KR100627011B1 - Fold-up type soundproof block, bottom materials and constructing method thereof - Google Patents

Abstract

The present invention relates to a prefabricated support block having improved soundproofing effect, a floor structure using the same, and a construction method thereof, comprising: a groove part disposed on a building slab to receive a heat medium circulation pipe, and a plurality of soundproof holes being formed in the space between the groove parts. A prefabricated support block consisting of the perforated flat plate, a sound insulation mat provided at the lower part thereof, a heat medium circulation pipe piped at the upper part thereof, a compressed nonwoven fabric provided to face the upper part thereof, and a floor finishing material laminated to face the upper side thereof. It provides a prefabricated support block, a floor structure using the same and improved construction method of the soundproofing effect comprising a.

As described above, the present invention has excellent effects in suppressing the noise and vibration between floors and layers by minimizing the generation of noise and vibration due to impact by drilling a soundproof hole in the flat plate of the support block in the floor structure.

Floor Structure, Support Block, Soundproof Hole, Sound Insulation Mat, Compression Nonwoven Fabric, Floor Finishing Material

Description

Prefabricated support block with improved sound insulation, floor structure and construction method using same {FOLD-UP TYPE SOUNDPROOF BLOCK, BOTTOM MATERIALS AND CONSTRUCTING METHOD THEREOF}

1 is a partial cross-sectional perspective view showing a floor structure constructed by the prior art,

Figure 2 is a perspective view showing a prefabricated support block with improved sound insulation according to the present invention,

3 is a plan view and a side view showing a prefabricated support block having improved sound insulation according to the present invention;

Figure 4 is a perspective view showing a thermally conductive member mounted to the groove of the prefabricated support block with improved sound insulation according to the present invention,

5 to 6 is a cross-sectional view and a cutaway perspective view showing an example of the floor structure constructed using the prefabricated support block with improved sound insulation according to the present invention,

7 to 8 is a cross-sectional view and a cutaway perspective view showing another example of the floor structure constructed by using the prefabricated support block with improved sound insulation according to the present invention.

<Description of the symbols for the main parts of the drawings>

20: support block 22: flat plate 24: coupling groove 25: coupling protrusion 28: soundproof hole

33: thermally conductive member 40: heat medium circulation pipe 41: sound insulation mat 42: compressed non-woven fabric

43: floor finishing material 45: heat storage layer 50: slab

The present invention relates to a prefabricated support block having a soundproofing effect, a floor structure using the same, and a construction method thereof, and more particularly, to manufacture a support block that is prefabricated to support a heat medium circulation pipe on a slab of a building to improve soundproofing effect. The present invention relates to a prefabricated support block having an improved soundproofing effect that can significantly reduce floor and floor noise propagation by constructing a floor structure of a building, and a floor structure using the same and a construction method thereof.

In general, the construction method of the floor structure in the construction is a wet method and a dry method. The wet method is to install a heat insulating plate on a building slab, install a pipe support plate on it, pipe the heat medium circulation pipe (hot water pipe), cover the heat storage material, and then finish the concrete mortar layer on the upper surface. While the wet method has good heat storage performance and solid advantages, the construction process is prolonged because the construction of the insulation board, support plate, heat storage material, sand, cement, etc. is carried out directly at the construction site, and the gradient of the hot water pipe is accurately Since only the skilled workers can be installed because they have to fit, the construction cost increases, and the repaired concrete mortar layer must be damaged even when the hot water pipe is leaked.

In order to solve the problems of the wet method, a construction floor construction method by the dry method is known. The dry process is to install insulation boards on the building slabs, install pipe support plates on them, pipe the heating medium circulation pipes (hot water pipes), install metal top plates on them, or transport the floor structure units assembled with these components to the site. It is a process of assembling. This dry method has the advantage that the strength is good because the top plate is made of a metal material to prevent breakage, and the heating time is shortened by good thermal conductivity, but the metal top plate is usually a screw or fixing pin, etc. Since it is fixed to the screw due to thermal expansion due to the heating during heating or deformation occurs such as bending, there is a problem that the floor finishing material is dropped or deformed from the top plate.

In particular, the dropout or deformation between the top plate and the floor finish is a cause of the noise caused by the problems of indoor noise and floor noise of high-rise buildings.

In order to solve the problems caused by the dry method as described above, the inventors have registered the registration No. 10-0257685, Registration No. 20-0152282, Registration No. 1995-0089950, etc., but this also shrinkage-expansion due to heat Problems, such as the noise generated in the upper floor of the prefabricated dry ondol caused a failure to utilize the noise shielding of the floor structure is somewhat occurring.

On the other hand, as a technique for solving the problems of the wet and dry method of the floor structure at the same time, the technique of the registration number 10-0210350 as shown in Figure 1 is disclosed, but this technique as a heat storage layer (9) Since the cement mortar is poured, the construction cost increase and repair, which is a problem of the wet method, have to be damaged when the cement mortar layer is damaged. In particular, the support plate (support block; 3) for supporting the heat medium circulation pipe 7 forms a plurality of sealed cavities 5, thereby generating indoor noise due to resonance of the cavities 5 due to vibration, which is an interlayer noise. This is causing the problem of developing.

That is, when the existing support plate (support block) 3 is assembled into the floor structure of the building, each support block 3 forms an independent closed cavity 5 and the cavity 5 is disposed continuously. do. Noise (which is called 'primary solid sound') and vibration are generated by an impact caused by a person walking or hitting an upper portion of the one or more cavities (5), and the noise and vibration are adjacent to each other by resonance. Is delivered to the closed cavity 5 of the support block 3 to derive more noise.

In order to solve the above problems, an object of the present invention by drilling a plurality of soundproof holes in the flat plate of the support block for supporting the heat medium circulation pipe by removing the resonance phenomenon by the sealed cavity formed by the conventional support block To provide a prefabricated support block with improved sound insulation.

In addition, another object of the present invention is to install a floor structure on the building slab using the above-described prefabricated soundproof block to improve the soundproofing effect for the indoor noise and floor noise, and the construction method using the prefabricated support block. To provide.

In order to achieve the above object, the present invention is a prefabricated support block consisting of a groove portion located on a building slab for receiving a heat medium circulation pipe and a plate portion protruding in the space between the groove portion, a plurality of soundproof holes perforated in the plate portion And, provided on one side of the support block provides a prefabricated support block with improved soundproofing effect including a coupling groove and a coupling protrusion for connecting and assembling the support block.

A lower support jaw may be formed at a side surface at which the coupling groove is formed, and an upper locking jaw may be formed at a side at which the coupling protrusion is formed.

In addition, the groove portion accommodating the heat medium circulation tube may be formed in a combination of a straight line and a curve, and the groove portion accommodating the heat medium circulation tube may be provided with a thermally conductive member for heat conduction from the heat medium circulation tube accommodated therein. will be.

On the other hand, the present invention is a floor structure installed on the building slab, the sound insulating mat is installed to face the building slab, the prefabricated support block is installed to face the sound insulating mat upper surface, and the groove portion of the support block Soundproof effect prefabricated support block including a heat medium circulation tube to be inserted, a compression nonwoven fabric laminated to face the upper side of the support block is installed, and a bottom finish laminated to face the upper surface of the compressed nonwoven fabric It provides a floor structure using.

The sound insulation mat may be made of a composite material having a lower PVC layer and an upper compressed fiber layer, and a sound insulating sheet of rubber material for noise shielding may be additionally installed at a lower portion of the bottom finish.

In addition, the compressed nonwoven fabric may further include a heat storage layer configured to receive heat radiated from the heat medium circulation tube and accumulate heat thereon.

Further, the present invention provides a method for constructing a floor structure on the upper surface of the building slab, the step of installing a sound insulation mat to shield the noise on the building slab, and the support block to face the upper surface of the installed sound insulation mat Step of installing the assembly, the step of piping the heat medium circulation pipe to the upper groove of the assembled support block, the step of installing a compressed non-woven fabric to face the upper portion of the support block on which the heat medium circulation pipe is mounted, and the compression It provides a construction method of the floor structure using the prefabricated support block with improved sound insulation, characterized in that it comprises the step of laminating the bottom finish to face the upper surface of the nonwoven fabric.

In addition, the step of installing a sound insulating sheet of rubber material for shielding noise between the compressed non-woven fabric and the bottom finishing material may be further included, the heat dissipated from the heat medium circulation pipe on the upper surface of the compressed non-woven fabric to be installed The heat storage layer may be further formed to face the heat storage layer.

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

Figure 2 is a perspective view showing a prefabricated support block with improved sound insulation according to the present invention, Figure 3 is a plan view and a side view showing a prefabricated support block with improved sound insulation effect according to the present invention.

Prefabricated support block according to the present invention is located on the building slab groove portion 21 is formed in a concave shape to accommodate the heat medium circulation pipe (40), and protrudes in the space between the groove portion 21, the upper surface is It consists of the flat plate part 22 which is a plane.

That is, as shown in Figures 2 to 3, the groove portion 21 of the support block of the present invention is formed in a U-shaped groove shape so that the heat medium circulation pipe 40, such as hot water pipes are piped to the upper portion of the block. .

In particular, the groove portion 21 receiving the heat medium circulation pipe 40 is formed of a combination of a straight line and a curve, which is a zigzag piping work is performed so that the continuous circulation of the heat medium in the heat medium circulation pipe 40 is made The curved portion 29 and the groove portion 21 of the straight line 29 and the straight line 30 are formed at the same time to be applied to the pipe portion in the form of a curved line generated at the same time.

The pipe support protrusion 23 is formed as a means for supporting the heat medium circulation pipe 40 when the heat medium circulation pipe 40 is mounted while being at the boundary between the curved portion 29 and the straight portion 30. The support protrusion 23 is formed in two pairs to form a cross-shaped arrangement in the space between the adjacent circular flat portion 22 formed in the support block to support the straight or curved heating medium circulation pipe 40. .

In addition, a space portion of a predetermined size is formed between the grooves 21 formed in a grid shape on the upper surface of the support block. The protruding space portion is a flat plate portion 22 having a flat upper surface. As described above, the groove portion 21 of the heat medium circulation pipe 21 is straight (30) to curved 29 as described above. ) Is formed into a circular to semi-circular, quarter-shaped.

That is, the flat portion 22 of a complete circle 22a is formed at the center of the rectangular unit of the assembled support block of the present invention, and the flat portion 22 of the semicircular 22b is formed at the corner center, and is near the vertex. In this case, the flat plate portion 22 of the circumferential circle 22c is formed. Therefore, when the unit blocks of the support block are continuously arranged, the flat plate portion 22 of the semi-circular shape 22b is in contact with the flat plate portion 22 of the neighboring semi-circular shape 22b to form a perfect circle, and the flat plate of the 1/4 circular shape 22c is formed. The part 22 is in full contact with the flat plate part 22 of three neighboring quarter circles 22c.

On the other hand, the support block of the present invention is installed in a prefabricated manner, the assembling method is a concave-convex coupling member formed on the side portion is assembled to each other.

That is, a plurality of coupling grooves 24 are formed in one side portion of the support block and the side portion contacting with the vertex, and the coupling protrusion 25 having the same shape at a position corresponding to the coupling groove portion 24 is formed at the side portion facing the support block 24. ) Is formed to protrude. Therefore, when the support block is continuously arranged and assembled, the coupling protrusion 25 is inserted into the coupling groove 24 to be assembled in such a manner as to be fixed.

In addition, when the support blocks of the present invention are continuously arranged and assembled, each support block unit is assembled in the form of the supporting jaw 27 to the locking jaw 26 so that a flow phenomenon does not occur in the left and right or up and down directions.

That is, the lower support jaw 27 is formed to protrude from the lower side of the side surface of the rectangular support block formed with the coupling groove 24 described above, and the upper locking jaw is formed on the side surface on which the engaging projection 25 is formed. (26) is formed in the shape which protrudes from the upper part. Therefore, when the support block units are continuously arranged and assembled, the coupling protrusion 25 is inserted into the coupling groove 24 and the upper locking jaw 26 is mutually interviewed on the lower support jaw 27. .

In addition, the support block of the present invention, in order to further prevent the occurrence of flow phenomenon in the left and right or up and down direction, the fixing jaw 31 is formed in a quadrangular shape at one vertex portion where the two lower support jaws 27 described above meet. The locking jaw 32 is formed at the other vertex of the lower support jaw 27 in the same shape so as to face and face the upper surface thereof.

One of the elements characterizing the support block of the present invention is a plurality of soundproof holes 28 perforated in each of the flat plates 22 described above.

That is, the conventional support block 3 shown in FIG. 1 forms an independent closed cavity 5 during construction, and this closed cavity 5 is a continuous arrangement of the support blocks 3. Due to the continuous formation of the primary solid sound generated by the resonance phenomenon to the adjacent closed cavity (5) as a means for solving the problems of the prior art, which is derived from more noise, the flat plate portion of the support block ( 22, a plurality of sound insulation holes 28 were drilled. In other words, the role of the soundproof hole 28 is to prevent the propagation of noise from the resonance phenomenon by preventing the primary solid sound generated by forming an open cavity instead of a closed cavity during the construction of the support block to the adjacent cavity. Prevents the function.

Figure 4 is a perspective view showing a thermally conductive member mounted to the groove of the prefabricated support block with improved sound insulation according to the present invention.

The supporting block constituting the present invention is a thermally conductive member 33 capable of conducting heat generated from the heat medium circulation pipe 40 accommodated in the groove portion 21 formed therein to the left and right flat plate portions 22 of the groove portion 21. It may be provided. The material of the thermally conductive member 33 may be any metal material, and it is particularly preferable to select a copper (Cu) material having high thermal conductivity.

In addition, the shape of the thermally conductive member 33 is formed in a pipe shape of a circular shape 33a so that the center portion can be inserted and seated in the groove portion 21, while the left and right wing portions of the circular shape 33a are formed in a plate shape 33b. To cover the plate portion 22 of the support block so that the heat generated from the heat medium circulation tube 40 is conducted to the plate portion 22.

Hereinafter, the floor structure of the building using the support block 20 constituting the present invention and its construction method will be described.

5 to 6 is a cross-sectional view and a cutaway perspective view showing an example of the floor structure constructed using the prefabricated support block with improved sound insulation according to the present invention.

As shown in Figure 5 and 6, the present invention is to form a floor structure of the building using the above-described support block, first to install the sound insulation mat 41 to face on the building slab 50, The sound insulating mat 41 separates the building slab 50 and the support block 20 to block vibration or noise generated from the support block 20 and at the same time serves as a heat insulating material.

The sound insulating mat 41 has a compressed fiber layer 41b having a predetermined density as its base material, and the lower part of the compressed fiber layer 41b may be made of a composite material having a PVC layer 41a for more reliable noise blocking. In addition, the PVC layer (41a) is to provide a waterproof effect in addition to the noise blocking and thermal insulation effect of the sound insulating mat (41).

After the sound insulating mat 41 of the present invention is installed on the building slab 50 as described above, the support block 20 constituting the present invention is assembled. Installation of the support block 20 is made by inserting and fixing the engaging projection 25 or the coupling groove 24 of the support block 20 adjacent to one support block 20, the side portion of the support block 20 The lower support jaw 27 and the upper locking jaw 26 formed in contact with each other to be installed without the left and right or up and down flow.

As described above, after the support block 20 of the present invention is assembled and installed, the thermally conductive member 33 is inserted into the groove 21 of the support block 20, and the center circle of the thermally conductive member 33 is installed. The 33a portion is inserted into the groove 21 so that the plate 33b on both sides covers the flat plate 22 of the support block 20.

Then, the heat medium circulation pipe 40, which is a hot water pipe, is installed to be inserted into the central circle 33a of the thermal conductive member 33, and the heat medium circulation pipe 40 is curved and deformed at the site where the pipe is Located in the curved groove portion 29 of the support block 20 to be stably supported by the support protrusion (23).

When the heat medium circulation pipe 40 is installed in the support block 20 as described above, the compressed nonwoven fabric 42 is laminated on the upper portion thereof, and when the compressed nonwoven fabric 42 is laminated, the bottom finishing material (face) faces the upper surface ( 43) are stacked to form the entire floor structure of the present invention. The compressed nonwoven fabric 42 is made of a common fiber or glass fiber, and the density is 60 to 200 ㎏ / ㎥ is attached by a commonly used method, this density range in consideration of sound insulation and heat transfer efficiency It is selected. In addition, the thickness of the compressed nonwoven fabric 42 is preferably 3 to 10 mm, which is a range suitable for sound insulation, dustproofing, and heat transfer efficiency to the upper portion.

When the compressed nonwoven fabric 42 is stacked as described above, the heat storage layer 45 may be formed thereon. The heat storage layer 45 performs the function of heat storage of heat radiated from the heat medium circulation pipe 40 and the thermally conductive member 33, and is composed of rumen, ganban stone, feldspar, mica, volcanic ash, silica sand, sand, cement, and the like. At least one selected from the group consisting of mixed in an appropriate ratio and a binder is added to the upper portion of the compressed nonwoven fabric 42.

The bottom finishing material 43 is laminated on the upper surface of the compressed nonwoven fabric 42 or the heat storage layer 45 formed as described above, and the finishing material 43 is made of PVC, such as PVC, which is relatively low in vibration and noise generation. It is a floor of material.

7 to 8 is a cross-sectional view and a cutaway perspective view showing another example of the floor structure constructed by using the prefabricated support block with improved sound insulation according to the present invention.

As shown in Figure 7 to 8, when the floor finishing material 43 is applied to the floor structure of the present invention, such as the floor of the wooden material with a relatively high vibration and noise generation is almost the same as the construction method of the floor structure described above The floor finish 43 is not directly laminated on the compressed nonwoven fabric 42, but the sound insulating sheet 44 having a predetermined thickness is first laminated on the compressed nonwoven fabric 42 or the heat storage layer 45, and then wood flooring. To laminate the floor finish 43, such as.

The sound insulating sheet 44 is preferably made of a rubber material capable of absorbing noise and vibration, and the thickness thereof is preferably 1 mm or less in consideration of heat transfer efficiency from the bottom.

In the present invention, the expression "lamination" means that the object is fixed on the lower layer by using an adhesive material such as an adhesive, or the like is fixed to each other by a predetermined mechanical means without adhesion, or the adhesive or fixing means on the lower layer. It means simple to be loaded without.

As described above, the present invention is to minimize the occurrence of noise and vibration by the impact from the outside by drilling a soundproof hole in the flat plate of the support block to prevent the closed cavity formed by the existing support block in the floor structure. It is possible to minimize the propagation of noise and vibration because it forms an open cavity even if the noise and vibration occurs locally. Therefore, the floor structure or construction method using the support block of the present invention is an excellent effect on the suppression of noise and vibration between floors and floors. In addition, in the case of finishing materials with high vibration and noise generation levels, a sound insulating sheet made of rubber material is laminated on the lower part thereof, thereby absorbing noise and vibration to secure a quiet interior space, and being constructed to contact the upper part of the building slab. By forming the lower part of the PVC material, it is possible to further prevent the noise propagation between layers and at the same time obtain a waterproof effect.

Claims (11)

In the prefabricated support block consisting of a groove portion located on the building slab to receive the heat medium circulation pipe and a flat plate portion protruding in the space between the groove portion, A plurality of soundproof holes perforated in the flat plate, It is formed on one side of the support block prefabricated support block with improved soundproofing effect, characterized in that it comprises a coupling groove and a coupling protrusion for connecting and assembling the support block. The prefabricated support block of claim 1, wherein a lower support jaw is formed at a side surface of the coupling groove, and an upper locking jaw is formed at a side of the coupling protrusion. The prefabricated support block of claim 1, wherein the groove part accommodating the heat medium circulation pipe is formed by a combination of a straight line and a curved line. 2. The prefabricated support block of claim 1, wherein the groove part accommodating the heat medium circulation pipe is provided with a heat conductive member for heat conduction from the heat medium circulation pipe accommodated therein. In the floor structure installed on the building slab, A sound insulation mat installed to face the building slab, Prefabricated support block as specified in any one of claims 1 to 4 which are installed to face the sound insulating mat upper surface, A heat medium circulation pipe inserted into a groove of the support block; Compression nonwoven fabric laminated so as to face the upper portion of the support block is the heat medium circulation pipe, Floor structure using the prefabricated support block with improved sound insulation, characterized in that it comprises a floor finishing material laminated to face the upper surface of the compressed nonwoven fabric. The floor structure of claim 5, wherein the sound insulation mat is a composite material having a lower PVC layer and an upper compressed fiber layer. The floor structure according to claim 5, wherein the compressed nonwoven fabric is further laminated with a heat storage layer configured to receive heat radiated from the heat medium circulation tube and accumulate heat. The floor structure according to claim 5, wherein the floor finishing material has a soundproof sheet of rubber material for noise shielding is installed under the floor finishing material. In the method of constructing a floor structure on the upper surface of the building slab, Installing a sound insulation mat to shield noise on the building slab; Prefabricating the supporting block specified in any one of claims 1 to 4 so as to face the upper surface of the installed sound insulation mat; Piping a heat medium circulation pipe to an upper groove of the assembled support block; Installing a compressed nonwoven fabric to face the upper portion of the support block on which the heat medium circulation pipe is mounted; The method of constructing a floor structure using a prefabricated support block with improved soundproofing effect comprising the step of laminating a floor finishing material to face the upper surface of the compressed nonwoven fabric. The method according to claim 9, wherein the upper surface of the non-woven fabric to be installed further comprises a step of forming a soundproofing effect prefabricated supporting block characterized in that the heat storage layer facing the heat storage heat radiation from the heat medium circulation tube facing the Construction method of used floor structure. 10. The method of claim 9, wherein the step of installing the sound insulating sheet of the rubber material for shielding noise between the compressed non-woven fabric and the floor finish further comprises the construction of the floor structure using the prefabricated support block with improved sound insulation effect Way.

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