KR102076943B1 - Floor structure for noise prevention between layers - Google Patents

Abstract

An objective of the present invention is to provide a floor structure for reducing noise between floors which maximally suppresses impact noise and effectively absorbs created noise by quick construction as a flooring material on the floor of a building such as an apartment house and a townhouse to maximize suppression of noise between floors. To achieve the objective, the floor structure for reducing noise between floors allows a sound-absorbing buffer unit (250) correspondingly formed on a lower structure (200) of an elastic rubber material for stably supporting a noise transfer unit (150) for transferring impact noise applied to an upper structure (100) of a rigid reinforced plate commercially injection-molded as a laminate component to stretch and deform an impact and absorb and minimize noise when noise is secondarily discharged by an air layer filled therein.

Description

Floor structure for noise prevention between layers

The present invention relates to a floor structure utilized as a building flooring material, and more particularly, as a flooring material of apartment buildings and multi-family houses or complex buildings, and maximizes sound absorption and sound insulation functions such as shock and vibration to maximize floor noise. The present invention relates to a floor structure for reducing noise between floors.

Recently, floor noise generated in apartments and apartments has emerged as a serious social problem, such that disputes between neighbors extend beyond violence to arson, fire, and murder.

In a recent survey of apartment dwellers, 79% were stressed by floor noise, 9% were stressed by frequent protests, and 88% of all respondents were interstitial. The noise was stressed out.

These noise levels were found to occur in 80.4% of apartments, 12.8% of multi-family houses, and 6.1% of townhouses.

In addition, the main causes of the noise between floors were the children's footsteps and running sounds (73.5%), hammer thumps (4%), furniture pulls (2.3%), musical instruments (2.3%), Home appliances (2.1%) and other (15.8%) were surveyed.

The form of tremor and hitting noise caused by the noise of children running or moving objects, which is the cause of the above-mentioned floor noise, can be generally reduced by raising the floor height, but the most common structure is to finish the soundproof panel structure on the slab and finish it. It is to provide a floor structure for reducing the noise between the layers to provide some relief by the structure.

If you look at some representative floor structures to reduce the noise and vibration between floors,

Structures in which plate materials are laminated, such as forming hollow portions between the plates, or honeycomb structures and structures applying rubber materials are known, and holes and holes are formed in the structure to further reduce noise, thereby making noise and vibration at the resonance frequency of the structure. Excitation is prevented from expanding and the effect of air bonding is reduced to increase transmission loss.

Various techniques are proposed conventionally like patent documents 1-4 about the technique for preventing such interlayer noise.

In Patent Literature 1, a technique for double bottom structure is disclosed by an anti-vibration insulation module plate in which a lattice rib is integrally formed in a suitable shape on an upper portion of a thin plate, and an anti-vibration rubber and a heat insulating material are integrally assembled in the lower portion.

This patent document 1 is utilized as an internal component for the construction of a double-floor structure of a building including a slab layer of the lower layer and a finishing mortar layer in which the heating pipes of the upper part are embedded, so that the impact applied to the finishing mortar layer of the upper part is elastically applied. There is a limitation that the sound absorption function for impact noise is weak because it cannot be buffered, and it is not applicable to the floor of an already constructed building.

In addition, Patent Document 2, by combining the upper plate on which the heating pipe pipe is seated on the lower support plate having the filling grooves filled with the sound-absorbing heat insulating material, the plurality of vertical

It is proposed to assemble on a plurality of mortars on the cement floor between multi-storey houses or apartments composed of floors, install heating pipes on top of them, and finish with finishing mortars.

In Patent Document 2, as in Patent Document 1, the sound absorbing function for the sounding is provided by the sound absorbing insulation material of the lower support plate, which provides the sound absorbing effect from the upper limit mortar layer and the limit point that can be applied to the internal component during construction of the building. This has a minor drawback.

In addition, Patent Document 3 can simultaneously block and absorb airborne sound propagated through air generated in a common house such as an apartment and solid radio waves propagated through a structure such as a floor, and can effectively disperse residual noise. The prefabricated interlayer noise blocking block is planned.

However, Patent Document 3 is a block for assembling and constructing a plurality of residual noise dispersing members and supporting members whose construction thicknesses correspond to the heights of the through-holes corresponding to the noise absorbing member and the residual noise absorbing member. In construction, the thickness is too large, and it is also unreasonable to use in the already constructed building.

In addition, Patent Literature 4 forms a unit chamber interposed between the upper cover panel and the lower cover panel, and the edge portion of the support panel, the upper cover panel and the support panel and the lower cover panel made of an egg plate structure to be arranged alternately radially It consists of a finish to seal and form a sandwich panel.

Such Patent Document 4 also has a limited thickness structure in construction, there is a limit to be constructed as a finishing material at the time of construction of the building.

In addition, there is a disadvantage in that the construction cost increases as the overall volume increases and the manufacturing cost increases.

1.Registered Korea Registration No. 20-0433792 (December 6, 2006) 2. Korean Registered Patent No. 10-1407185 (2014.06.05. Registered) 3. Korea Patent Registration No. 10-1641218 (registered Jan. 14, 2016) 4. Korean Patent Publication No. 10-2018-0056036 (published May 28, 2018)

The present invention was developed to solve the disadvantages of the prior art as described above, the floor structure for reducing noise between floors of the present invention impact noise by the rapid construction as a flooring on the floor of the building, such as apartments, town houses, etc. It is aimed at maximizing the suppression of interlayer noise by suppressing the maximum noise and effectively absorbing and attenuating the generated noise.

In addition, an object of the present invention is to provide a modular structure with excellent productability by providing a range of thickness of the floorboard that can be installed on the floor of the pre-built building to minimize the noise between floors.

Moreover, an object of the present invention is to provide a mass production structure by industrial injection molding as a simple structure.

In order to achieve the above object, in the floor structure for reducing the interlayer noise of the present invention, the upper structure, the impact noise applied to the upper structure, provides a sound absorbing and sound absorption at the same time through the shock absorbing structure and the lower structure of the lower structure, the interlayer noise. It is characterized in that it is configured to suppress the maximum.

In other words, the present invention is a laminated structure configuration, the sound absorbing shock absorbing portion formed corresponding to the lower structure of the elastic rubber material that stably supports the noise transmission unit for transmitting the impact noise applied to the upper structure of the industrially molded hard reinforced plate material When it is stretched and deformed and the noise is discharged secondly by the inside of the filled air layer, it absorbs and attenuates and minimizes the noise.

In a specific configuration, a preferred embodiment of the present invention,

The upper surface portion in the state in which the widthwise covering portion and the longitudinal covering portion protrude along the sides of the width direction and the longitudinal direction on one side, and the widthwise support portion and the lengthwise direction formed on the bottom surface of the upper surface portion and opposing the respective covering portions. The decorative body is formed in the diagonally opposite direction of the support portion formed by the rectangular border wall formed on the lower portion of the decorative body, protruding a plurality of noise transmission parts protruding from the bottom surface of the upper surface portion inside the first housing portion One superstructure;

Insertion border wall protruding thereon so as to be fitted to the rectangular rim wall inside the first enclosure of the decorative body, the lower support portion formed therein the second enclosure by the insertion border wall, the lower support portion inside the A support body having a widthwise support portion and a longitudinal support portion protrudingly formed corresponding to the widthwise covering portion and the longitudinally supporting portion as the fitting edge wall while protruding the corresponding sound absorbing buffer portion supporting the noise transmitting portion. And a support edge wall formed by forming an air flow hole at a predetermined interval in a state of integrally protruding to the bottom edge of the lower support portion and each support support portion, the air being formed by the support edge wall and communicating with the second housing portion. A substructure having a sound absorbing body portion communicating with the ball; Characterized in that it comprises a.

According to the present invention, the noise transmission part is protruded into a conical shape formed at the tip of the tip, and the sound absorbing shock absorbing portion is formed as a cone shape of the upper and lower light absorbing shock absorbing grooves for accommodating a part of the outer circumferential surface of the noise transmitting part 150. It is characterized by.

According to a preferred embodiment of the present invention, the impact sound or vibration due to the impact applied to the upper structure by the load or impact is distributed and transmitted through each of the cone-shaped noise transmission protrusion protruding to the bottom surface of the upper surface of the decorative body, The impact sound and the vibration sound are first absorbed by the cone-shaped sound absorbing buffer parts protrudingly formed on the upper part of the lower support part of the supporting body of the lower structure while being compressed and compressed air at the same time through the air outlet grooves at the sound absorbing buffer grooves of the sound absorbing buffer parts. At the same time as the discharge is discharged through the air discharge hole in the space enclosed by the first housing portion and the second housing portion and the second sound absorbing and flows through the air flow hole (261) in the sound absorbing enclosure portion of the support rim wall, It is characterized by attenuation.

Another embodiment of the present invention,

The upper surface portion in the state in which the widthwise covering portion and the longitudinal covering portion protrude along the sides of the width direction and the longitudinal direction on one side, and the widthwise support portion and the lengthwise direction formed on the bottom surface of the upper surface portion and opposing the respective covering portions. A decorative body in which a supporting part is formed in a diagonally opposite direction and formed with a first frame part formed by a rectangular rim wall formed at a lower part thereof, and a sound absorbing buffer groove having a cone shape of lower narrow light at the bottom of the upper surface part inside the first housing part. Is formed and the sound absorbing buffer groove is an upper structure protruding a plurality of noise transmission portion formed with a plurality of air outlet grooves at regular intervals in the vertical direction on the inner peripheral surface,

Insertion border wall protruding thereon so as to be fitted to the rectangular rim wall inside the first enclosure of the decorative body, the lower support portion formed therein the second enclosure by the insertion border wall, the lower support portion inside the A cone-shaped sound absorbing buffer portion having a tip portion formed with a sharp tip portion to support the noise transmitting portion protrudes correspondingly, and a widthwise support portion protrudingly formed in correspondence to the widthwise covering portion and the longitudinal supporting portion as the fitting edge wall and the longitudinal direction. A support frame having a support body, and a support frame wall formed by forming a certain air flow hole at a predetermined interval in a state of integrally protruding to the bottom edge of the lower support portion and each support support, and formed by the support frame wall 2 consists of a substructure formed with a sound absorbing body portion communicating with the air discharge hole communicating with the enclosure,

The impact sound or vibration caused by the impact applied to the upper structure by the load or the impact is distributed and transmitted through each of the cone-shaped noise transmission parts of the decorative body, and the impact sound and the vibration sound are primarily supported by the sound absorbing buffer portion of the lower support portion of the lower structure. At the same time, the compressed air is discharged through the air outlet groove from the sound absorbing buffer groove of each noise transmitting unit, and is discharged through the air outlet in the space enclosed by the first and second enclosures, It is characterized in that the sound absorbing, attenuating while flowing through the second sound absorbing and air flow hole in the sound absorbing body portion of the wall.

Another embodiment of the present invention,

The upper surface portion in the state in which the widthwise covering portion and the longitudinal covering portion protrude along the sides of the width direction and the longitudinal direction on one side, and the widthwise support portion and the lengthwise direction formed on the bottom surface of the upper surface portion and opposing the respective covering portions. The decorative body is formed in the diagonally opposite direction of the support portion formed by the rectangular border wall formed at the lower portion of the decoration body, protruding a plurality of noise transmission parts protruding from the bottom surface of the upper surface portion inside the first housing portion One superstructure;

Insertion border wall protruding thereon so as to be fitted to the rectangular rim wall inside the first enclosure of the decorative body, the lower support portion formed therein the second enclosure by the insertion border wall, the lower support portion inside the A support body having a widthwise support portion and a longitudinal support portion protrudingly formed corresponding to the widthwise covering portion and the longitudinally supporting portion as the fitting edge wall while protruding the corresponding sound absorbing buffer portion supporting the noise transmitting portion. And a support edge wall formed by forming an air flow hole at a predetermined interval in a state of integrally protruding to the bottom edge of the lower support portion and each support support portion, the air being formed by the support edge wall and communicating with the second housing portion. A substructure having a sound absorbing body portion communicating with the ball; And,

The bottom wall is formed on the upper surface of the bottom plate by a grating of the left and right, before and after the rim wall support groove for supporting the support rim wall of the support body and the air flow path grooves corresponding to the air discharge hole and providing air flow Structures; Characterized in that it comprises a.

According to the present invention, the reliability of the product is ensured by the effect that the floor noise of the building as a floor noise, the impact noise and vibration noise as a floor noise can be buffered and absorbed in multiple stages to minimize the noise between floors.

Further, according to the present invention, the laminate of the decorative plate of the hard material of the upper layer and the support plate of the elastic buffer material of the lower layer, or the laminated plate assembly of the support plate of the hard material of the upper layer and the support plate of the elastic buffer material of the lower layer and the bottom plate of hard material It can be expected to actively use as flooring material for suppressing noise between floors of buildings by providing sound absorption while absorbing noise and shock formed in the inside and guiding air flow through multiple stages.

In addition, according to the present invention, it is possible to use as a flooring material that can be installed on the floor of the pre-built building, and can be applied to a limited thickness range of the flooring material according to the new construction, commercialization as a modular structure with excellent productability There is also.

1 is a perspective view of a preferred preferred embodiment of the present invention.
2 is a plan view of FIG. 1.
3 is an exploded perspective view of the superstructure and substructure of a preferred embodiment of the present invention.
4 is a bottom perspective view seen in the bottom direction of FIG. 3.
5 is an enlarged view illustrating an “F” portion of FIG. 3.
6 is an enlarged view of an excerpt "G" of FIG. 3.
7 is an enlarged view illustrating an “H” portion of FIG. 3.
8 is an enlarged view of an excerpt of the portion “I” of FIG. 4.
9 is a cross-sectional view taken along the line IV-IV of FIG. 2.
10 is an enlarged view of an excerpt "J" of FIG. 9.
FIG. 11 is a cross-sectional view taken along the line VV of FIG. 2.
12 is an enlarged view of an excerpt of the "K" part of FIG.
Figure 13 is a cross-sectional view illustrating the coupling of the superstructure and the substructure of the preferred embodiment of the present invention.
14 is a partially omitted assembled state sectional view showing a construction state of a preferred embodiment of the present invention.
15 is an enlarged view of an excerpt "L" of FIG. 14.
16 and 17 are partially enlarged cross-sectional views of the assembled state of the preferred embodiment of the present invention.
16 is a state diagram before the impact is applied to the superstructure,
17 is an operation of the deformation state by the buffer of the lower structure by the impact applied to the upper structure.
18 and 19 illustrate another embodiment of the present invention.
18 is an assembled state cross-sectional view of the surface sheet with a decorative pattern printed on the surface of the upper structure of the present invention,
19 is an enlarged view of an excerpt "M" of FIG. 18.
20 to 22 are still another embodiment of the present invention.
20 is an assembled cross-sectional view of the superstructure and the substructure,
FIG. 21 is an enlarged view of an “N” part excerpt of FIG. 20;
FIG. 22 is an enlarged view of a portion “N” of FIG. 20 showing operation of the substructure by impacting the superstructure. FIG.
23 to 25 are still another embodiment of the present invention.
23 is a perspective view of a separated state of the superstructure and the substructure,
24 is a bottom perspective view of a separated state of the upper structure and the lower structure,
25 is an assembled cross-sectional view of the superstructure and the substructure,
FIG. 26 is an enlarged view illustrating an “O” part of FIG. 25.
27 and 28 are partially enlarged cross-sectional view of the assembled state of another embodiment of the present invention,
27 is a state diagram before the impact is applied to the superstructure,
28 is an operation view of the deformed state by the buffer of the lower structure by the impact applied to the upper structure.
29 to 32 are still another embodiment of the present invention.
29 is a perspective view of the separated structure of the upper structure, the lower structure, the bottom structure,
30 is a bottom perspective view of the separated structure of the upper structure, the lower structure, the bottom structure,
31 is an assembled cross-sectional view of the upper structure, the lower structure and the bottom structure.
32 is an exploded cross-sectional view illustrating an assembly according to construction of another embodiment of the present invention disclosed in FIG. 29.
33 and 34 are partially enlarged cross-sectional views of the assembled state of another embodiment of the present invention disclosed in FIG. 29;
33 is a state diagram before the impact is applied to the superstructure,
34 is an operation view of the deformed state by the buffer of the lower structure coupled to the bottom structure by the impact applied to the upper structure.
35 is a plan view of a construction state extract according to the present invention.

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

In the description of the present invention, the structure and size of the components shown in the drawings may be simplified or simplified as long as the description of the invention is not a problem.

1 to 17 are views for explaining a preferred embodiment of the present invention with reference to these drawings with reference to the preferred embodiment of the present invention.

In the floor structure for reducing noise between layers of the present invention,

A laminated assembly of an upper structure 100 molded by industrial injection molding using a hard reinforced material, and a lower structure 200 molded by industrial injection molding by an elastic buffer synthetic rubber material to support the upper structure. Shock and vibration noise applied to the structure 100 is configured to absorb at the same time the shock absorber of the multi-stage while the lower structure 200 is buffered.

In other words, the present invention is formed in a laminate configuration corresponding to the lower structure 200 of the elastic rubber material so as to stably support the noise transmission unit 150 for transmitting the impact noise applied to the upper structure 200 of the hard reinforced plate material Sound absorbing shock absorbing unit 250 is to absorb the shock as the first expansion and contraction at the same time, the sound is absorbed and attenuated shock through the multi-stage of sound absorption and discharge by the air layer filled inside.

With reference to Figures 1 to 4, 9, and 11 with respect to the configuration of a preferred preferred embodiment of the present invention,

The upper structure 100 has an upper surface portion 120 in a state where the widthwise covering portion 121 and the longitudinal covering portion 122 protrude along the width direction and the lengthwise side of one side, and the bottom surface of the upper surface portion. A first edge formed by a rectangular border wall 130 formed in a lower portion of the widthwise supporting portion 131 and the longitudinal supporting portion 132 facing each other in the diagonal direction. In the state of protruding a plurality of noise transmission parts 150 protruding from the bottom surface of the upper surface portion 120 inside the decorative body 110, the first housing portion 140 formed the enclosure portion 140; Molded.

Here, referring to FIG. 10, the plurality of noise transmission units 150 are protruded and formed into a conical shape each of which is formed by a sharp portion, so that the impact or impact applied to the upper surface portion 120 of the decoration body 110. This is to transmit the noise such as vibration caused by the state of the sharp portion and to provide sound absorption attenuation by the air layer inside.

And the outer peripheral surface of the cone-shaped narrowly reduced tip is supported in a state in which the sound absorbing shock absorbing portion 260 of the substructure 200 to be described later seated, the noise or vibration caused by the impact of the stable support according to the lowering operation Etc. can be absorbed and attenuated.

3 and 4 and the enlarged portion of FIG. 5, the widthwise supporting portion 131 and the longitudinal supporting portion 132 of the decorative body 110 are each formed in a waveform at regular intervals on the upper surface in the longitudinal direction. The buffer line protrusions 133 and 134 are formed.

The lower structure 200 has a fitting rim wall 230 protruding from the upper portion to be fitted to the square rim wall 130 inside the first enclosure 140 formed in the decorative body 110 of the upper structure 100, The lower support part 220 having the second housing part 240 formed therein by the fitting edge wall, and the corresponding sound absorbing shock absorbing part 250 supporting the noise transmission part 150 in the lower support part is provided. At the same time as the protruding edge wall 230 is provided with a widthwise support portion 221 and a longitudinal support portion 222 protruded to correspond to the widthwise covering portion 121 and the longitudinal support portion 132 is provided. It is composed of a support body (210).

At this time, the support body 210 is a support frame wall 260 formed by forming the air flow hole (261) at a predetermined interval in the state protruded integrally formed on the bottom frame of the lower support portion 220 and the bottom support portion of each of the support (221 222). The sound absorbing body portion 270 is formed by the support rim wall and communicates with the air discharge hole 272 communicating with the second housing portion 240.

And the widthwise support portion 221 and the longitudinal support portion 222, referring to the enlarged portion of Figures 3 and 4 and 7, respectively, the buffer line projections formed in a waveform of a predetermined interval on the upper surface in the longitudinal direction ( 233) 234 are molded.

On the other hand, the first border portion 140 and the second enclosure portion 240 formed in each of the defects of the rectangular border wall 130 of the decorative body 110 and the fitting border wall 230 of the support body 210 The air part A1 is formed by the open part sealing.

In addition, the sound absorbing buffer 250 of the lower structure 200, as shown in the enlarged view of Figure 6, 10, the outer circumferential surface of the noise transmission unit 150 of the upper structure 100 in the cone shape of the upper and lower beams. The sound absorbing buffer groove 251 is partially accommodated, and the sound absorbing buffer groove 251 is formed with a plurality of air outlet grooves 252 at regular intervals in the vertical direction on the inner circumferential surface.

The sound absorbing buffer 250 is integrally formed at the bottom of the decorative body 110 on the inner circumferential surface of the upper end of the sound absorbing buffer groove 251, as shown in the enlarged operation of FIGS. Partial accommodating coupled to the cone-shaped noise transmission unit 150 in a seated state, when the noise transmission unit 150 is lowered by the external force applied to the decorative body 110, the sound absorbing buffer groove 251 is extended along the outer peripheral surface of the cone While deforming and cushioning, the internal air of the sound absorbing buffer groove 251 is naturally discharged by volume expansion (compression of the noise transmission unit) by a plurality of air outlet grooves 252 at regular intervals in a direction perpendicular to the inner peripheral surface of the upper structure 100. Noise, such as impact noise or vibration applied to the concentrated transmission through the tip of the noise transmission unit 150, and the lower structure 200 of the elastic material is absorbed and cushioned.

Of course, the amount of air discharged through the sound absorbing shock absorbing groove 251 is fine, but the sound, shock and vibration is softly absorbed and buffered by the inner air layer, and at the same time the air discharged by the air outlet groove 252 (noise, vibration). ) Is absorbed and attenuated again by being induced in the air layer A1.

As shown in FIG. 13, the preferred embodiment of the present invention assembles the upper structure 100 in a state of being installed on the bottom surface of the lower structure 200, and as shown in FIG. As a result, the construction is performed with the upper surface portion 120 of the bottom structure 100 exposed.

The present invention thus constructed can be installed on the floor surface of the building in a continuous construction as shown in Figure 14 in the assembled state of the upper structure 100 and the lower structure 200, such as Figures 9 and 11.

The preferred embodiment of the present invention, as shown in the enlarged view of Figure 16 and 17, the impact sound or vibration due to the impact applied to the upper structure 100 by the load or impact is the upper surface portion 120 of the decorative body 110 Dispersed and transmitted through each of the cone-shaped noise transmission unit 150 protruded to the bottom of the, shock sound, vibration sound is projected to the upper portion of the lower support portion 220 of the support body 210 of the lower structure 200 Each of the sound absorbing buffers 250 of the cone shape is first absorbed and simultaneously compressed air is absorbed by the air outlet grooves 252 in the sound absorbing buffer grooves 251 of each sound absorbing buffer unit 250 In the sound absorbing body portion 270 of the support rim wall 260 is discharged through the air layer (A1) of the space enclosed by the body portion 140 and the second enclosure portion 240 and formed at the bottom of the support body 210. Secondary sound is absorbed and attenuated while flowing through the sound absorption and air flow holes 261.

12 and 15, the bottom surface of the widthwise covering portion 121 of the decorative body 110 adjacent to the buffer line projection 133 of the widthwise base portion 131 of the decorative body 110 is in close contact with each other. It is constructed in such a state that the bottom surface of the longitudinal covering portion 122 of the decorative body 110 adjacent to the buffer line projection 134 of the longitudinal support portion 132 of the decorative body 110 in close contact with the state. Constructed, and at the same time the lower surface of the supporting member 131 in the width direction of the decorative member 110 and the rectangular border wall 130 of the width supporting member 221 of the supporting member 210 constituting the lower structure 200 In close contact with the buffer line projection 233, the bottom surface of the longitudinal support portion 132 and the rectangular border wall 130 of the decorative body 110 is the length of the support body 210 constituting the lower structure 200 The width direction support part 221 of the support body 210 which is constructed to be in close contact with the buffer line projection 234 of the direction support part 222 and is an elastic buffer material, and a length While the buffer by each of the line buffer protrusion (233 234) molded to the upper direction of the backrest support 222 is to absorb a vibration or shock.

Since the buffer line protrusions 233 and 234 are shaped into wavy protrusions, the height of the buffer line protrusions 233 and 234 shrinks according to the impact load applied to the decorative body 110 by the space between the protrusions and the protrusions, and the buffer line protrusions 233 and 234 may be buffered in the width direction expansion.

In a preferred embodiment of the present invention, the sound absorbing body portion 270 of the lower structure 200 may be applied by filling the non-woven fabric or environmentally friendly Biscorayon 100% as a sound absorbing material to provide a sound absorbing function.

In addition, the present invention, as shown in Figure 18 and 19, can be applied to the surface sheet printed with a decorative pattern on the upper surface portion 120 of the upper structure 100 of the present invention.

That is, the upper structure 100 may provide a decorative pattern sheet 125 having elasticity to the upper surface portion 120 in the injection molding during the injection molding to improve the decorative appearance of the outer surface.

20 to 22 is another embodiment of the present invention, the difference between the preferred embodiment of the present invention is the noise transmission unit 150 is formed of a hemispherical noise transmission unit 155, the sound absorbing buffer 250 is A sound absorbing buffer groove 251 may be formed to accommodate a part of the outer circumferential surface of the noise transmission unit 150 as a cone shape of the light of the lower side.

In addition, the sound absorbing buffer groove 251 may be formed by applying a plurality of air outlet holes 253 at a predetermined interval in the horizontal direction so as to discharge the internal air according to the compression of the noise transmission unit 155.

22, the noise transmitting part 155 descends further by digging the sound absorbing buffer groove 251 by the impact load, thereby expanding the sound absorbing buffer groove 251 of the sound absorbing buffer part 250 outward. At the same time, the inside air layer is discharged through the air outlet hole 253 to be absorbed and attenuated while being discharged through the air layer A1.

Another embodiment of the invention is shown in FIGS. 23-25.

FIG. 23 is a perspective view of a separated state of the superstructure and a lower structure, FIG. 24 is a bottom perspective view of a separated state of the superstructure and a lower structure, FIG. 25 is a cross-sectional view illustrating an assembled state of the superstructure and a lower structure, and FIG. O 'excerpt is an enlarged view.

In this embodiment, the noise transmission unit 150 of the upper structure 100 and the upper structure 100a of the lower structure 200 presented in the preferred embodiment of the present invention is one side by injection molding with a hard reinforcing material. The upper surface portion 120a of the state in which the widthwise covering portion 121a and the longitudinal covering portion 122a protrude along the sides of the width direction and the longitudinal direction is formed on the bottom surface of the upper surface portion, and the respective covering portions 121a are formed. The first housing portion 140a is formed by a rectangular border wall 130a formed at a lower portion of the widthwise supporting portion 131a and the lengthwise supporting portion 132a opposite to each other in a diagonal direction. The plurality of noise transmission parts 150a protruding from the bottom surface of the upper surface part 120a are protruded and formed in the decorative body 110a and the first housing part 140a.

Here, the noise transmission unit 150a is formed with a sound absorbing buffer groove 151a in the cone shape of the lower narrow light, the sound absorbing buffer groove 151a has a plurality of air outlet grooves 252 at regular intervals perpendicular to the inner circumferential surface. Molded.

In addition, the widthwise supporting portions 131a and the longitudinal supporting portions 132a of the decorative body 110a are each formed with buffer line protrusions 133a and 134a formed in a waveform at a predetermined interval on the upper surface in the longitudinal direction.

The lower structure 200a is fitted inside the first border portion 140a of the decorative body 110a by the fitting border wall 230a protruding from the top so as to be fitted to the square border wall 130a, and the fitting border wall therein. The lower support part 220a having the second housing part 240a formed therein, and the corresponding sound absorbing shock absorbing part 250a supporting the noise transmission part 150a in the lower support part protrude and simultaneously fit the edge frame ( 230a), a support body 210a having a widthwise support portion 221a and a longitudinal support portion 222a protruded to correspond to the widthwise covering portion 121a and the longitudinal support portion 132a, and a lower support portion. Supporting edge wall 260a formed by air support hole 261a at a predetermined interval in a state of integrally protruding molded into the bottom portion 220a and the bottom edges of each of the supporting supports 221a and 222a, and formed by the supporting edge wall And a sound absorbing body portion 270a communicating with the air discharge hole 272a communicating with the second housing portion 240a. .

Here, the widthwise support portion 221a and the longitudinal support portion 222a refer to the enlarged portion of FIG. 23, and the buffer line protrusions 233a and 234a are formed in a waveform at a predetermined interval on the upper surface of each longitudinal direction. Is molded.

Opening of the first enclosure 140a and the second enclosure 240a formed in each of the rectangular border walls 130a of the decorative body 110a and the fitting border walls 230a of the support body 210a. The air seal A1 is formed by partial sealing.

As shown in the enlarged view of FIG. 26, the upper structure 100a is laminated in a state in which the noise transmitting part 150a protruded and formed on the bottom surface of the decorative body 110a is assembled with the sound absorbing buffer 250a of the lower structure 200a. Is assembled.

This assembling step is the same as the preferred embodiment of the present invention, the noise transmission portion 150a formed in the decorative body 110a of the upper structure 100a is formed in the lower support portion 220a of the lower structure 200a. There is a difference in the opposite structure of assembling the outer peripheral surface of the sound absorbing shock absorbing portion (250a) in a state of receiving.

Another embodiment of the present invention, as shown in the enlarged operation of Figure 27 and 28, integrally to the lower support portion 220a on the lower inner peripheral surface of the sound absorbing buffer groove 151a of the noise transmission unit 150a. Conical sound-absorbing shock absorbing portion (250a) formed by the shape of the tip is formed and accommodated in the seated state, and the sound transmitting portion (150a) is lowered by the external force applied to the decorative body (110a) when the sound absorbing shock absorbing groove 151a presses the conical outer circumferential surface of the sound absorbing buffer portion 250a to deflate and shrink.

At this time, the internal air of the sound absorbing shock absorbing groove 151a is naturally discharged by volume reduction (compression of the sound absorbing buffer) by the plurality of air outlet grooves 152a at regular intervals in the vertical direction to the inner circumferential surface, and applied to the upper structure 100a. While the sound absorbing shock absorbing part 250a shrinks and deforms noises such as noise and vibration, the lower structure 200a of the elastic material is absorbed and absorbed.

In this embodiment, as in the preferred embodiment of the present invention, the noise transmission unit 150a operates by lowering the state in which the sound absorbing buffer unit 250a is inserted into the sound absorbing buffer groove 251a by shrinkage deformation. In the discharge process through the (152a) to absorb and buffer the noise, shock, and vibration gently and at the same time, the air (noise, vibration) discharged by the air outlet groove (152a) is a square border wall of the decorative body (110a) 130a) is guided to the air layer A1 enclosed by the fitting edge wall 230a of the lower support part 220a, and the sound absorbing and buffering is performed again.

And the sound is absorbed by the sound absorbing material of the sound absorbing body portion 270a formed by the support rim wall 260a and discharged through the plurality of air discharge holes 272a penetrating the lower support portion 220a or the air flow hole 261a. The sound or shock is absorbed and absorbed through the multi-step discharged through.

29 to 31 is another embodiment of the present invention is different from the preferred embodiment of the present invention is different from the point that the bottom structure 300 by applying the bottom structure 300 to the triple structure.

This embodiment can be applied to a triple stacked structure as shown in FIG.

Another embodiment of the present invention by applying a hard floor structure 300 to the bottom structure portion 220 while at the same time buffering the noise or shock generated through the lower structure 200 back to the bottom structure (300). It is discharged through the plurality of air discharge holes 272 through and discharged through the air flow path groove 330 can be naturally absorbed and attenuated.

The bottom structure 300 is an air discharge hole 272 of the rim wall support groove 320 and the lower support portion 220 to support the support rim wall 260 of the support body 210 constituting the lower structure 200. Air flow path grooves 330 corresponding to c) and providing air flow are provided in a structure formed on the upper surface of the bottom plate body 310 in a grid of left, right, front and back.

33 and 34, the conical shape in which the impact sound or vibration caused by the impact applied to the upper structure 100 protrudes to the bottom surface of the upper surface portion 120 of the decorative body 110. Each noise transmission unit 150 is distributed and transmitted, and the impact sound, the vibration sound is each sound absorbing buffer of the cone shape protruded on the upper portion of the lower support portion 220 of the support body 210 of the lower structure 200. The first air absorbing unit 145 and the second box are absorbed at the same time while the 250 is buffered and the first air is compressed through the air outlet grooves 252 in the sound absorbing buffer grooves 251 of the sound absorbing buffer units 250. The air is discharged through the air layer A1 in the space enclosed by the body part 240 and through the air discharge hole 272 at the sound absorbing body part 270 of the support frame wall 260 formed at the bottom of the support body 210. Secondary sound absorption, if the air introduced into the sound absorbing unit 270 is introduced through the air flow path groove 330 of the bottom structure 330 Attenuation is the sound-absorbing.

As described above, in the detailed description of the present invention, specific embodiments have been described, but various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the claims below but also by the equivalents of the claims.

The present invention can be mass-produced components by injection molding, can be actively utilized as a material for reducing the noise between floors such as apartments can be very useful in solving the noise between floors that emerge as a social problem.

100: upper structure 110: decorative body
120: upper surface portion 121, 121a: width direction covering portion
122, 122a: longitudinal covering 125: decorative pattern sheet
130: rectangular border wall 140: the first housing
150, 150a, 155: noise transmission unit
200: substructure 210, 210a: base body
220, 220a: lower support part 221, 221a: width direction support part
222, 222a: longitudinal support portion 230, 230a: fitting border wall
240, 240a: Second enclosure 250, 250a: Sound absorption buffer
251, 251a: sound absorption buffer grooves 252, 252a: air outlet groove
260, 260a: Supporting edge wall 270, 270a: Sound absorbing enclosure
272, 272a: air outlet 300: floor structure
310: bottom plate 320: rim wall support groove
330: air flow path A1: air layer

Claims (14)

The upper surface portion in the state in which the widthwise covering portion and the longitudinal covering portion protrude along the sides of the width direction and the longitudinal direction on one side, and the widthwise support portion and the lengthwise direction formed on the bottom surface of the upper surface portion and opposing the respective covering portions. The decorative body is formed in the diagonally opposite direction of the support portion formed by the rectangular border wall formed at the lower portion of the decoration body, protruding a plurality of noise transmission parts protruding from the bottom surface of the upper surface portion inside the first housing portion One superstructure;
Insertion border wall protruding thereon so as to be fitted to the rectangular rim wall inside the first enclosure of the decorative body, the lower support portion formed therein the second enclosure by the insertion border wall, the lower support portion inside the A support body having a widthwise support portion and a longitudinal support portion protrudingly formed corresponding to the widthwise covering portion and the longitudinally supporting portion as the fitting edge wall while protruding the corresponding sound absorbing buffer portion supporting the noise transmitting portion. And a support edge wall formed by forming an air flow hole at a predetermined interval in a state of integrally protruding to the bottom edge of the lower support portion and each support support portion, the air being formed by the support edge wall and communicating with the second housing portion. A substructure having a sound absorbing body portion communicating with the ball;
Floor structure for reducing noise between floors comprising a.
The method of claim 1,
The noise transmitting part is protruded and shaped into a conical shape formed by a sharp part, and the sound absorbing shock absorbing part is formed as a cone shape of upper and lower light beams. Structure.
The method of claim 1,
The noise transmitting part is formed in a hemispherical shape, and the sound absorbing shock absorbing part is a cone shape of upper and lower beams, and a sound absorbing buffer groove is formed to receive a part of the outer peripheral surface of the noise transmitting part.
The method of claim 2,
The sound absorbing buffer groove is a floor structure for reducing noise between floors, characterized in that a plurality of air outlet grooves are formed at regular intervals in the vertical direction on the inner circumferential surface to discharge the internal air according to the compression of the noise transmission unit.
The method of claim 1,
Floor structure for reducing the interlayer noise, characterized in that the sound absorbing body portion of the substructure is filled with a non-woven fabric or environmentally friendly Biscorayon 100% as a sound absorbing material to provide a sound absorbing function.
The method of claim 1,
The widthwise base portion and the longitudinal side portion are buffer line protrusions are formed on the upper surface in the longitudinal direction at a predetermined interval, respectively,
The floor supporting structure for reducing noise between floors is characterized in that the buffer supporting protrusions are formed in a wave shape at a predetermined interval on the upper surface in the longitudinal direction supporting portion and the longitudinal supporting portion.
The upper surface portion in the state in which the widthwise covering portion and the longitudinal covering portion protrude along the sides of the width direction and the longitudinal direction on one side, and the widthwise support portion and the lengthwise direction formed on the bottom surface of the upper surface portion and opposing the respective covering portions. The main body is formed in a diagonal direction facing each other, the decorative body is formed by a rectangular border wall formed on the lower portion, protruding into a conical shape of the tip is formed at the bottom surface of the upper surface portion inside the first housing portion with a sharp tip portion; An upper structure protruding a plurality of molded noise transmission parts;
Insertion border wall protruding thereon so as to be fitted to the rectangular border wall inside the first enclosure portion of the decorative body, a lower support portion formed therein the second enclosure portion by the insertion border wall, the upper support portion in the lower support portion A corresponding sound absorbing buffer portion provided with a sound absorbing buffer groove for receiving a portion of the outer circumferential surface of the noise transmitting portion as a cone shape of lower light projects, and protruded to correspond to the widthwise covering portion and the longitudinal supporting portion as the fitting border wall. A support body having a widthwise support and a longitudinal support, a support frame wall formed by forming an air flow hole at a predetermined interval in a state of integrally protruding to the bottom edge of the lower support and each support support, the support frame A lower structure formed by a wall and having a sound absorbing body portion communicating with an air discharge hole communicating with the second housing portion; Made up of
The impact sound or vibration caused by the impact applied to the upper structure by the load or the impact is distributed and transmitted through each noise transmission part of the decorative body, and the impact sound and the vibration sound are absorbed and attenuated firstly while supporting the sound absorbing buffer part of the lower support of the lower structure. At the same time, the compressed air is discharged through the air outlet groove from the sound absorbing buffer groove of each sound absorbing buffer portion, and is discharged through the air discharge hole in the space enclosed by the first housing portion and the second housing portion. Floor structure for reducing noise between floors, characterized in that the sound absorbing, attenuated while flowing through the second sound absorbing and air flow holes in the enclosure.
The upper surface portion in the state in which the widthwise covering portion and the longitudinal covering portion protrude along the sides of the width direction and the longitudinal direction on one side, and the widthwise support portion and the lengthwise direction formed on the bottom surface of the upper surface portion and opposing the respective covering portions. A decorative body in which a supporting part is formed in a diagonally opposite direction and formed with a first frame part formed by a rectangular rim wall formed at a lower part thereof, and a sound absorbing buffer groove having a cone shape of lower narrow light at the bottom of the upper surface part inside the first housing part. The sound absorbing buffer groove is formed with an upper structure protruding a plurality of noise transmission portion formed with a plurality of air outlet grooves at regular intervals in the vertical direction on the inner circumferential surface,
Insertion border wall protruding thereon so as to be fitted to the rectangular rim wall inside the first enclosure of the decorative body, the lower support portion formed therein the second enclosure by the insertion border wall, the lower support portion inside the A cone-shaped sound absorbing buffer portion having a tip portion formed with a sharp tip portion to support the noise transmitting portion protrudes correspondingly, and a widthwise support portion protrudingly formed in correspondence to the widthwise covering portion and the longitudinal supporting portion as the fitting edge wall and the longitudinal direction. A support frame having a support body, and a support frame wall formed by forming a certain air flow hole at a predetermined interval in a state of integrally protruding to the bottom edge of the lower support portion and each support support, and formed by the support frame wall 2 consists of a substructure formed with a sound absorbing body portion communicating with the air discharge hole communicating with the enclosure,
The impact sound or vibration caused by the impact applied to the upper structure by the load or the impact is distributed and transmitted through each of the cone-shaped noise transmission parts of the decorative body, and the impact sound and the vibration sound are primarily supported by the sound absorbing buffer portion of the lower support portion of the lower structure. At the same time, the compressed air is discharged through the air outlet groove from the sound absorbing buffer groove of each noise transmitting unit, and is discharged through the air outlet in the space enclosed by the first and second enclosures, Floor structure for reducing noise between floors, characterized in that the sound absorbing, attenuated while flowing through the second sound absorbing and air flow hole in the sound absorbing body portion of the wall.
The method of claim 8,
The noise transmission part accommodates and couples the outer circumferential surface of the cone-shaped sound absorbing buffer portion, which is formed with a sharp tip, to the sound absorbing buffer groove in a state in which it is seated. Floor structure for reducing noise between floors, characterized in that the buffer damping while shrinkage deformation by pressing.
The method of claim 8,
The widthwise base portion and the longitudinal side portion are buffer line protrusions are formed on the upper surface in the longitudinal direction at a predetermined interval, respectively,
The floor supporting structure for reducing noise between floors is characterized in that the buffer supporting protrusions are formed in a wave shape at a predetermined interval on the upper surface in the longitudinal direction supporting portion and the longitudinal supporting portion.
The upper surface portion in the state in which the widthwise covering portion and the longitudinal covering portion protrude along the sides of the width direction and the longitudinal direction on one side, and the widthwise support portion and the lengthwise direction formed on the bottom surface of the upper surface portion and opposing the respective covering portions. The decorative body is formed in the diagonally opposite direction of the support portion formed by the rectangular border wall formed at the lower portion of the decoration body, protruding a plurality of noise transmission parts protruding from the bottom surface of the upper surface portion inside the first housing portion One superstructure;
Insertion border wall protruding thereon so as to be fitted to the rectangular rim wall inside the first enclosure of the decorative body, the lower support portion formed therein the second enclosure by the insertion border wall, the lower support portion inside the A support body having a widthwise support portion and a longitudinal support portion protrudingly formed corresponding to the widthwise covering portion and the longitudinally supporting portion as the fitting edge wall while protruding the corresponding sound absorbing buffer portion supporting the noise transmitting portion. And a support edge wall formed by forming an air flow hole at a predetermined interval in a state of integrally protruding to the bottom edge of the lower support portion and each support support portion, the air being formed by the support edge wall and communicating with the second housing portion. A substructure having a sound absorbing body portion communicating with the ball; And,
The bottom wall is formed on the upper surface of the bottom plate by a grating of the left and right, before and after the rim wall support groove for supporting the support rim wall of the support body and the air flow path grooves corresponding to the air discharge hole and providing air flow Structures; Floor structure for reducing noise between floors comprising a.
The method of claim 11,
The noise transmitting part is protruded and shaped into a conical shape formed by a sharp part, and the sound absorbing shock absorbing part is formed as a cone shape of upper and lower light beams. Structure.
The method of claim 11,
The noise transmission part is formed in a hemispherical shape, and the sound absorbing buffer part is a cone shape of upper and lower beams, and a sound absorbing shock absorbing groove for receiving a part of the outer circumferential surface of the noise transmitting part is formed.
The method of claim 11,
The widthwise base portion and the longitudinal side portion are buffer line protrusions are formed on the upper surface in the longitudinal direction at a predetermined interval, respectively,
The floor supporting structure for reducing noise between floors is characterized in that the buffer supporting protrusions are formed in a wave shape at a predetermined interval on the upper surface in the longitudinal direction supporting portion and the longitudinal supporting portion.

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