KR101744948B1 - Floor structure for sound insulation in building - Google Patents

Abstract

The present invention provides a support panel comprising: a support panel which is arranged to maintain a gap from an upper surface of a slab defining a layer of a house and has a plurality of seating grooves on the bottom; A buffer member interposed between the support panel and the slab and movably supporting the support panel in a vertical direction and restraining a downward motion of the support panel to a set value or less; And a flooring supported by the buffering portion and forming a bottom surface of the room, wherein the buffering portion comprises: a supporting rail mounted on the upper surface of the slab; A plurality of elastic blocks arranged on the support rail with a gap therebetween; A case disposed in a space between the elastic blocks and provided with a plurality of supporting members capable of retracting; A fixing operation portion for fixing the elastic block to the support rail; And a separating portion for releasing the restraining state of the fixing operation portion to convert the elastic block into a flowable state, wherein the flooring comprises: (a) seating a panel member on a first mold having a seating recess; (b) moving the second mold, which is stacked on the first mold and has a mounting hole portion opposed to the mounting groove portion, in a lateral direction to separate the mounting groove portion and the mounting hole portion from each other; (c) filling the urethane foam resin into the seating groove and the accommodation hole and foaming the foam to form a cushioning member integrally formed with the panel member; And (d) separating the second mold from the cushioning member by separating the second mold into a plurality of blocks, and discharging the flooring material from the seating recessed portion.

Description

[0001] FLOOR STRUCTURE FOR SOUND INSULATION IN BUILDING [0002]

More particularly, the present invention relates to a sound insulation floor structure between buildings. More particularly, the present invention relates to a sound insulation floor structure between buildings, and more particularly, And it is possible to reduce the time and cost required for the construction of the sound insulating floor structure, to prevent noise between the floor by canceling the impact applied to the floor of the room, to reduce the heat loss, The present invention relates to a structure interlayer sound insulation floor structure capable of producing a continuous operation of a flooring material.

Generally, a typical construction method of two or more stories such as an apartment or a residential house is performed by constructing a concrete slab according to the number of the buildings, completing the foundation work, and then arranging heating pipes on the concrete slab at regular intervals Gravel and cement mortar with a predetermined thickness.

Thus, slabs dividing layers and layers of multi-layered multi-storey buildings such as apartments, high-rise buildings, etc., are constructed only by concrete, so that vibration due to noise and impact generated in the corresponding layer of the building is directly transmitted through the inter- .

In general, the impact sound applied to the building structure of apartment houses or villas is transmitted to the four sides of the building due to the impact of the person's walking, opening and closing of the door, moving of the equipment, Thereby causing the surface of the building structure to vibrate, as well as being converted into an air transmission sound, which is perceived as noise when it is heard by people around the ear.

For example, a sound such as a falling object is applied to the floor or a sound of moving a chair generates a solid sound, and the sound transmitted through the floor slab to the lower layer is referred to as interlayer noise.

Nowadays, this kind of interstory noise problem is seriously arising in a multi-family house, and the government announced that it will impose a penalty by applying the crime of disturbance of the misdemeanor punishment law to the interstice noise induction act, and even the stranger noise, And the regulations on housing construction standards, etc. have been strengthened and revised.

The above provisions stipulate that floor impact sound between each floor should be less than 58 decibels (dB) for light impact sound, 50 dB (dB) or less for heavy impact sound, or standard floor structure notified by the Minister of Construction and Transportation.

Conventional interlayer floor structures for minimizing the interlayer noise so as to reduce the severely interlayer noise are proposed. In the conventional interlayer floor structure, a lightweight foamed concrete layer is formed on the basis of a concrete slab, A heating pipe and a mortar layer for finishing, and a floor decoration layer made of a decorative material such as monolith, wood, or tile.

However, the above-mentioned interlayer bottom structure is responsible for attenuating the noise by the lightweight foamed concrete layer formed on the concrete slab, but it is not able to properly absorb or block the noise such as the light impact sound and the heavy impact sound.

Therefore, when the building is constructed with such a conventional floor structure, for example, the noise and vibration caused by the impact applied to the floor due to the children running upstairs are directly transmitted to the lower layer, resulting in a significant deterioration in the comfort of the building.

As a result, many kinds of interlayer noise-proofing materials have been developed in order to more effectively block noise or impact. However, since all of them are closely attached to the concrete slab surface of the apartment house, the noise-blocking effect is not significant.

For example, the conventional interlayer noise preventing material has a disadvantage in that noise is not blocked because the lightweight foamed concrete and the mortar are laid on the slab surface of the apartment house mainly by the styrofoam heat insulating material or other synthetic resin foam sheet.

In addition, an interlayer noise preventing material using rubber chips and foamed polyester obtained by pulverizing waste tires has been used, but it has not been popularized because it can not be mass-produced in reality and is not economical.

In other words, waste tires, which are the raw material of rubber bodies, have advantages of easy recycling as well as recycling of resources. However, they are scattered all over the country, so that logistics cost is high in collecting and selective utilization rate due to bead wire The manufacturing cost of the rubber chip is inevitably high.

In order to have such a function as the interlayer noise preventing material of the rubber chip, it is necessary to impregnate tar and to adhere foamed polyester having an appropriate thickness to one side or both sides thereof. However, This is also pointed out as a cause of price increase because it takes a lot of adhesive and it is applied only to some high-grade houses due to expensive unit price, but it is not widely spreaded. Since manufacturing facilities are also not economical, This is not the case.

In addition, the interlayer noise preventing material using the rubber chip and the foamed polyester uses the pore, the restoring force and the elasticity, and since the thicker the thickness is, the higher the effect is obtained, the thickness is thick to obtain the noise prevention effect as necessary for the residential use The interior space is taken away by that much. Since the layered noise preventing material of this structure is divided into plate type due to the characteristics of the material, it is inconvenient for handling and storage because it can not be formed in a long length during manufacture, and construction work is very troublesome .

BACKGROUND ART [0002] The background art of the present invention is disclosed in Korean Patent Registration No. 10-1323476 (published on October 31, 2013, entitled " Layer-to-Sound Noise Suppression Material for Building, " .

Since the conventional interlayer noise preventing material is interposed between the slab and the bottom finishing material, there is a problem that the impact can not be sufficiently canceled due to the action of compressing or expanding the interlayer noise preventing material when an impact generating the interlayer noise is applied.

In addition, since the conventional interlayer noise preventing material does not have a separate technical structure for performing the buffering action, there is a problem that when the floor is applied to the indoor floor of the apartment house, the interlayer noise may be generated.

In addition, since the conventional layered sound-deadening material does not have a separate technical structure for connecting a plurality of flooring materials to each other, a gap may be generated between the flooring material and the flooring material when a plurality of flooring materials are successively applied.

Therefore, there is a need for improvement.

In the present invention, the shock that causes the interlayer noise is first canceled by the operation of the buffer portion, the second offset is performed by the buffer mat, the noise transmission is prevented by the sound insulating sheet, and the time and cost The flooring material having the connecting protrusions and the connecting recesses can be used as a building interlayer sound insulating floor structure capable of producing a continuous operation, The purpose is to provide.

The present invention provides a support panel comprising: a support panel which is arranged to maintain a gap from an upper surface of a slab defining a layer of a house and has a plurality of seating grooves on the bottom; A buffer member interposed between the support panel and the slab and movably supporting the support panel in a vertical direction and restraining a downward motion of the support panel to a set value or less; And a flooring supported by the buffering portion and forming a bottom surface of the room, wherein the buffering portion comprises: a supporting rail mounted on the upper surface of the slab; A plurality of elastic blocks arranged on the support rail with a gap therebetween; A case disposed in a space between the elastic blocks and provided with a plurality of supporting members capable of retracting; A fixing operation portion for fixing the elastic block to the support rail; And a separating portion for releasing the restraining state of the fixing operation portion to convert the elastic block into a flowable state, wherein the flooring comprises: (a) seating a panel member on a first mold having a seating recess; (b) moving the second mold, which is stacked on the first mold and has a mounting hole portion opposed to the mounting groove portion, in a lateral direction to separate the mounting groove portion and the mounting hole portion from each other; (c) filling the urethane foam resin into the seating groove and the accommodation hole and foaming the foam to form a cushioning member integrally formed with the panel member; And (d) separating the second mold from the cushioning member by separating the second mold into a plurality of blocks, and discharging the flooring material from the seating recessed portion.

In addition, the step (d) of the present invention may include: a first block that is seated on the upper surface of the first mold and is bent in an 'C' shape; And a second block which is bent in the shape of 'A' so as to form the fixing hole at the center when the first block is disposed adjacent to the first block.

The present invention also provides a mold comprising: a third mold having a molding hole portion opposed to the mounting hole portion and seated on the second mold; And a finishing block that is seated on the upper surface of the third mold to close the forming hole.

In the flooring structure between layers of a building according to the present invention, the shock which causes the interlayer noise is canceled first by the operation of the buffer part and the interlayer noise is canceled by the buffer mat by the second order, It is possible to effectively prevent the interlayer noise from being transmitted through the antenna.

In addition, in the structure-to-floor sound insulation floor structure according to the present invention, since the supporting frame supported by the plurality of supporting blocks in a vertically movable manner supports the supporting panel, it is possible to move the supporting panel without the elastic member having a size covering the entire bottom surface And the impact generated by the flow of the support panel can be canceled by the elastic member, thereby effectively preventing the interlayer noise.

In addition, since the plurality of support rods are installed so as to protrude / retract from the case, the support floor and the mounting plate can be easily accommodated even if the support rods are housed in the space between the elastic blocks at random, So that it is advantageous in that the floor structure can be easily installed.

In addition, since the flooring sound insulation floor structure according to the present invention forms a buffer member integrally formed with the panel member by foaming the urethane foam resin into the mold after positioning the panel member in the recessed groove portion of the mold, There is an advantage that it is possible to easily manufacture a floor material that can be reduced.

In addition, the structure-to-layer sound insulation floor structure according to the present invention can easily form the flooring having the connecting protrusions and the connecting recesses by easily molding the buffering member having the connecting protrusions and the connecting recesses by the single mold operation, There is an advantage to be able to do.

In addition, since the flooring structure between layers of buildings according to the present invention is manufactured by the mold apparatus having the spacing drive unit for pressing and projecting the central portion of the buffer member to one side, the connection protrusion and the connection groove unit can be easily formed There is an advantage.

1 is a cross-sectional view illustrating a structure-to-building sound insulation floor structure according to an embodiment of the present invention.
FIG. 2 is a plan view illustrating a structure-to-building sound insulation floor structure according to an embodiment of the present invention.
3 is a perspective view illustrating a buffering portion of a flooring structure between layers of a building according to an embodiment of the present invention.
FIG. 4 is a cross-sectional view illustrating a support block and a support structure connection structure of a floor structure between layers of a building according to an embodiment of the present invention.
FIG. 5 is a perspective view illustrating a case and a support of a structure-to-building sound insulation floor structure according to an embodiment of the present invention.
6 is a cross-sectional view illustrating a case and a support of a flooring structure between layers of a building according to an embodiment of the present invention.
FIG. 7 is a perspective view illustrating a floor material of a flooring structure between layers of a building according to an embodiment of the present invention. FIG.
FIG. 8 is a perspective view illustrating a mold opening state of the flooring manufacturing apparatus of the flooring structure between layers of a building according to an embodiment of the present invention. FIG.
9 is a cross-sectional view illustrating a floor panel member insertion state of a flooring structure between layers of a building according to an embodiment of the present invention.
10 is a cross-sectional view illustrating a separation operation of the flooring material manufacturing method of a flooring structure between layers of a building according to an embodiment of the present invention.
FIG. 11 is a cross-sectional view illustrating a second mold release state of a floor material manufacturing method of a flooring structure between layers of a building according to an embodiment of the present invention.
FIG. 12 is an exploded perspective view illustrating the construction of flooring of a building-to-building sound insulation floor structure according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an embodiment of a building-to-building sound insulation floor structure according to the present invention will be described with reference to the accompanying drawings.

In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation.

In addition, the terms described below are terms defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator.

Therefore, definitions of these terms should be made based on the contents throughout this specification.

FIG. 1 is a sectional view illustrating a floor structure for inter-building sound insulation between buildings according to an embodiment of the present invention. FIG. 2 is a plan view illustrating a floor structure for inter-building sound insulation between buildings according to an embodiment of the present invention. 1 is a perspective view of a buffering portion of a building-to-building sound insulation floor structure according to an embodiment.

4 is a cross-sectional view illustrating a support block and a support connection structure of a floor structure between layers of a building according to an exemplary embodiment of the present invention. FIG. 5 is a cross- FIG. 6 is a cross-sectional view illustrating a case and a support of a structure-to-building sound insulation floor structure according to an embodiment of the present invention.

FIG. 7 is a perspective view illustrating a floor material of a flooring structure between layers of a building according to an embodiment of the present invention. FIG. 8 is a cross- And FIG. 9 is a cross-sectional view illustrating a floor panel member insertion state of a building-to-floor sound insulation floor structure according to an embodiment of the present invention.

10 is a cross-sectional view illustrating a separating operation of the flooring material manufacturing method of a flooring structure between layers of a building according to an embodiment of the present invention. FIG. 11 is a cross- And FIG. 12 is an exploded perspective view showing a bottom material manufacturing process of the interlayer sound insulation floor structure according to the embodiment of the present invention.

1 to 12, a structure-to-building sound insulation floor structure according to an embodiment of the present invention is arranged so as to maintain an interval from an upper surface of a slab 1 partitioning a layer of a house, A support panel 50 provided between the support panel 50 and the slab 1 and supporting the support panel 50 so as to be vertically movable and having a lowering motion of the support panel 50; And a floor member 10, 12, 20 which is supported by the buffering portion 30 and constitutes the floor of the room.

The support panel 50 is stacked on the upper surface of the buffer part 30 and the upper surface of the support panel 50 is provided with the buffer part 30 on the upper surface of the slab 1, Flooring is applied.

Accordingly, when the impact is transmitted to the floor material while the person is running or carrying heavy objects on the upper side, the support panel 50 is moved downward by the shock absorbing part 30 in this embodiment to cancel the impact transmitted from the floor material.

The cushioning portion 30 includes a support rail 32 that is seated on the upper surface of the slab 1, a plurality of elastic blocks 36 that are spaced apart from the support rail 32, A fixing operation part 110 for fixing the elastic block 36 to the support rail 32 and a fixing part 130 for fixing the elastic block 36 to the fixing operation part 110. [ And a separating portion 120 for releasing the restricting state to convert the elastic block 36 into a flowable state.

A plurality of rails 32 including a first rail 32a and a second rail 32c are arranged on the upper surface of the slab 130 in a lattice shape and a first rail 32a on which a guide protrusion 32c is formed, So that a plurality of elastic blocks are spaced apart from each other.

The pair of guide grooves 36a extending from the bottom surface of the elastic block 36 is formed in the elastic block 36 so that the guide protrusion 32c of the first rail 32a is inserted into the guide groove 36a, ).

At this time, the elastic blocks 36 are arranged at intervals between the grid-shaped rails, and the elastic blocks 36 and 36 are arranged such that the supports 34 and the case 130 are disposed at intervals between the elastic blocks 36 and 36 ).

An elastic body 136 having a stopper 34b formed at an inner end portion of a plurality of support rods 34 is installed at a central portion of the case 130. A protrusion protrusion formed at a central portion of the support roster 34, And protrudes outwardly of the protrusion guide 132 by the second elastic member 128 interposed between the inner walls of the guide 132.

The fixed operating portion 110 includes a restricting projection 114 that protrudes and retracts from the elastic block 36 into the guide groove 36a and a guide projection 32c and a fixed hole portion 32d that are opposed to the restricting projection 114 A first rail 32a provided on the upper surface of the slab 10 and a plurality of guide hole portions 32d formed on the guide protrusion 32c so that the restricting protrusion 114 is inserted.

A restricting projection 114 is provided on the inside of the guide groove 36a of the elastic block 36 so as to protrude and retract inside the guide groove 36a and a protrusion formed at the center of the restricting protrusion 114 And the first elastic member 116 is interposed between the protruding portion formed on the inner side of the restricting protrusion 114 and the protruding guide end so that the restricting protrusion 114 protrudes from the protruding guide 132).

Therefore, the operator can vary the position of the elastic block 36 while sliding the elastic block along the first rail, and the elastic block 36 fixed at the predetermined position is guided by the guide protrusion 32c protruding toward the guide groove 36a. Is inserted into the fixing hole portion 32d formed in the first rail 32a to prevent the elastic block 36 from flowing.

The present embodiment is provided with a separating portion 120 for releasing the restraint state of the fixed operating portion 110 and releasing the restraint of the elastic block 36. The separating portion 120 is disposed outside the elastic block 36 A pushing slope 124 formed at the inner end of the knob 122 and a rising slope 126 formed at the inner side of the restraining protrusion 114 so as to face the pushing slope 124, And a second elastic member 128 installed to press the knob 122 inside the elastic block 36.

When the operator grips the elastic block 36 and presses the knob 122 to the inside of the elastic block 36, the knob 2 is inserted into the elastic block 36 so that the pressure sloped surface 124 is located inside the guide groove 36a And the pressing slope 124 pushes up the slope 126 to lift the restricting protrusion 114 into the first elastic member 128 to release the restricting state of the elastic block 36. [

A second elastic member 128 is provided at the center of the knob 2 to push the knob 122 outwardly of the elastic block 36 to hold the elastic block in a restrained state.

The bottom material according to the present embodiment includes a step of placing the panel member 212 on the first mold 330 having the seating groove 332 and the step of stacking the panel member 212 on the seating groove 332 A step of moving the second mold 350 provided with the mounting hole 352 in the lateral direction to separate the mounting groove 332 and the mounting hole 352 from the mounting groove 332 and the mounting hole 352; Molding the cushioning member 220 which is formed integrally with the panel member 212 by filling and foaming the urethane foamed resin, separating the second mold 350 into a plurality of blocks and separating the cushioning member 220 from the cushioning member 220 , And discharging the bottom material from the seating groove (332).

The third mold 370 is lifted or lowered by the operation of the lifting and lowering driving unit 386 so that the third mold 370 is raised so that a gap is formed between the second mold 350 and the third mold 370 The panel member 210 can be inserted into the seating groove portion 332 at an interval between the second mold 350 and the third mold 370.

The second mold 350 includes a first block 358a which is placed on the upper surface of the first mold 330 and is curved in an ' And a second block 358b bent in an 'a' shape so as to form a stationary hole portion 352. [

The first block 358a and the second block 358b are each formed with an inclined surface 354 at an outer edge thereof to connect the spacing drive unit 380. The spacing drive unit 380 is disposed on the inclined surface of the first block 358a 354 and a second spacing cylinder 384 connected to the slope 354 of the second block 358b.

Accordingly, when the rod is projected from the first spacing cylinder 382 and the second spacing cylinder 384, both end portions of the first block 358a and the second block 358b are closely attached to each other and a rectangular embossed hole portion 352 .

When the rod is projected from the first spacing cylinder 382 while both ends of the first block 358a and the second block 358b are in close contact and the rod is inserted into the second spacing cylinder 384, The entire second mold 350 is protruded to the outside of the first mold 330 and the third mold 370 while the both ends of the second block 358a and the second block 358b are kept in close contact with each other, The hole portion 372 and the mounting hole portion 352 are spaced apart.

When the second mold 350 is moved in the lateral direction, grooves for forming the connecting protrusions 322 are formed on two side surfaces of the central portion of the work space in which the urethane foamed resin is filled, The connection groove portion 324 is formed.

The filler material to be filled in the mold by the injection hole portion is made of a metal material and is formed to have a thickness of 200 mesh or less, The heat conductivity is higher than that of the flooring according to the prior art.

As described above, when the thermal conductivity of the floor material is high, when thermal energy is supplied from the floor of the room when the heating operation is performed, it can be understood that the thermal energy transmitted from the floor of the room can be more easily conducted by the action of the conductive member 226 .

Since the urethane foam resin constituting the buffer member 220 has a plurality of pores 228 formed therein when expanded and hardened, when the impact is transmitted to the surface of the bottom material, the pores 228 are compressed, do.

The flooring material produced by the above-described manufacturing method is formed of a panel having a rectangular shape, and the 'b' shaped connecting protrusions 222 are formed on a pair of side surfaces adjacent to each other, When the plurality of floor members are successively installed, the connection groove portion 224 is inserted into the connection groove portion 224 of another floor member disposed adjacent to the connection groove portion 224, .

Reference numerals 386a and 386b denote a first elevating cylinder 386a and a second elevating cylinder 386b constituting an elevation driving unit 386. The third metal mold 330 is provided with supporting members extending laterally on both sides thereof , And the pair of supports is raised or lowered by the first elevating cylinder 386a and the second elevating cylinder 386b installed on the ground or the base block.

Thereby, the impact that causes the interlayer noise is canceled first by the operation of the buffer portion, the second order cancellation is performed by the buffer mat, the noise transmission is prevented by the sound insulating sheet, and the time and cost required for the construction of the sound insulating floor structure The present invention relates to a structure for interlayer sound insulation floor structure capable of reducing the impact applied to the floor of the room to prevent noise from the floor, reducing the heat loss, and providing the flooring material having the connecting protrusions and the connection grooves as a continuous operation. .

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. .

In addition, the present invention has been described by taking the sound insulation floor structure between buildings as an example, but this is merely an example, and the floor structure of the present invention can be used for other products other than the sound insulation flooring structure between buildings.

Accordingly, the true scope of the present invention should be determined by the following claims.

1: Slab 30: Buffer
32: support block 32a: curved surface groove portion
34: support plate 34a:
34b: pressing surface 36: elastic block
50: Support panel 80: Cement mortar layer
90: Surface finish layer

Claims (3)

A support panel disposed to maintain a gap with an upper surface of a slab defining a layer of the apartment house, and having a plurality of seating grooves on a bottom surface thereof;
A buffer member interposed between the support panel and the slab and movably supporting the support panel in a vertical direction and restraining a downward motion of the support panel to a set value or less; And
And a flooring supported by the buffering portion and constituting a bottom surface of the room,
The buffering portion
A support rail seated on an upper surface of the slab;
A plurality of elastic blocks arranged on the support rail with a gap therebetween;
A case disposed at an interval between the elastic blocks and provided with a plurality of supporting members capable of retracting;
A fixing operation portion for fixing the elastic block to the support rail; And
And a separating section for releasing the restraining state of the fixed operating section to switch the elastic block to a flowable state,
The floor member
(a) placing a panel member on a first mold having a seating groove;
(b) moving the second mold, which is stacked on the first mold and has a mounting hole portion opposed to the mounting groove portion, in a lateral direction to separate the mounting groove portion and the mounting hole portion from each other;
(c) filling the urethane foam resin into the seating groove and the accommodation hole and foaming the foam to form a cushioning member integrally formed with the panel member; And
(d) separating the second mold from a plurality of blocks, separating the second mold from the buffer member, and discharging the floor material from the seating groove portion.
The method of claim 1, wherein the step (d)
A first block that is seated on the upper surface of the first mold and is bent in an 'a'shape; And
And a second block that is bent in the shape of 'A' so as to form the fixing hole portion at a central portion when disposed adjacent to the first block.
3. The method of claim 2,
A third mold having a molding hole portion opposed to the mounting hole portion and seated on the second mold; And
And a finishing block that is seated on the upper surface of the third mold to close the molding hole.

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