KR100827426B1 - Ondol floor structure for reducing noise between floors of apartment house and construction method thereof - Google Patents

Abstract

An underfloor heating system for reducing noise between floors of an apartment house and a construction method thereof are provided to reduce noise transmitted from an upper floor to a lower floor by permitting an upper portion of a lower vibration isolation column to surface-contact partially to a bottom of an upper vibration isolation column. An underfloor heating system for reducing noise between floors of an apartment house, includes vibration isolation members(10), an auxiliary plate(20), a rubber plate(30), a first magnesium board(40), a foam rubber sheet(50), a second magnesium board(60), a heat insulation member(70), a plurality of pipe panels(80), a plurality of heat conduction plates(90), and a third magnesium board(100) and a fourth magnesium board(110). The vibration isolation members are arranged within rings(14) mounted on a slab. Each vibration isolation member includes a lower vibration isolation column(11) having a pot-shape with a center having a resonance hole(11a), a vibration isolation ring(12) tightened onto the lower vibration isolation column, and an upper vibration isolation column(13) joined onto the vibration isolation ring. The upper vibration isolation column has a bottom surface with a protrusion(13a) having a conical shape mating to the resonance hole of the lower vibration isolation column.

Description

Dry floor floor structure and its construction method for reducing floor noise in multi-unit houses {ONDOL FLOOR STRUCTURE FOR REDUCING NOISE BETWEEN FLOORS OF APARTMENT HOUSE AND CONSTRUCTION METHOD THEREOF}

The present invention relates to a dry on-floor floor structure and a construction method thereof for reducing the noise between floors of a multi-family house, and more particularly, installation between an on-floor layer for heating the same floor, such as a concrete slab and a heating pipe. The present invention relates to a dry on-floor floor structure and a construction method thereof, which can not only excel in insulation and heat storage performance, but also significantly reduce the noise between floors of apartment houses.

In general, in the case of a multi-family building such as an apartment or a multi-storey building, most of the air waves are blocked by the concrete slab structure.However, when a shock or vibration is applied directly to the floor by human walking or falling objects, the solid wave It is hardly attenuated, and radiates through floor slabs, ceilings and walls to lower floors or adjacent generations.

These floor impact sounds are light weight impact sounds that generate a lot of high-frequency components, such as falling sounds of bowls and objects, and weights that generate a lot of low-frequency components such as children's running sounds and adults' walking. It is roughly classified as a shock sound.

In recent years, the conflict between neighbors due to the floor impact noise (floor noise) has emerged as a serious social problem.In March 2004, the Korean government established the "Prevention Standard for Inter-floor Noise in Apartment Buildings" to reduce the noise between floors of apartment buildings. Including the five standard floor structures, the floor shock sound performance grades were announced, and only the products of a certain quality or higher specified in this standard can be applied at the construction site.

In addition, the floors of residential buildings must be mandatory to install insulation to increase the efficiency of cooling and heating and to prevent heat loss in accordance with the "Rules for Facility Standards of Buildings".

As a result, the slab floors of residential MDUs, such as apartments and villas, must meet both thermal insulation and noise barriers, which prevent heat from being transferred to the bottom of the interlayer structure.

On the other hand, the ondol floor structure of the building is divided into wet and dry. The wet structure is an improvement of the traditional ball structure, and the heat storage performance of the floor is good and structurally strong, but the construction period due to the formwork, concrete pouring and curing Due to problems such as delays and maintenance, it is recently being replaced by dry structures.

In other words, the dry on-floor floor structure does not require concrete pouring and curing time, so that the air can be shortened, and unlike the wet on-floor structure, there is a difference between sites due to changes in water content and volume depending on temperature. As a result, it is possible to obtain the most important effects in construction, such as reducing construction costs, shortening the air, and standardizing the quality.

However, the conventional dry on-floor floor structure generally generates solid propagation sound in the heat storage top plate, and the solid propagation sound is transmitted to the lower layer in the form of airflow sound through the space between the top plate and the slab, thereby preventing the interlayer noise standard as described above. There was a structural limitation to meet.

In view of the above, the present inventors have made many efforts to develop a dry on-floor floor structure that is economical in terms of material use and excellent in soundproofing and dustproofing properties and insulation performance, without impairing the structure and design stability of the multi-family house. The present invention has been invented as a result.

Accordingly, an object of the present invention is to provide a dry on-floor floor structure and a construction method for reducing floor noise in a multi-family house that can significantly reduce the floor impact sound (floor noise) while having excellent insulation and heat storage performance.

In order to achieve the above object, the present invention in the on-floor floor structure laminated construction on the floor concrete slab of the multi-unit house, each installed on the inner side of the ring is arranged in a plurality at regular intervals, the resonance in the center A lower dustproof pillar having a jar shape having a tapered hole, a dustproof ring and a jar lid shape coupled to an upper portion of the lower dustproof pillar, and coupled to an upper portion of the dustproof ring, corresponding to a resonance hole of a lower dustproof pillar at a bottom thereof. An anti-vibration hole consisting of an upper anti-vibration column formed with a fixed projection of a conical cylindrical shape; An auxiliary plate installed on an upper portion of the dustproof port to reinforce the support force of the dustproof opening, a rubber plate installed on an upper portion of the auxiliary plate, a first MG board installed simultaneously on the plurality of rubber plates, and an upper portion of the first MG board Foamed rubber sheet, a second MG board installed on top of the foamed rubber sheet, a heat insulator installed on top of the second MG board, and a plurality of pipes installed on top of the heat insulated material to maintain a heating pipe in a constant shape. A cavity including a panel, a plurality of heat conduction plates coupled to respective piping panels while surrounding heating pipes arranged on an upper portion of the piping panel, and third and fourth MG boards installed on the upper portion of the heat conduction plate. It provides a dry on-floor floor structure to reduce the noise between floors.

In addition, the present invention in the on-floor floor construction method to be laminated on the floor concrete slab of the wall-enclosed apartment house, the plurality of rings are arranged at regular intervals on the upper part of the slab, the rubber mortar is placed inside each ring While having a lower dustproof pillar having a jar-shaped tapered resonance hole in the center, and a dustproof ring and jar lid shape coupled to the upper portion of the lower dustproof pillar and coupled to the upper portion of the dustproof ring, A dustproof installation step of installing a dustproof outlet made of a top dustproof column formed with a conical cylindrical fixing protrusion corresponding to a resonance hole in a horizontal state, and then installing an auxiliary plate and a rubber plate on the top of the dustproof hole; The first MG board is installed at the same time on the upper rubber plate of the first MG board Installing a foam rubber sheet for installing a foam rubber sheet on the upper part of the first MG board, Installing a second MG board for installing a second MG board on the upper part of the foam rubber sheet, Insulation material on the upper part of the second MG board Insulating material installation process to be installed, the piping panel installation step of installing the piping panel on the upper portion of the heat insulating material, the heating pipe reinforcement step of enclosing the heating pipe in the upper portion of the piping panel with a heat conduction plate and the upper portion of the piping panel Provided is a dry on-floor floor construction method for reducing floor noise in a multi-family house including a third and fourth MG board installation step of installing the third and fourth MG board in sequence.

The present invention according to the configuration and construction method as described above is not only to absorb and alleviate light impact sound and heavy impact sound at the same time, such as a component such as a dust barrier is sequentially installed between the bottom layer and the slab, the floor layer spaced apart from the slab and wall Since it forms a floor shock can be blocked from being transmitted through the wall. Therefore, the soundproofing and dustproofing properties are excellent, and there is an effect that can significantly reduce the interlayer noise.

In addition, the present invention is able to significantly reduce the load of the floor layer as well as the thermal insulation performance is greatly improved due to the space formed between the floor layer and the slab. Therefore, there is an effect that can improve the insulation performance and structural stability during the design and construction of the building.

In addition, the present invention can easily adjust the horizontal state of the dustproof opening through the installation and placing of the ring and the rubber mortar, and in some cases it is possible to easily adjust the height of the dustproof opening by stacking a plurality of dustproof rings. Therefore, since the heating pipe can be quickly placed in a horizontal state, there is an effect that can greatly improve the construction efficiency and heating efficiency.

In addition, the present invention, since the lower dustproof pillar has a circular jar shape that becomes bulging toward the center of the stomach, disperses and mitigates the vibration transmitted from the bottom layer, and the upper dustproof pillar has a narrow width in diameter as it goes upward. Due to the shape characteristic of the jar lid, the upper part of the lower dustproof pillar is partially in surface contact with the bottom of the upper dustproof pillar, so that the light impact sound or heavy impact sound transmitted from the upper layer can be sufficiently dispersed and attenuated, and the appearance can be provided with beauty. have.

Hereinafter, the ondol floor structure and the construction method according to an embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

Prior to this, terms to be described below are defined in consideration of functions in the present invention, and it should be understood that they should be interpreted as concepts and inherent commonly used meanings consistent with the technical spirit of the present invention.

In addition, when it is determined that the detailed description of known functions or configurations related to the present invention may obscure the gist of the present invention, the detailed description thereof will be omitted.

Figure 1 shows an ondol floor structure according to an embodiment of the present invention, Figure 2 shows a dustproof opening according to an embodiment of the present invention, as shown in Figures 1 and 2, in the embodiment of the present invention According to the ondol floor structure is a dustproof hole 10, auxiliary plate 20, rubber plate 30, the first to fourth MG board (40, 60, 100, 110), foam rubber sheet 50, heat insulating material 70, piping panel 80 And a heat conduction plate 90.

First, the anti-vibration opening 10 is formed of an elastomer that continuously maintains its elastic force and is installed inside a plurality of rings 14 arranged at regular intervals on the upper side of the slab S, and inside the ring 14. While placing the rubber mortar (15) to adjust the horizontal state, and serves to absorb and mitigate the shock transmitted from the top.

Here, the ring 14 and the rubber mortar 15 are configured in consideration of the difficulty in constructing the slab S while maintaining the horizontal state. In other words, if the slab (S) does not maintain a horizontal state, a plurality of dustproof holes 10 are arranged at regular intervals thereon also do not keep the bar, unbalanced through the ring 14 and rubber mortar (15) By correcting the slab (S) so that the dustproof opening 10 can be installed while maintaining a stable horizontal state.

In addition, the ring (Ring) is preferably formed of a cylindrical metal material or synthetic resin, rubber mortar (Rubber Mortar) can be formed by mixing a synthetic resin fixing material to a plurality of fine rubber grains by curing.

The dustproof port 10 is configured to include an upper / lower vibration damper 11/13 and a dustproof ring 12.

First, the lower dustproof pillar 11 is formed in a jar shape in which the resonance hole 11a is tapered in the center portion. The first coupling groove 11b is formed along the upper circumference.

The anti-vibration ring 12 is coupled to the upper part of the lower anti-vibration column 11, and has a resonance hole 12a connected to the resonance hole 11 of the lower anti-vibration column, and formed along the upper and lower circumferences. The second coupling groove 12c and the first coupling protrusion 12b corresponding to the first coupling groove 11b are formed.

The anti-vibration ring 12 is preferably formed of isoprene having a high resistance to elongation and crack generation, low heat generation, and good wear resistance, aging resistance, and electrical characteristics.

The upper anti-vibration column 13 is coupled to the upper part of the anti-vibration ring 12, and has a jar lid formed at the same time at the bottom of the lower anti-vibration column 11 and the resonance holes (11a, 12a) of the anti-vibration ring (12). The fixing projection 13a to be inserted is formed in a conical cylindrical shape having a tapered surface corresponding to the resonance hole of the lower vibration pillar, that is, the width of the diameter narrows toward the lower portion.

The fixing protrusion 13a allows the upper anti-vibration pillar 13 and the lower anti-vibration pillar 11 to be quickly and easily made in nature, and naturally forms a resonance groove 13c in the inner side to disperse the floor impact sound. And double the damping function.

A second coupling protrusion 13b corresponding to the second coupling groove 12c of the anti-vibration ring is formed along the bottom circumference of the upper anti-vibration pillar 13.

Here, the total height of the anti-vibration opening 10 is less than 50mm, the anti-vibration ring 12 is less than 4mm, the diameter of the resonance holes (11a / 12a) is preferably formed within 12mm.

In addition, the upper part of the anti-vibration ring 12 may be easily adjusted by adjusting the height of the anti-vibration opening 10 by stacking a plurality of other anti-vibration rings.

In addition, as shown in FIG. 3, the support grooves 11c are formed on the bottom surface of the lower dustproof pillar 11 so as to further double the buffering force of the dustproof outlet 10, and correspond to the support grooves 11c. The anti-vibration plate 16 having the supporting protrusions 16a of the shape may be coupled to the bottom of the lower anti-vibration column 11.

Like the anti-vibration ring 12, the anti-vibration plate 16 is formed of isoprene, which is large in resistance to elongation and crack generation and generates little heat, and has good abrasion resistance, aging resistance, electrical characteristics, and the like.

Such a dustproof port 10 is to reduce the direct contact area between the ondol floor and the slab (S) to mitigate the impact from the outside. That is, since only the lower edge portion of the dustproof opening 10 contacts the slab S by the resonance holes 11a / 12a, the light impact sound or heavy impact sound transmitted from the upper layer is sufficiently dispersed and attenuated.

In addition, since the lower dustproof pillar 11 has a circular jar shape that becomes bulging toward the center of the stomach, the vibration transmitted from the bottom layer is dispersed and alleviated, and the upper dustproof pillar 13 has a diameter thereof as it goes upward. It has a narrow jar lid shape, so that it is easy to be combined with the joining jaw of the auxiliary plate, and the upper part of the lower anti-vibration pillar 11 has a morphological and structural characteristic that is partially in surface contact with the bottom of the upper anti-vibration pillar 13. Due to this, the function of the upper anti-vibration pillar 13 to dissipate and disperse the vibration primarily can be doubled.

The auxiliary plate 20 is installed on the upper part of the dustproof outlet 10 to reinforce the supporting force of the dustproof outlet, and the coupling jaw 21 is formed on the bottom surface so that the coupling operation can be made quickly and easily. have.

The auxiliary plate 20 is preferably made of synthetic resin material and the thickness of 4mm or more.

The rubber plate 30 is installed above the auxiliary plate 20, and serves to absorb and mitigate the impact.

Like the anti-vibration ring 12 described above, the rubber plate 30 is preferably formed of isoprene, which is large in resistance to elongation and crack generation and generates little heat, and has good abrasion resistance, aging resistance, electrical characteristics, and the like.

In addition, the thickness of the rubber sheet is preferably formed to be 4mm or more.

The first MG board (Magnesium Board) 40 is installed on the plurality of rubber plates at the same time, and serves to block moisture caused by condensation of the heating pipe (P).

The first MG board 40 is hard and ductile by kneading sawdust 3 to 5 wt%, pearlite 3 to 5 wt%, magnesium ore powder 70 to 75 wt%, and mixing and drying 15 to 20 wt% binders. Fireproof, waterproof, soundproof performance is excellent.

In addition, since it includes sawdust, it is environmentally friendly and beneficial to the human body, and includes pearlite to reduce the weight of the board and maintain a predetermined strength.

Here, the first MG board 40 is preferably used having a thickness of 12mm or more.

Foam rubber sheet 50 is installed on the upper portion of the first MG board 40, and prevents the moisture generated from the upper portion such as the heating pipe (P) to penetrate the lower portion, and blocks the interlayer noise.

The foam rubber sheet 50 may be easily adhered to the upper portion of the first MG board 40 by using a non-toxic water-soluble bond harmless to the human body.

Here, it is preferable to use a foam rubber sheet having a thickness of 5mm or more.

The second to fourth MG boards 60, 100, and 110 are installed on the upper portion of the foam rubber sheet 50 and the upper portion of the heat conducting plate 90, respectively, similar to the first MG board 40, sawdust 3 to 5 wt%, pearlite 3 to 5 wt%. % By mixing 70 ~ 75wt% of magnesium ore powder, and the binder composition 15 ~ 20wt% by mixing and drying, and has a rigidity and ductility, in particular, has the excellent fire, waterproof, soundproof performance.

Preferably, the thickness of the second MG board and the fourth MG board is 6 mm or more, and the thickness of the third MG board is 3 mm or more.

The corrugated material 130 is selectively installed between the foam rubber sheet 50 and the second MG board 60, as shown in FIG. 4, and absorbs and mitigates the impact from the outside so that the floor impact sound is in a specific position. Ensure uniform distribution regardless.

Such a corrugated material 130 is preferably formed in a shape in which the surface of the corrugated bone made in the corrugated shape is flat and adhered to both sides.

In addition, the thickness of the corrugated material 130 is preferably used that is 5mm or more.

The heat insulating material 70 is installed on the upper part of the second MG board 60, and it is preferable to use a silver foil layer formed on the surface of a material such as PE form or styrofoam having a low elastic modulus and excellent heat insulating property.

In addition, it is preferable that the thickness of the heat insulating material 70 is 3 mm or more.

Piping panel 80 protects the heating pipe (P) while maintaining the heating pipe (P) arranged in the upper portion of the heat insulating material 70 and at the same time insulates.

The pipe panel 80 scatters, reflects, and scatters loads and impacts and noises applied from the outside in various directions, as well as uniformly transmits the heat generated from the heating pipes through the convection phenomenon. With the rise of, the room temperature is maintained for a long time by the latent heat even when the boiler is not operating so that the thermal efficiency of heating can be greatly improved.

Here, the pipe panel 80 is preferably used to have a thickness of 24mm or more so as to insert the heat conduction plate and the heating pipe to the inside to stably support.

The heat conduction plate 90 is coupled to the piping panel while surrounding the heating pipe that is disposed on the upper portion of the piping panel 80. The thermal conduction function of the excellent thermal conductivity as well as the excellent sound insulation and sound absorption function are caused by the impact applied to the floor. Minimize the propagation of noise to adjacent generations.

Since the heat conduction plate 90 is made of a material such as rubber, which ensures flexibility and tensile strength, the construction work is easy, and the heating pipe is softly and stably wrapped, and responds flexibly to external forces, thereby preventing inadvertent mistakes or errors from the construction process. The impact can be prevented from damaging the heating pipe.

Here, it is preferable that the thickness of the heat conductive plate 90 is 1 mm or more.

On the other hand, the first to fourth MG boards (40, 60, 100, 110), the foam rubber sheet 50, the heat insulating material 70, the piping panel 80 and the heat conduction plate 90 and the wall (W) in contact with each other a separate portion By installing the soundproof material 120 to prevent the impact sound and vibration transmitted to the side.

That is, when the impact force is generated on the surface of the bottom layer, the wavelength of the solid transmission sound is blocked without being transmitted to the wall W due to the gap between the bottom layer and the wall W and the soundproof material 120. However, it can be distributed and propagated to the lower slab (S), but this is buffered by the dustproof hole 10, the sound pressure generated by resonance and resonance phenomena because the wavelength energy leaks into the gap, resulting in the sound pressure is amplified By preventing and weakening the transmission of the floor impact sound can be minimized.

The sound insulation material 120 is preferably a PE foamed resin material having a thickness of 10mm or more.

The construction method of the ondol floor structure according to an embodiment of the present invention will be described with reference to the flowchart of FIG. 5.

Here, the same components as the above-described ondol floor structure have the same similar effects and functions as described above, and therefore the same reference numerals are used, and detailed description thereof will be omitted.

<Vibration Proof Installation Process>

First, a plurality of rings 11 are arranged at regular intervals on the upper side of the slab S, and the dustproof opening 100 is positioned inside the ring 14. The lower dustproof pillar 11 having a jar shape in which the rubber mortar 15 is placed inside the ring and the resonance hole is tapered in the center thereof, and the dustproof ring 12 and the jar coupled to the upper portion of the lower dustproof pillar After adjusting the height of the dust-proof opening (10) consisting of an upper dust-proof column (13) having a lid shape and coupled to the upper portion of the dust-proof ring, and then adjust the horizontal state, and install the auxiliary plate 20 and rubber plate 30 thereon in order do.

At this time, by stacking a plurality of anti-vibration ring 12 constituting the anti-vibration opening 10 can be quickly and easily adjust the height of the anti-vibration opening 10.

In addition, the dustproof plate 16 may be provided on the bottom surface of the dustproof opening 10 so as to further double the buffering force of the dustproof opening 10.

Here, it should be noted that before or after the installation of the anti-vibration opening 10, the auxiliary plate 20, and the rubber plate 30, the installation of the soundproofing material 120 should be preceded along the circumference of the wall.

The soundproof material 120 may block the floor shock sound from being transmitted to the side wall W.

<1MG board installation process>

After installing a plurality of anti-vibration port 10, the auxiliary plate 20 and the rubber plate 30, the first MG board 40 is simultaneously installed on the plurality of rubber plates.

At this time, the first MG board 40 may be connected to each other by the other 1MG board and the adhesive tape, such that the flow and departure do not occur.

<Cardboard Installation Process>

After the first MG board 40 is installed, the corrugated material 130 may be selectively installed thereon.

Such a corrugated material 130 is preferably used that is bonded to both sides of the cardboard or plate with a flat face and a flat core to the corrugated bone.

<Foaming rubber sheet installation process>

After installing the first MG board 40 or the corrugated material 130, and then install a foam rubber sheet 50 thereon.

At this time, by applying a water-soluble bond on the back surface of the foam rubber sheet 50 to ensure that the foam rubber sheet 50 is firmly attached to the upper surface of the first MG board 40 or to the foam rubber sheet 50 and other foam rubber sheet By connecting to each other with an adhesive tape or the like may be prevented from occurring flow and departure.

<2 MG board installation process>

After installing the foam rubber sheet 50, the second MG board 60 is installed thereon.

At this time, the first and second MG board 40/60 and the foam rubber sheet 50 may be firmly fixed to each other by using a fixing member such as a nail or a piece. The 2MG boards may be connected to each other with adhesive tape to prevent flow and departure.

<Insulation Material Installation Process>

After installing the second MG board 60, the heat insulating material 70 is installed thereon.

In this case, the heat insulating material 70 may be connected to each other with another heat insulating material and adhesive tape, such that flow and departure do not occur.

<Plumbing panel installation process>

After installing the heat insulating material 70, the piping panel 80 is installed thereon.

At this time, the pipe panel 80, the second MG board 60 and the heat insulating material 70 may be firmly fixed to each other using a fixing member such as a nail or a piece.

<Heating piping reinforcement process>

After installing the pipe panel 80, the heating pipe (P) is wrapped in the pipe fixing groove 81 formed in the inside of the heating pipe (P) while reinforcement.

<3rd and 4th MG board installation process>

After heating the heating pipe using the piping panel and the heat conduction plate, the third and fourth MG boards 100/110 are overlapped and installed thereon.

In this case, the third and fourth MG boards 100 and 110 may be connected to each other with the third and fourth MG boards by using an adhesive tape to prevent flow and departure.

In addition, after the third and fourth MG board installation process, the flooring material 140, such as a sheet of cardboard is laid on the fourth MG board 110 and finished.

This construction method can significantly reduce the noise between floors of apartments, while completing an eco-friendly dry on-floor floor structure.

On the other hand, the standard laboratory measurement of the floor shock sound insulation performance of the ondol floor structure constructed in accordance with an embodiment of the present invention.

This test was performed in accordance with the test method specified in KS F 2810-1 and KS F 2810-2 by requesting Korea Noise and Vibration Co., Ltd., and the inverse A characteristic curve of KS F 2863-1 and KS F 2863-2. Evaluated by.

In addition, the light impact sound according to the test results was measured at the octave band center frequency of 125 ~ 2 ,, the heavy impact sound was measured at 63 ~ 500 ㎐.

As a result of the evaluation, the light impact sound performance level is shown in FIG. 6, and the measured value is a normalized floor impact sound level calculated from the reverberation time measurement result measured in the first-floor sound receiving room, and the single calculated by the inverse A characteristic reference curve. Inverse A characteristic weighted normalized floor impact sound level L'n , AW Was estimated at 38 dB.

As shown in FIG. 7, the weight shock sound performance level is a floor impact sound level measured in the first floor sound receiving chamber, and the inverse A characteristic weighted floor impact sound level L _{i , Fmax ,} calculated by the inverse A characteristic reference curve. _AW Was estimated at 45 dB.

Therefore, it can be seen that the ondol floor structure according to the embodiment of the present invention is very superior in floor shock sound blocking performance.

On the other hand, the present invention is not limited by the above-described embodiment and the accompanying drawings, it can be changed to other embodiments equivalent to substitution and equivalent within the scope without departing from the technical spirit of the present invention is usually in the art. It will be evident to those who have knowledge of.

1 is a sectional view of the main portion showing the ondol floor structure according to an embodiment of the present invention,

Figure 2 is an exploded perspective view showing a dustproof outlet according to an embodiment of the present invention,

Figure 3 is an enlarged cross-sectional view of the main part showing a dustproof outlet according to another embodiment of the present invention,

Figure 4 is an enlarged cross-sectional view of the main portion showing the ondol floor structure according to another embodiment of the present invention,

5 is a flow chart showing a construction method of ondol floor according to an embodiment of the present invention,

Figure 6 is a graph showing the level of light impact sound performance of the ondol floor structure according to an embodiment of the present invention,

Figure 7 is a graph showing the weight impact sound performance level of the ondol floor structure according to an embodiment of the present invention.

<Explanation of symbols for main parts of the drawings>

10: anti-vibration port 11: lower anti-vibration column

11a: resonance hole 11b: first coupling groove

11e: support groove

12: dustproof ring 12a: resonance hole

12b: first coupling protrusion 12c: second coupling groove

13: upper vibration pillar 13a: fixed protrusion

13b: second coupling protrusion 14: ring

15: Rubber mortar

16: dustproof plate 16a: support protrusion

20: baffle plate

30: rubber plate 40: first MG board

50: foam rubber sheet 60: the second MG board

70: insulation material 80: piping panel

90: thermal conductive plate 100: 3 MG board

110: fourth MG board 120: sound insulation

130: corrugated material P: heating piping

S: Slab W: Wall

Claims (7)

In the on-floor floor structure laminated on the floor concrete slab of the apartment house, And installed on the inside of the ring is arranged in a plurality at regular intervals on the upper portion of the slab, the lower dust-proof pillar having a jar-shaped tapered resonance hole in the center, and the dust-proof ring coupled to the upper portion of the lower dust-proof pillar and An anti-vibration port having a jar lid shape and coupled to an upper part of the anti-vibration ring, wherein the anti-vibration cylinder is formed of an upper anti-vibration column having a conical cylindrical shape corresponding to the resonance hole of the lower anti-vibration column; An auxiliary plate installed at an upper portion of the dustproof port to reinforce the support force of the dustproof port; A rubber plate installed on an upper portion of the auxiliary plate; A first MG board installed simultaneously on the plurality of rubber plates; A foam rubber sheet installed on the first MG board; A second MG board installed on an upper portion of the foam rubber sheet; A heat insulator installed on the second MG board; A plurality of piping panels installed on an upper portion of the heat insulating material to maintain heating pipes in a predetermined form; A plurality of heat conduction plates coupled to respective piping panels while surrounding heating pipes arranged on top of the piping panels; Third and fourth MG boards installed in an overlapping manner on top of the heat conduction plate; Dry ondol floor structure for reducing the noise between floors of a multi-family house. The method of claim 1, Dry on-floor floor structure for reducing the noise between floors of the multi-family house further comprises a corrugated material bonded on both sides of the corrugated cardboard or plate with a flat surface in the corrugated corrugated bone between the first MG board and the foam rubber sheet. The method according to claim 1 or 2, The dustproof opening, A first coupling groove is formed along the upper circumference of the lower anti-vibration pillar, and a resonance hole is formed inside the anti-vibration ring to be connected to the lower anti-vibration pillar, and the lower anti-vibration pillar is formed along the circumference of the upper and lower surfaces. Forming a second coupling groove and the first coupling protrusion corresponding to the first coupling groove, the second coupling protrusion corresponding to the second coupling groove of the anti-vibration ring is formed around the bottom surface of the upper dustproof pillar Dry floor structure for reducing floor noise in apartments. The method of claim 3, wherein The dustproof opening, Dry on-floor floor for floor noise reduction in a multi-family house, characterized in that the support groove is formed on the bottom of the lower dustproof pillar, and the dustproof plate having a support protrusion having a shape corresponding to the support groove is coupled to the bottom of the lower dustproof pillar. rescue. In the construction method of the on-floor floor laminated on the floor concrete slab of the apartment house surrounded by the wall, A lower dustproof cylinder having a jar shape in which a plurality of rings are arranged at a predetermined interval on the upper part of the slab, and a rubber mortar is formed inside each ring to taper a resonance hole in the center thereof, A dustproof ring having a dustproof ring and a jar lid shape coupled to the upper portion and coupled to an upper portion of the dustproof ring, and having a top anti-vibration column formed with a conical cylindrical shape fixing protrusion corresponding to the resonance hole of the lower dustproof column on the bottom thereof in a horizontal state. A dustproof opening installation step of installing an auxiliary plate and a rubber plate on the upper side of the dustproof opening after the installation in accordance with the furnace; A first MG board installation step of simultaneously installing the first MG boards on the plurality of rubber plates and having a gap having a predetermined width with the wall; A foam rubber sheet installation step of installing a foam rubber sheet on the first MG board; A second MG board installation process of installing a second MG board on top of the foam rubber sheet; A heat insulating material installation step of installing a heat insulating material on the top of the second MG board; A pipe panel installation step of installing a pipe panel on an upper portion of the insulation; A heating pipe reinforcement step of surrounding the heating pipe with a heat conduction plate on the upper portion of the pipe panel; And A third and fourth MG board installation process of sequentially installing third and fourth MG boards on the upper portion of the piping panel; Dry ondol floor construction method for reducing the noise between floors of a multi-family house comprising a. The method of claim 5, wherein Before or after the dustproof installation step, dry ondol floor construction method for reducing the noise between floors further comprising the step of installing a soundproofing material along the circumference of the wall. The method according to claim 5 or 6, Between the first MG board installation process and the foamed rubber sheet installation process further comprises a corrugated material installation process for installing a corrugated material bonded to both sides of the cardboard or plate that is smooth and firm on the corrugated core made of corrugated corrugation Dry Ondol Floor Construction Method for Reducing Interlaminar Noise

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