KR100831998B1 - High strength concrete with high heat insulation capacity and floor stuructue for insulating muti-level impact sound using the same - Google Patents

Abstract

A high insulation and high stiffness lightweight concrete composite and a floor structure for interlayer impact sound reduction using a high insulation and high stiffness lightweight concrete composite are provided to cut off the transfer of floor impact sound from the upper floor to the lower floor in a multistoried building effectively. A high insulation and high stiffness lightweight concrete composite is placed on the upper part of a concrete slab structure to reduce impact sound transferred from the upper floor, and composed of 47.4~70.2 weight percent perlite, 5.3~10.6 weight percent plaster, 5.3~10.6 weight percent calcium hydroxide, 10.6~21.2 weight percent calcium carbonate and 2.6~5.3 weight percent calcium chloride per 100 weight percent cement. A floor structure for interlayer impact sound reduction using a high insulation and high stiffness lightweight concrete composite comprises a concrete slab layer(10) dividing the upper floor and the lower floor of a building, a high insulation and high stiffness lightweight concrete layer(20) formed by placing a concrete composite on the upper part of the concrete slab layer, a cement mortar layer(30) formed on the upper part of the high insulation and high stiffness lightweight concrete layer, and a finishing layer(40) formed on the upper part of the cement mortar layer.

Description

High-strength, high-stiffness, lightweight concrete composition and floor structure with low impact sound using the same {HIGH STRENGTH CONCRETE WITH HIGH HEAT INSULATION CAPACITY AND FLOOR STURUCTUE FOR INSULATING MUTI-LEVEL IMPACT SOUND USING THE SAME}

1 is a diagram showing a cross-sectional structure of a conventional general floating floor structure.

Figure 2 is a cross-sectional view showing the configuration of the floor structure for reducing the impact sound of the interlayer constructed using the high-insulation high rigidity lightweight concrete composition of the present invention.

Explanation of symbols on the main parts of the drawings

10: slab structure 20: high insulation high rigidity lightweight concrete layer

30: cement mortar layer 40: finishing layer

The present invention relates to a concrete composition and a floor structure using the same to effectively block the floor impact sound generated from the upper floor is placed on the slab structure of a multi-storey building, such as a multi-family building, in particular the mass of the entire floor structure It is very effective in reducing the impact of weight impact by integrating the entire floor structure together with its integrated structure, and it has excellent thermal insulation and satisfies the legal heat transmission rate standard without using a separate insulation material, so it replaces existing lightweight foam concrete and interlayer noise buffer. The present invention relates to a high-insulation lightweight concrete composition that can obtain excellent interlayer noise reduction effects, and a floor structure for floor impact noise reduction using the same.

Recently, with the rapid industrial development and economic growth, the demand for buildings is increasing and land prices are continuously increasing. As a result, office buildings, etc., which are constructed in urban areas with high land prices, tend to become high-rise as a way to use land efficiently. In order to solve this problem, residential buildings are being concentrated in multi-unit apartments such as apartments, villas and multi-family houses. However, in the case of these multi-story buildings, the upper floor and the lower ceiling are shared as the same structure between the upper floor and the lower floor, so that various noises generated in the upper floor are transmitted to the lower floor through the interlayer slab, so that other people's life or work There is a problem that will interfere with the situation, and accordingly, disputes or complaints due to the noise level between the apartments in the apartments are increasing rapidly.

Therefore, various studies have been conducted in the past to solve the noise and impact sound problems, and the most commonly applied method as a floor structure for reducing the impact noise between the slab structure and the upper plastering mortar layer. Typical so-called floating floors have been provided in which an interlayer buffer layer is provided, thereby allowing interlayer noise to be blocked. Figure 1 shows a general cross-sectional structure of the conventional floating floor structure as described above, as shown in Figure 1, which is installed on the slab structure (S) with a cushioning material having a good sound insulation and shock absorbing to install an interlayer buffer layer (F) Lightweight foamed concrete (C) and ondol plastering mortar (M) was cast thereon to prevent the impact energy applied from the upper part to be directly transmitted to the slab structure. Here, as the interlayer cushioning material to be constructed in the floating floor structure as described above, various materials such as rubber-based mats, urethane foam, glass wool, including synthetic resin-based materials such as EPS, EPE, EPP, and EVA, and the thickness thereof are used. Is usually constructed on the order of 10 to 30 mm.

However, the floor structure as described above basically cushions the impact from the top by its elastic deformation due to the material properties of the interlayer buffer material, and the floating floor structure is KS F 2810 or Japanese Industrial Standard (JIS 1419). Although it has shown some effects on the light impact sound defined by), etc., it has been confirmed that it does not show a great reduction effect in solving the heavy impact sound that causes problems in real life. In other words, it can be seen that this energy is almost transferred to the slab structure as the materials such as ondol plaster, foam concrete, and interlayer buffers, which are existing floor structures, do not efficiently attenuate the energy due to the weight impact. will be.

In particular, the standard floor structure for the prevention of floor impact sound recently announced by the Ministry of Construction and Transportation suggests the recommended performance criteria for the interlayer cushioning material.In the case of the interlayer cushioning material having a dynamic modulus of 40 MN / ㎡ or less, the interlayer cushioning material is installed. It is confirmed experimentally and academically that the effect of reducing the weight impact sound is almost ineffective or results in increasing the weight impact sound as compared with the case where it is not. Thus, the interfacial separation hypothesis and the 1 degree of freedom resonance resonance hypothesis have been convinced that the installation of the interlayer shock absorber causes an increase in the weight impact sound, and these theories are inherent in floor slabs as the current level interlayer shock absorber. It is pointed out that it is difficult to improve the heavy impact sound because it is hard to get out of the resonance range of the frequency band.

As another method for solving the above problems, there has been proposed a method of using a double floor structure or damping material, but these methods also have the following problems, which is not sufficient as a fundamental solution to the inter-layer noise problem. there was.

In other words, the double-floor structure has a merit that there is no limit to the performance improvement only in theory, and it has been proved that the effect of improving the lightweight impact sound of the second-class level is sufficient, and that it can sufficiently cope with the thermal permeability problem. In actual site casting, only 4 grades of performance were shown, and there was an economic disadvantage due to the construction cost of more than 30,000 won per ㎡, and the structure was complicated, and there was a problem of delaying the air with the possibility of various defects.

In addition, in the case of using the damping material, the performance of up to grade 2 is expected and the effect of improving the weight impact sound of the grade 3 level is proved, but in this case, it is not effective in reducing the light impact sound. In addition to the problem of need, there was a disadvantage in that the problem of heat permeability needs to be solved. In addition, in the case of the method using the damping material is expected to cost more than 20,000 won per m 2 in the construction cost, and the specific mechanism for reducing the weight impact sound of the damping material was not clearly verified, there was a disadvantage that there is a limitation in universal use .

Accordingly, the present invention has been made with the object of effectively preventing the floor impact sound from being transmitted to the lower floor in a multi-storey building in view of all the problems exhibited in the conventional floor structure for preventing floor noise, including the floating floor structure as described above. In particular, the present invention is to be placed on top of the slab structure to integrate the mass of the entire floor structure so that the entire floor structure behaves together to reduce the weight impact sound very effectively, and at the same time excellent thermal insulation and separate heat insulating material Since it satisfies the legal heat transmissivity standard without using it, it provides a high-insulation lightweight concrete composition that can replace the existing lightweight foamed concrete and the interlayer noise absorbing material and can obtain excellent interlayer noise reduction effect, and a floor structure for interlayer impact noise reduction using the same. It is assumed that the technical problem to be solved.

In order to achieve the above technical problem, the high-insulation lightweight concrete composition for reducing the floor impact sound provided by the present invention is a lightweight concrete composition for reducing the impact sound applied from the upper layer is placed on top of the concrete slab structure, cement; Perlite; gypsum; And calcium hydroxide; Calcium carbonate; It comprises the calcium chloride; it is characterized by its basic characteristics.

In addition, in the present invention as a floor structure for reducing the inter-layer impact sound made using the high-insulation lightweight concrete composition as described above, the concrete slab layer for separating the upper and lower floors of the building; Cement is poured on top of the concrete slab layer; Perlite; gypsum; And, a high thermal insulation lightweight concrete layer comprising calcium hydroxide; And a cement mortar layer that is poured on top of the high-insulation lightweight concrete layer. In another aspect, the present invention provides an interlayer impact sound reduction floor structure using the high-insulation lightweight concrete composition.

Concrete composition of the present invention made of the composition as described above is a high-insulation, high-stiffness lightweight concrete developed to effectively reduce the floor floor impact sound transmitted to the lower floor in a multi-story building such as a multi-family building, the concrete composition of the present invention as described above In the case of the floor structure constructed using the concrete composition of the present invention having a higher rigidity than the general foam concrete by integrating the mass of the entire structure constituting the floor structure by the floor impact the entire floor structure acts integrally without weight loss It has the advantage of reducing the weight impact sound very effectively.

In addition, the high-insulation, high rigidity lightweight concrete provided by the present invention has a high thermal insulation performance due to its characteristic composition, and thus satisfies the existing heat-concrete concrete because it satisfies the legal heat transmission rate criteria without using a separate insulation material. It can also provide the effect of replacing the insulation.

Hereinafter, the technical characteristics and theoretical background of the interlayer impact sound reduction floor structure formed by pouring the concrete composition of the present invention and the concrete provided by the present invention will be described in comparison with the floating floor structure using a conventional interlayer cushioning material. .

As described above, in the case of the floating floor structure, which is generally applied as a floor structure of a multi-family house, an elastic interlayer cushioning material was installed to prevent the floor impact sound from propagating from the upper part to the lower floor. In contrast to the conventional expectation that the interlayer cushioning material will reduce the floor impact sound, the existing floor structure has resulted in an increase in the weight impact sound, compared to the general floor structure without the buffer material.

The cause of the increase in the weight shock sound of the existing interlayer cushioning material can be explained as follows. First, the concrete slab and its superstructure are separated and behave independently of each other due to the installation of the interlayer cushioning material, thereby acting independently of each other. The weight loss occurs and the effect of reducing the weight impact sound is inferior.

That is, in the floating bottom structure provided with the interlayer cushioning material, the lower slab and the foamed concrete + mortar layer of the upper layer are separated from each other by the interlayer cushioning material. In the conventional floating floor structure, the shock absorber upper structure (bubble concrete) is applied when the impact is applied. + Mortar) and the lower slab structure have to vibrate individually to dissipate the impact energy, resulting in less effect on the weight impact sound than when the entire mass vibrates as one.

In addition, another theory explained as the reason that the interlayer cushioning material increases the weight impact sound as described above is that the vibration is amplified by the resonance phenomenon of the slab and the upper structure (bubble concrete + mortar) separated from the slab by the interlayer cushioning material. . In other words, according to the above theory, when considering the physical properties of the interlayer cushioning material and its upper structure in the case of the existing floating floor structure, the natural vibration of the 50 ~ 100Hz band occurs in the upper structure (bubble foam concrete + mortar layer) This vibration causes resonance in the lower slab structure, thereby increasing the vibration further, thereby increasing the weight impact sound.

Accordingly, the present invention focuses on the fact that the bubble concrete / mortar layer on the upper side and the slab structure on the lower side of the present invention have a reverse effect in terms of dissipation of the impact energy due to the installation of the interlayer cushioning material as described above. Instead of planting cement; It is important to manufacture a new high strength, high-insulation lightweight concrete composition that includes perlite, gypsum, calcium hydroxide, calcium carbonate, and calcium chloride, and then cast it on top of the slab structure and cast cement mortar on it to form the floor structure. There are technical features.

The concrete composition of the present invention has a high strength and light weight due to its characteristic composition, which is effective in reducing floor impact sound itself, and in particular, of the floor structure using the high-strength high-insulation lightweight concrete composition of the present invention. In this case, when the impact is applied from the top by completely integrating the lower slab structure and the mortar layer by using the concrete composition of the present invention which does not occur elastic deformation, the entire bottom structure behaves together as a structure to dissipate the impact energy. By inducing it can provide an effect that shows a very good performance in reducing the weight impact sound.

Furthermore, the high-strength, high-insulation, lightweight concrete composition provided by the present invention has a property of thermal conductivity of 0.09 W / m 2 K or less, thereby satisfying the legal thermal insulation standard heat permeability (0.81 W / m 2 K or less), so that a separate insulating material is used. It also has the advantage of solving the insulation problem.

Hereinafter, the high stiffness high insulation lightweight concrete of the present invention as described above will be described in more detail with respect to the main components, functions and specific composition ratios.

In the present invention, the light weight concrete composition which is placed on top of the concrete slab structure and serves as a use for reducing the impact sound applied from the upper layer is basically cement; Perlite; gypsum; Calcium hydroxide; Calcium carbonate and; Lightweight concrete composition characterized in that it has a high insulation and high rigidity by the composition including calcium chloride, the specific composition is based on 100 parts by weight of cement, 47.4 ~ 70.2 parts by weight, 5.3 ~ 10.6 parts by weight gypsum It is preferably formulated to contain 5.3 to 10.6 parts by weight of calcium hydroxide, 10.6 to 21.2 parts by weight of calcium carbonate, and 2.6 to 5.3 parts by weight of calcium chloride.

Summarizing the main components and composition ratio of the high rigidity high thermal insulation lightweight concrete composition provided by the present invention as described above can be represented as shown in Table 1 below.

Table 1 Main components of the concrete composition of the present invention

Composition ratio (part by weight) % By weight cement 100 52 ± 5 Perlite 47.4-70.2 30 ± 3 gypsum 5.3 to 10.6 4 ± 1 Calcium hydroxide 5.3 to 10.6 4 ± 1 Calcium carbonate 10.6 to 21.2 8 ± 2 Calcium chloride 2.6 to 5.3 2 ± 0.5

In the high-insulation high-strength lightweight concrete composition of the present invention as described above, the cement functions as the main binder of the hydration reaction, and generally, it is preferable to use one kind of portland cement. It is also possible to use.

In the present invention, the perlite added to the cement (Perlite), as is well known in the volcanic rock zone, the crushed pearl rock, pine stone, obsidian or similar type of volcanic rock quenched during the activity of the volcanic rock to an appropriate particle size and then 800 ℃ It was expanded by applying rapid heat at the above-mentioned high temperature. In the case of such a perlite, fine pores are formed inside and outside thereof. When the perlite is added to the concrete composition of the present invention, it is bonded by the hydration reaction of cement to form a porous structure in the entire concrete composition. Advantageous effect on sound absorption can be obtained.

It is preferable that such a perlite is included in a ratio of 47.4 to 70.2 parts by weight with respect to 100 parts by weight of cement, which is difficult to exhibit sufficient thermal insulation performance when added less than 47.4 parts by weight, and conversely when added in excess of 70.2 parts by weight. Considering the disadvantage that it is difficult to dissipate impact energy effectively due to low strength.

In addition, in the present invention, in order to improve the initial compressive strength, gypsum is further added and used as an auxiliary binder. As gypsum used in the present invention, calcined gypsum (제거한 石膏) from which the crystal water is removed by heating gypsum can be preferably used, and the amount of the gypsum is 5.3 to 10.6 parts by weight (4 ± 1% by weight) based on 100 parts by weight of cement. It is preferably included in the ratio of.

In addition, in the composition of the high-insulation high-strength lightweight concrete of the present invention can be further added to the composition of calcium hydroxide, the added calcium hydroxide can ensure high performance (high strength, high durability, high density) of connective tissue through the pozzolan reaction. Function to make it. In addition, according to the present invention, to improve the compressive strength by densification of the connective tissue, as a pore filling material to fill the pores between cement hydrated tissues, calcium carbonate is further added, and the hydration reaction of the cement as the main binding material is also performed. Calcium chloride is further added and used for the purpose of promotion.

The content of the calcium hydroxide, calcium carbonate and calcium chloride components is preferably included in the amount of 5.3 to 10.6 parts by weight of calcium hydroxide, 10.6 to 21.2 parts by weight of calcium carbonate and 2.6 to 5.3 parts by weight of calcium chloride, based on 100 parts by weight of cement, but the three If the calcium compound component is added in an excessively large amount, the workability may deteriorate or the properties of the concrete may deteriorate. Therefore, the total amount thereof (calcium hydroxide + calcium carbonate + calcium chloride) is in the range of 23 to 32 parts by weight (14 ± 1% by weight) based on the total composition. More preferably added (the ratio between the three components may vary depending on site conditions and season).

On the other hand, in addition to the basic composition of the light weight concrete composition of the present invention as described above, it is also possible to further use various admixtures such as air entrainer, water reducing agent, fluidizing agent.

The high-insulation, high-stiffness lightweight concrete composition of the present invention composed of the above composition is combined with water and then cast into a predetermined thickness on the concrete slab of the building to interconnect the cement mortar layer and the slab structure to be placed thereon, thereby acting integrally. By doing so, it provides an effect of improving the inter-layer noise, especially the weight impact sound reduction performance.

Figure 2 is a cross-sectional view showing the configuration of the floor structure for reducing the impact sound of the interlayer constructed using the high-insulation high rigidity lightweight concrete composition of the present invention described above, as shown in Figure 2, interlayer according to the present invention Floor structure for reducing the impact sound basically, concrete slab layer (10) for separating the upper and lower floors of the building; A high insulation high rigidity lightweight concrete layer 20 formed by pouring the concrete composition of the present invention on top of the concrete slab layer 10; A cement mortar layer 30 disposed on top of the high insulation high rigidity lightweight concrete layer 20; It is made, including, the top of the cement mortar layer 30 is made of a finish layer 40 is further formed.

In constructing a floor structure for reducing the inter-layer impact sound using the high-insulation high-stiffness lightweight concrete composition of the present invention as described above, the lightweight concrete composition of the present invention described above on the reinforced concrete slab structure (10) first cast in a predetermined thickness The compound is poured with water to form a high insulation high strength lightweight concrete layer 20 having a predetermined thickness. At this time, the mixing performance and quality standards of the light weight concrete composition of the present invention may be prepared according to KS F 4039 foam concrete specification standards for site casting.

Here, prior to placing the lightweight concrete of the present invention, the side cushioning material 100 having a thickness of 5 to 10 mm is attached to the corner portion where the slab structure 10 and the wall 15 meet. After installing the side cushioning material 100 as described above, the lightweight concrete of the present invention is poured on the upper surface of the slab structure 10, in which case the thickness of the 180mm slab in the case of 60 ~ 70mm thickness is appropriate . At the time of placing, it is preferable to sufficiently compact the vibration by using a device such as a vibrator so that the concrete material can be poured intactly without material separation of concrete.

After forming the high-insulation high-strength lightweight concrete layer 20 using the light weight concrete composition of the present invention as described above, after arranging various heating pipes 200 thereon, the cement mortar is poured and cured to a certain thickness to cement mortar. Form layer 30. In this case, the thickness of the cement mortar layer 30 is generally about 40 to 50 mm.

The top of the cement mortar layer 30 formed as described above is formed by attaching and constructing various floor finishes to form a finish layer 40 to complete the floor structure for reducing the inter-layer impact sound of the present invention. As the finishing material used to form the finishing layer 40, various types of finishing materials known in the art, such as vinyl-based sheet boards (trade name: Monolium, etc.), reinforced floorboards, wood floorboards, ondol flooring, etc. Can be used.

In order to confirm the performance of the floor structure for reducing the interlayer impact sound of the present invention as described above, a weight impact sound test was performed on the floor structure of the present invention and other conventionally known floor structures, and the test conditions and results thereof. Is described below.

Specifically, the inventors test the floor structure of the present invention in two rooms of the living room and the main room at the inventors' own construction site, and then test the floor structure for reducing the impact sound of interlayer impacts of the other forms known on the same plane. The weight impact sound test was carried out before and after the construction of the Examples and Comparative Examples for the present invention, respectively, to determine the degree of reduction of the weight impact sound. Specific configuration conditions for the embodiment and comparative embodiments of the present invention applied to the MOCK-UP test as described above are as follows.

[ Example  1] of the present invention High insulation High rigidity  Floor structure using lightweight concrete

The high-insulation high-strength lightweight concrete composition of the present invention was placed on a 180 mm slab at a thickness of 75 mm, and the cement mortar was poured at a thickness of 45 mm to form an interlaminar impact sound reducing floor structure. At this time, the composition ratio of each material in the high-insulation high-strength lightweight concrete of the present invention is 52% by weight of cement, 30% by weight of perlite, 4% by weight of gypsum, 4% by weight of calcium hydroxide, 8% by weight of calcium carbonate, 2% by weight of calcium chloride. Formulated in proportions.

[ Comparative example  One] Damping material  Floor structure using-wet structure 1

A 5 mm thick damping material was laid on the 180 mm slab, 10 mm honeycomb was placed on it, and the EVA foamed concrete was cast 72 mm thick (including honeycomb). Cement mortar was poured on it to form an interlaminar impact sound-reducing floor structure.

[ Comparative example  2] With elastic materials Damping material  Floor Structure Using-Wet Structure 2

Dust-proof rubber plate and foamed polystyrene (EPS) were laid on a 180mm slab in total thickness of 30mm, and foamed concrete was 45mm thick on it to complete the interlaminar impact sound reduction floor structure.

[ Comparative example  3] With elastic materials Damping material  Floor Structure Using-Wet Structure 3

In Comparative Example 2, instead of foam concrete, the floor structure was configured in the same manner as in Comparative Example 2 except that the high-insulation, high-stiffness lightweight concrete of the present invention described in Example 1 was poured to a thickness of 45 mm.

[ Comparative example  4] With elastic materials Damping material  Used floor structure- Semi-dry structure

A 30mm thick dustproof rubber plate was laid on a 180mm slab, a 25mm styrofoam insulation was installed on it, a 10mm thick lattice-shaped plastic mold was installed, and a cement mortar was cast to a 45mm thickness to form an interlaminar impact sound-reducing floor structure.

Weight impact sound measurement results for Example 1 and Comparative Examples 1 to 4 according to the present invention configured as described above are as shown in the table below.

[Table 2] Weight impact sound measurement results

Livingroom Inner room Reduction amount (db) Before construction (db) After construction (db) Before construction (db) After construction (db) Livingroom Inner room Example 1 51 48 55 52 3 3 Comparative Example 1 50 48 54 50 2 4 Comparative Example 2 50 53 54 57 -3 -3 Comparative Example 3 51 55 56 55 -4 One Comparative Example 4 49 48 55 47 One 8

As can be seen from Table 2 above, in the case of Example 1 according to the present invention it was confirmed that the weight impact sound reduction effect of 3db each in the living room and the back room. In addition, in the case of Comparative Example 1 (wet structure 1), the effect of reducing the weight impact sound of 2db in the living room, 4db in the room, and in the case of Comparative Example 4 it was confirmed that the reduction effect of 1db, 8db in the living room and the room, respectively, In Comparative Example 2 (wet structure 2) and Comparative Example 3 (wet structure 3) it can be seen that the result that the weight impact sound is increased rather than the structure without the buffer material.

On the other hand, according to the recognition and management criteria of the floor shock sound blocking structure of the multi-family house, the place of measurement when the complaint of the floor impact sound occurs after moving in is limited to the living room. The results are excellent.

However, in the case of the floor structure according to the present invention has been confirmed that there is a reduction effect for the weight impact sound as described above, it is determined that it is necessary to reduce through the appropriate finishing material for the light impact impact bar, in the following the interlayer impact sound reduction floor of the present invention The results of the test by changing the finish for the structure are shown and accordingly, a finish that can be most suitably used in the practice of the present invention will be presented.

After installing the various types of finishing materials currently used in the interlaminar impact sound reduction floor structure using the high-insulation high-strength lightweight concrete of the present invention as described above, the weight impact sound and light impact sound measurement test were performed. Specifically, the high-insulation, high-stiffness lightweight concrete of the present invention is placed on a 150mm slab in a thickness of 70mm, and the cement mortar is poured in a thickness of 40mm, and cured. Ondol floors were finished and tested. The conditions applied to the test and the measurement results are as follows.

1. Lightweight impact sound measurement result

(Slab THK 150, light weight impact sound 74db)

Finishing Type 125 Hz 250 Hz 500 Hz 1000 Hz 2000 Hz Rating Reduction Example 2-1 No finish 72.5 70.1 66.2 61.9 53.9 62 12 Example 2-2 Reinforced floor 70.8 67.9 60.7 45.3 23.0 57 17 Example 2-3 2 layers of reinforced floor 70.7 67.5 60.4 38.6 22.8 57 17 Example 2-4 Monolium 2.3 mm 69.7 67.2 64.2 57.4 41.8 59 15 Example 2-5 Monolium 4.3 mm 70.3 68.1 65.4 57.1 36.1 60 14 Example 2-6 Ondol floor 73.5 70.0 66.8 60.2 44.3 62 12

2. Lightweight impact sound measurement result

(Slab THK 150, light weight impact sound 54db)

Finishing Type 63 Hz 125 Hz 250 Hz 500 Hz Rating Reduction Example 2-1 No finish 72.5 70.1 66.2 61.9 50 4 Example 2-2 Reinforced floor 70.8 67.9 60.7 45.3 50 4 Example 2-3 2 layers of reinforced floor 70.7 67.5 60.4 38.6 50 4 Example 2-4 Monolium 2.3 mm 69.7 67.2 64.2 57.4 49 5 Example 2-5 Monolium 4.3 mm 70.3 68.1 65.4 57.1 50 4 Example 2-6 Ondol floor 73.5 70.0 66.8 60.2 50 4

As shown in the result table, as a result of applying the floor structure method using the high-insulation high-stiffness lightweight concrete provided by the present invention, the weight impact sound is 50db (weight impact sound), which is the floor impact sound standard for reducing the floor noise of the apartment determined by the Ministry of Construction and Transportation. The specification was found to be satisfied. Therefore, according to the test results as described above, it can be seen that the floor structure according to the present invention has an effect regardless of the type of finishing material in the case of a heavy impact sound.

In addition, in the case of lightweight impact sound, as shown in the result table above, only the case of using the reinforced floor as a finishing material showed the result satisfying the condition of 58db or less of the lightweight impact sound standard prescribed by the Ministry of Construction and Transportation. Therefore, from the above test results, the current finishing method is generally used as a reinforcement floor (wooden wood pulp, a high-density laminate of compressed wood fiber pattern printed on the surface of the wood layer is printed to give a feeling of solid wood A kind of floor finishing material) can be said to be most suitably used in the floor structure for reducing the interlayer impact sound of the present invention.

Although the present invention has been described in detail with reference to the embodiments described above, those skilled in the art to which the present invention pertains will be capable of various substitutions, additions, and modifications without departing from the technical spirit described above. It is to be understood that such modified embodiments also fall within the protection scope of the present invention as defined by the appended claims below.

According to the present invention described in detail as described above, the mass of the entire floor structure is integrated so that the entire floor structure behaves together, which is very effective in reducing the weight impact sound, and the thermal insulation is excellent, so that it is not necessary to use a separate insulating material. As it satisfies the standard of heat permeability, it is possible to replace the existing lightweight foamed concrete and the interlayer noise absorbing material, and to provide the high insulation high stiffness lightweight concrete composition that can obtain the excellent interlayer noise reduction and insulation effect, and the floor structure to reduce the floor impact sound using the same. have.

Claims (5)

A light weight concrete composition for reducing impact sound applied from an upper layer by being poured on top of a concrete slab structure, comprising: cement; Perlite; gypsum; Calcium hydroxide; Calcium carbonate; And calcium chloride; High insulation high stiffness lightweight concrete composition for reducing the floor impact sound comprising a. As a lightweight concrete composition for reducing the impact sound applied from the upper layer is placed on top of the concrete slab structure, A bottom comprising 47.4 to 70.2 parts by weight of ferrite, 5.3 to 10.6 parts by weight of gypsum, 5.3 to 10.6 parts by weight of calcium hydroxide, 10.6 to 21.2 parts by weight of calcium carbonate, and 2.6 to 5.3 parts by weight of calcium chloride High insulation, high rigidity and lightweight concrete composition for impact sound reduction. In the floor structure for reducing the floor impact sound of the building, A concrete slab layer separating the upper and lower layers of the building; Cement is poured on top of the concrete slab layer; Perlite; gypsum; And, high thermal insulation, high rigidity lightweight concrete layers comprising calcium hydroxide; And, A cement mortar layer that is poured on top of the high insulation, high rigidity, lightweight concrete layer; Interlayer impact sound reduction floor structure using a high-insulation high-stiffness lightweight concrete composition comprising a. According to claim 3, wherein the high-insulation, high rigidity lightweight concrete layer is 47.4 to 70.2 parts by weight, 5.3 to 10.6 parts by weight of gypsum, 5.3 to 10.6 parts by weight of calcium hydroxide, 10.6 to 21.2 parts by weight of calcium carbonate, and 100 parts by weight of cement and , Interlayer impact sound reduction floor structure using a high-insulation high rigidity lightweight concrete composition, characterized in that it comprises 2.6 to 5.3 parts by weight of calcium chloride. [4] The interlayer impact sound reduction floor structure using the high insulation high stiffness lightweight concrete composition according to claim 3, wherein a finish layer formed by attaching a reinforced floor plate is further formed on the cement mortar layer.

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