulating material is formed by the steps of (a) grinding the surface, (b) applying the primer, (c) e) step of bonding wire mesh and sound insulating material using anchor bolts, and (f) step of mortar treatment.

In the concrete structure to which the method according to the present invention is applied, the sound insulating material is a recycled rubber plate. In order to improve the adhesion performance between the reclaimed rubber plate and the base material, epoxy may be used between the recycled rubber mesh and the wire mesh.

In the concrete structure to which the method according to the present invention is applied, the mortar can use a refractory mortar excellent in compressive strength.

In the concrete structure to which the method according to the present invention is applied, a plurality of through holes arranged at predetermined intervals are formed in the sound insulating material. In the wire mesh, Can be arranged differently.

In the concrete structure to which the method according to the present invention is applied, the spacing space between the plurality of through holes and the through holes can separate the base material and the sound insulating material, and absorb shock transmitted from the sound insulating material to the concrete slab Embossing can be installed.

In the concrete structure to which the method according to the present invention is applied, a groove is formed in the base material, and a plurality of interference protrusions for widening the contact area with the base material are embedded in the groove, and the sound insulating material and the wire mesh And a fastening member may be coupled to the nut embedded in the groove to fix the base material.

In the concrete structure to which the method according to the present invention is applied, the artificial mineral fiber may be a glass wool.

In the concrete structure to which the method according to the present invention is applied, the artificial mineral fiber may be a mineral wool.

In the concrete structure to which the method according to the present invention is applied, the artificial mineral fiber may be integrally formed on the single layer.

In the concrete structure to which the method according to the present invention is applied, the interference protrusions may be formed in a serrate-like shape repeatedly around the outer periphery of the nut.

Another concrete structure to which the method according to the present invention is applied includes a base material; A sound absorbing material provided on at least a part of the surface of the base material; A sound insulating material provided on the surface of the base material continuously with the sound absorbing material; And a wire mesh for fixing the sound absorbing material and the sound insulating material, wherein the fixed sound absorbing material, the sound insulating material and the wire mesh are subjected to a mortar treatment to form a single layer, and the sound absorbing material comprises a melamine sheet (20-25T) Wherein the sound insulating material further comprises a heat insulating material selected from an eco-friendly ceramic composite material and an EVA sheet, the heat insulating material applying artificial mineral fibers, the sound insulating material comprising: (a) a step of surface grinding (b) Step of applying primer (c) Step of epoxy putty processing (d) Step of attaching sound insulating material using epoxy resin (e) Step of bonding wire mesh and sound insulating material using anchor bolt Wherein the mortar is a refractory mortar having excellent compressive strength, a plurality of through holes arranged at predetermined intervals are formed in the sound insulating material, The meshes may be formed with eyes of different sizes or different arrangements of the eyes formed in the same size, and the spacing space between the plurality of through holes and the through holes may be spaced apart from the base material and the sound insulating material, And a plurality of interference protrusions for widening a contact area with the base material are buried in the grooves, wherein a plurality of nuts provided on the outer circumferential surface are embedded in the grooves, A fixing member is coupled to a nut embedded in the groove so as to fix the sound insulating material, the wire mesh, and the base material, and the interference protrusion is formed in a serrated shape repeatedly on the outer periphery of the nut to form a plurality of .

The concrete structure having the interlaminar noise reduction reinforcing member capable of improving the strength of the present invention to solve the above problems has the following merits.

First, there is an advantage that a sound insulation effect can be improved as compared with a standard floor structure applied to a conventional building.

Second, there is an advantage that the strength of the structure can be improved along with the sound insulation effect.

Third, there is an advantage that the construction cost is reduced and construction time is shortened because the construction process is simple.

Fourth, it is possible to reduce the material cost by improving the strength and unifying the noise / vibration cut-off, thereby ensuring economic efficiency and environmentally friendly construction.

Fifth, the sound-absorbing material and the sound insulating material can be more firmly attached to the concrete member by the wire mesh.

Sixth, artificial mineral fiber can be applied to ensure insulation performance.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the description of the claims.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a view showing a wall of a conventional conventional reinforced concrete apartment house; Fig.
2 is a view showing a wall to which a reinforcement method according to the present invention is applied.
Fig. 3 is a diagram showing the reverse A characteristic of a light weight and weight impact member of a structure to which the present method is applied; Fig.
4 is a view showing a load displacement relationship of a structure to which the method of the present invention is applied.
5 is a view for explaining that a sound insulating material with embossing is installed in the reinforcement method according to the present invention.
6 is a view for explaining the installation of a mesh member in the reinforcement method according to the present invention.
FIG. 7 is a view for explaining that two mesh members having different eye sizes are installed in the reinforcement method according to the present invention.
8 is a view for explaining the installation of two mesh members having the same eye size in the reinforcement method according to the present invention.
Fig. 9 is a view for explaining how the sound insulation reinforcement member and the mesh member are fixed to the concrete slab in the reinforcement method according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. In describing the present embodiment, the same designations and the same reference numerals are used for the same components, and further description thereof will be omitted.

The technical outline of the present invention will be described as follows.

First, sound absorbing material + sound insulating material + wire mesh (strength improvement) + mortar structure.

Second, the sound absorbing material and sound insulating material are consecutively constructed to increase the sound insulation efficiency. For this purpose, a sound absorbing sheet and a sound insulating sheet are attached, and then fixed with a wire mesh and subjected to a mortar treatment.

Third, environmentally friendly materials that do not generate harmful substances are used.

Fourthly, melamine sheet (20-25T), PP microfiber fiber sheet, EPS, EVA (foam rubber) can be used as a sound absorbing material.

Fifth, as a sound insulating material, eco-friendly ceramic composite material, EVA sheet can be used.

Sixth, artificial mineral fiber can be applied to ensure insulation performance.

Seventh, the sound-absorbing material and the sound insulating material can be more firmly attached to the concrete member by the wire mesh.

In the method of reinforcing the internal noise reduction which can improve the proof strength according to the present invention, it is possible to improve the proof stress and to cut off the noise and vibration and to achieve the insulation effect. That is, by reinforcing the structure, it is possible to reduce the noise, in particular, the interlayer noise, and to improve the strength of the structure itself. This is especially meaningful in the remodeling of aged reinforced concrete apartment houses.

(A) Surface grinding (b) Primer coating (c) Epoxy putty treatment (d) Sound insulating material (recycled rubber plate) using epoxy resin (e) Wire mesh using anchor bolts And rubber plate adhesion (f) mortar treatment.

Here, the construction process from (a) to (c) may be the same as the construction process of the fiber sheet reinforcement method. In order to improve the adhesion performance of the sound insulating material (recycled rubber plate) with the base material, it is possible to attach the sound insulating material to the sound insulating material by making a hole with a square (100 × 100 mm) at intervals of 100 mm, and the construction for attaching the wire mesh, Anchor bolts can be attached to the base material by making a 100 mm hole, and then the sound insulating material and wire mesh can be integrated. The refractory mortar with a compressive strength of 20 MPa can be used to improve the adhesion of the base material, the sound insulating material and the wire mesh, and to finish the finishing to ensure fire resistance.

Since the main purpose of this method is to propose a construction method that can be applied to slabs and wall members of buildings, the total reinforcement thickness can be designed to be less than 30 mm in order to minimize the load and thickness of the reinforcement.

According to the fracture pattern of the reinforced concrete structure, no detachment or breakage of the wire mesh and the sound insulating material occurred in the final fracture pattern of the test specimen, and the final fracture occurred in a manner of increasing the flexural crack width. From this, it can be seen that the wire mesh and the sound insulating material do not fall off from the specimen due to the fixing force of the anchor bolts.

In addition, the 17 - layer decreased by 4 dB and the 16 - layer decreased by 7.4 - 12.3 dB compared to the 18 - layer without reinforcement at the reverse A - type floor impact sound level by the standard weight impact source. And finally, in the final failure mode of the test specimen, the dropout and fracture of the wire mesh and the sound insulating material did not occur, and the final fracture occurred in a manner of increasing the flexural crack width. From this result, it can be seen that the present reinforcing method shows a higher sound-absorbing effect than the measured value by the light-weight sound impulse source, and that the present method is effective for the sound insulation effect (see FIG. 3).

In addition, the reinforced specimens reinforced by the embedded sound - damping method, which can improve the strength, showed the maximum strength of 1.11 times, 1.3 times, and 1.38 times higher than those of the non - reinforced specimens, respectively. From this, it can be seen that the present method is an effective method for improving the proof strength (see FIG. 4)

In the method according to the present invention, a) after refractory mortar treatment without surface treatment, b) adhering the sound-absorbing material and the soundproofing plate, adhering the heat insulating stiffener, c) attaching and fixing the lattice type steel mesh, d) have.

Closing with refractory mortars can simplify construction, including installing sound insulation, sound insulation boards, insulation reinforcement plates and, if necessary, wire meshes into a single layer.

FIG. 1 shows a wall of a conventional reinforced concrete apartment house. Conventionally, as shown in Fig. 1, concrete is applied to the surface of the gypsum board in the order of a heat insulating material and a gypsum board.

2 is a reinforced concrete wall to which the reinforcement method of the present invention is applied. According to the method of the present invention, it is possible to provide an economical method by applying an eco-friendly material replacing a gypsum board with a heat insulating material as shown in Fig. 2 and applying a material capable of reducing interlayer noise vibrations, which is a problem in a wall- It is possible.

According to the present invention, there is provided an interlayer noise reduction reinforcement method comprising: constructing a sound absorbing material on at least a part of a surface of a base material of a concrete structure; Constructing a sound insulating material on the surface of the base material continuously with the sound absorbing material; Fixing the sound absorbing material and the sound insulating material by a wire mesh; The sound absorbing material is selected from a melamine sheet (20-25T), a PP microfiber fiber sheet, an EPS, and an EVA (foamed rubber). The sound insulating material is an eco-friendly ceramic composite material, EVA sheet.

The base material may include various concrete structures to be applied to buildings, and in the case of the present embodiment, the base material is a reinforced concrete with reinforcing bars embedded therein.

The slab, the wall, the beam, the column, and the like that can be used as the base material are not limited thereto. In this embodiment, the base material is used as the base material.

As the sound insulating material, various materials for sound insulation may be used. In this embodiment, the sound insulating material is made of recycled rubber.

The sound insulating material 200 may have a through hole 210 and a plurality of rectangular through holes 210 may be formed at predetermined intervals along the longitudinal direction of the sound insulating material 200. The reason for doing this is to improve the adhesion between the sound insulating material 200 and the concrete base material 101. The sound insulating material 200 may be attached to the base material 101 using an adhesive resin such as epoxy.

Further, before the step of providing the sound insulating material 200, the step of surface-treating the base material 101 may be further included. In this step, at least one of grinding the surface of the base material 101, applying a primer to the surface of the base material 101, and applying an epoxy putty to the surface of the base material 101 The above process may be included. Each of these processes enhances the structural characteristics of the base material 101 and improves the adhesion of the sound insulating material 200.

After the step of providing the sound insulating material on at least a part of the surface of the base material 101, a step of providing the mesh member 300 to surround the sound insulating material is performed.

The mesh member 300 has a shape woven by wires formed to intersect with each other and has a purpose of preventing the sound insulating material 200 from falling off and reinforcing the base material 101.

In the present embodiment, the mesh member 300 is provided on all four surfaces of the base material 101, like the sound insulating material 200.

The sound insulating material 200 and the mesh member 300 may be fixed by the fastening member 400. That is, a coupling groove 410 is formed in the base material 101, and the coupling member 400 is formed to be insertable in correspondence with the coupling groove 410. Accordingly, the sound insulating material 200 and the mesh member 300 are stably fixed.

Meanwhile, in the present embodiment, the mesh member 300 is provided only as one layer, but the mesh member 300 may be formed as a plurality of layers. In this case, adhesion of the sound insulating material 200 and reinforcement of the base material 101 can be improved. This can then be selected considering the thickness of the final concrete structure.

When the mesh member 300 is provided in a plurality of layers, the plurality of mesh members 300 may have eyes 310 of different sizes. That is, the wire densities of the respective mesh members 300 may be formed to be different from each other, so that structural stability and rigidity can be further increased.

After the step of providing the mesh member 300 to enclose the sound insulating material 200, a step of packing the mesh member 300 with a packaging material to form a packaging layer is performed.

In this step, the refractory mortar, concrete or the like is applied to the mesh member 300 for finishing treatment, and the concrete is cured to finalize the manufacture of the concrete structure. The adhesion performance between the base material 101 and the sound insulating material 200 and the mesh member 300 can be improved by the finishing treatment and the fire resistance performance can be ensured.

Hereinafter, the installation of the sound insulating material 200 and the method of wrapping the sound insulating material 200 with the mesh member 300 will be described in detail with reference to FIGS. 5 to 9. In the following description, the sound insulating material 200 is continuously installed with the sound absorbing material, And the base material can be understood as a base material of a concrete material. In the interlaminar noise reduction reinforcement method of the present invention, a sound insulating material 200 made of an elastic material such as recycled rubber is wrapped around the concrete slab base material 101. As the sound insulating material 200, various materials for sound insulation may be used. In this embodiment, the sound insulating material 200 is made of recycled rubber, but a foamed polyether sheet material can be used. In addition, a porous synthetic resin such as a sponge or a nonwoven fabric can be made to have a sound-absorbing property. In this case, resonance in the hole should be suppressed and resonance sound should be absorbed to reduce the noise.

The sound insulating material 200 has through holes 210 arranged at a plurality of predetermined intervals. The through holes 210 may be formed in various shapes, but in the present embodiment, a plurality of rectangular through holes 210 are formed at predetermined intervals along the longitudinal direction of the sound insulating material 200.

5, an embossing 220 is formed in the sound insulating material 200 in a spaced-apart space between the through hole 210 and the through hole 210. When the embossing 220 is formed, the space between the through hole 210 and the through hole 210 can absorb a certain portion of the impact transmitted to the concrete slab base material 101, The dustproof effect can be expected.

This embossing 200 minimizes the contact between the concrete slab base material 101 and the sound insulating material 200 so as to minimize impact transmission while providing a spacing space between the concrete slab base material 101 and the concrete slab base material 101, And the effect of complementing the adiabatic effect can be expected.

An adhesive such as an epoxy resin is injected through the through hole 210 of the sound insulating material 200 to be firmly attached to the concrete slab base material 101.

The sound insulating material 200 may be installed on all sides of the concrete slab base material 101, but may be installed on only a part of the surface.

Further, as shown in FIG. 6, a mesh member 300 is installed on the sound insulating material 200.

7 and 8, two or more of the mesh members 300 may be installed on the sound insulating material 200 on the concrete slab base material 101 at a time.

A plurality of eyes 310 having different sizes are formed on the mesh member 300 so that the mesh member 300 is overlapped with the sound insulating material 200 and the wire density of the mesh member 300 is different for each mesh member 300. Therefore, the sound insulating material 200 can be prevented from falling off the concrete slab base material 101 and the strength of the concrete slab 101 can be reinforced.

The size of the eye of the mesh member 300 and the arrangement of the eyes can be determined such that the sizes of the eyes 310 of the mesh members 300 overlap each other as shown in FIG. This is because when the plurality of mesh members 300 are overlapped, the places where the eyes 310 of the mesh member 300 are located are shifted from each other to maximize the wire density with respect to the concrete slab base material 101, And to increase the stiffness.

In addition, the wire 310 of the mesh member 300 is different in size, and the mesh members 300 are formed to have different wire densities and are superimposed on each other, resulting in improved structural stability and rigidity.

7 shows an example in which the eyes 310 of the mesh member 300 are different from each other. In FIG. 8, the mesh member 300 having the eyes 310 having the same size and different arrangement, 200). ≪ / RTI >

As shown in FIG. 8, when two mesh members (one solid line and one broken line) having the eyes 310 of the same size and arrangement are overlapped, the eye 310 of the mesh member 300 indicated by the solid line, The eye 310 of the mesh member 300 indicated by the dashed line may be positioned between the overlapped mesh member 310 and the eye 310 of the overlapped mesh member 300 may be dense.

The mesh member 300 may be installed on all sides of the concrete slab 101, but may be installed on only a part of the sides of the concrete slab 101. However, the mesh member 300 is installed together with the surface on which the sound insulating material 200 is installed.

As shown in FIG. 9, the sound insulating material 200 and the mesh member 300 may be fixed by the fastening member 400 by the concrete slab base material 101. The concrete slab base material 101 has a coupling groove 410 to which the coupling member 400 is to be coupled. In the present invention, the nut 420 is embedded in the fastening groove 410 of the concrete slab base material 101 so that the fastening member 400 can be easily fastened to the concrete slab base material 101 The fastening member 400 is rotated with respect to the nut 420 so as to be fastened.

The nut 420 is inserted into the concrete slab base material 101 with the interference protrusion 421 formed around the nut 420 so that the nut 420 is not separated from the concrete slab base material 101. The interference protrusion base material 421 can be firmly inserted into the concrete slab base material 101 by widening the contact area with the concrete slab base material 101.

As shown in FIG. 9, the interference protrusions 421 may be formed in a serrated shape on the outer periphery of the nut 420, and a plurality of the interference protrusions 421 may be formed.

The coupling member 400 is inserted into the coupling groove 410 of the concrete slab base material 101 so as to integrally join the concrete slab base material 101, the sound insulating material 200 and the plurality of mesh members 300 And is fastened to the nut 420 having the interference protrusion 421.

The mesh member 300 may be covered with a separate packaging layer (not shown) and may be finished with a refractory mortar.

The mortar used in the present invention is a structure in which, for example, a sound absorbing material of a spherical shape is mixed with a mortar to absorb noise when the noise is transmitted through the mortar, and sound absorption and sound insulation are generated at the same time, The effect of increasing the loss can be obtained. In addition, artificial mineral fibers can be used to ensure insulation performance. Man-Made Mineral Fiber (MMMF) is artificially fiberized by liquefaction of glass, rock and other minerals at high temperatures. It can replace the use of natural asbestos fibers. Unlike natural fibers, amorphous ≪ / RTI > silicate. In the present invention, glass wool and mineral wool can be used as artificial mineral fibers.

If glass wool is used as an insulation material as in the present invention, soft and soft fibers are delicately gathered to ensure excellent heat insulation performance, sound insulation performance, and low density. In addition, it can be nonflammable because it is inorganic, and it has excellent durability of material, and it can be applied semi-permanently without deformation with time. It can be easily cut by simple tools such as knife even during construction and can be manufactured in various sizes to suit the application.

As shown in FIG. 2, since the finishing mortar, the lightweight foamed concrete, the sound insulating material and the heat insulating material are constructed in a single layer structure, the convenience of construction and the economical efficiency are greatly improved.

In the present invention, a sound absorbing material and a sound insulating material are continuously formed to increase the sound insulation efficiency. To this end, a sound absorbing sheet and a sound insulating sheet are attached, and then fixed with a wire mesh.

In the present invention, since the existing gypsum board is replaced with the single-layer structure as described above, it is preferable from the environmental point of view.

It is a matter of course that the concrete slab 101 of the present invention can be a wall, a beam, and a column of a building.

It will be apparent to those skilled in the art that the present invention can be embodied in other specific forms without departing from the spirit or scope of the invention as defined in the appended claims. It is obvious to them. Therefore, the above-described embodiments are to be considered as illustrative rather than restrictive, and thus the present invention is not limited to the above description, but includes the scope of the appended claims and their equivalents.

101: Concrete slab base material
200: sound insulating material
210: Through hole
220: Embossing
300: mesh member
310: Eye
400: fastening member
410: fastening groove
420: nut
421: interference projection

Claims (13)

Base material,
A sound absorbing material provided on at least a part of the surface of the base material;
A sound insulating material provided on the surface of the base material continuously with the sound absorbing material; And
And a wire mesh fixing the sound absorbing material and the sound insulating material,
Wherein the fixed sound absorbing material, the sound insulating material, and the wire mesh are subjected to a mortar treatment to form a single layer,
The sound absorbing material is selected from a melamine sheet (20-25T), a PP microfine fiber sheet, EPS, EVA (expanded rubber)
Wherein the sound insulating material is selected from eco-friendly ceramic composite materials and EVA sheets. The method according to claim 1,
Characterized in that it additionally comprises a thermal insulation applying artificial mineral fibers. The method according to claim 1,
The sound insulating material may be formed by the steps of (a) grinding the surface, (b) applying the primer, (c) stepping the epoxy putty, (d) attaching the sound insulating material using the epoxy resin, (e) attaching the wire mesh using the anchor bolt, And (f) a mortar treatment step. The method of claim 3,
Wherein the sound insulating material is a recycled rubber plate, and between the wire mesh and the recycled rubber plate is attached using epoxy to improve the adhesion performance between the recycled rubber plate and the base material. 5. The method of claim 4,
Wherein the mortar uses a refractory mortar having excellent compressive strength. The method according to claim 1,
A plurality of through holes arranged at predetermined intervals are formed in the sound insulating material,
Wherein the wire mesh is formed with eyes of different sizes or arrangements of eyes formed in the same size differently from each other. The method according to claim 1,
Wherein a spacing space between the plurality of through holes and the through holes is provided with an embossing capable of separating the base material from the sound insulating material and capable of absorbing impact transmitted from the sound insulating material to the concrete slab. The method according to claim 1,
Wherein a groove is formed in the base material and a plurality of interference protrusions for widening a contact area with the base material are buried in the groove and a plurality of grooves are formed on the outer surface of the groove so as to fix the space between the sound insulating material and the wire mesh, Wherein the fastening member is coupled to the nut embedded in the reinforcing member. 3. The method of claim 2,
Wherein the artificial mineral fiber is a glass wool. 3. The method of claim 2,
Wherein the artificial mineral fiber is a mineral wool. 11. The method according to claim 9 or 10,
Wherein the artificial mineral fiber is integrally applied to the single layer. 9. The method of claim 8,
Wherein the interference protrusions are formed in a serrated shape on the outer periphery of the nut, and a plurality of the interference protrusions are formed. Base material,
A sound absorbing material provided on at least a part of the surface of the base material;
A sound insulating material provided on the surface of the base material continuously with the sound absorbing material; And
And a wire mesh fixing the sound absorbing material and the sound insulating material,
Wherein the fixed sound absorbing material, the sound insulating material, and the wire mesh are subjected to a mortar treatment to form a single layer,
The sound absorbing material is selected from a melamine sheet (20-25T), a PP microfine fiber sheet, EPS, EVA (expanded rubber)
The sound insulating material is selected from eco-friendly ceramic composite materials and EVA sheets,
Further comprising a heat insulation material using artificial mineral fibers,
The sound insulating material may be formed by the steps of (a) grinding the surface, (b) applying the primer, (c) stepping the epoxy putty, (d) attaching the sound insulating material using the epoxy resin, (e) attaching the wire mesh using the anchor bolt, Step (f) is installed through the step of mortar treatment,
The mortar is a refractory mortar excellent in compressive strength,
A plurality of through holes arranged at predetermined intervals are formed in the sound insulating material,
In the wire mesh, eyes of different sizes are formed or arrangements of eyes formed in the same size are arranged differently,
And an embossing unit capable of separating the base material from the sound insulating material and capable of absorbing shock transmitted from the sound insulating material to the concrete slab is installed in the spacing space between the plurality of through holes and the through-
Wherein a groove is formed in the base material and a plurality of interference protrusions for widening a contact area with the base material are buried in the groove and a plurality of grooves are formed on the outer surface of the groove so as to fix the space between the sound insulating material and the wire mesh, The fastening member is engaged with the nut embedded in the nut,
Wherein the interference protrusions are formed in a serrated shape on the outer periphery of the nut, and a plurality of the interference protrusions are formed.

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