KR100799243B1 - Method for manufacturing bottom structure between floors of building using porous material for insulation and absorption of sound, method for manufacturing side wall structure of building using the same - Google Patents

Abstract

The present invention provides a method for producing a building interfloor structure comprising a concrete slab, comprising: a) a main material comprising vermiculite powder, perlite powder, coal ash, and far infrared ray generating material; Foaming additives including at least one metal powder blowing agent selected from aluminum powder and zinc powder, at least one foaming catalyst selected from slaked lime and quicklime and sodium bicarbonate, and at least one foam stabilizer selected from crystalline cellulose and carboxymethylcellulose (CMC); At least one binding enhancer selected from kaolin and bentonite; And b) preparing at least one ion coagulant selected from montmorillonite and calcium chloride, and b) simultaneously mixing the main material, the foaming additive, the binder strengthening agent, the ion coagulant, and water together. Producing a building interlayer floor structure using a porous sound absorbing and insulating material, characterized in that it comprises the step of forming a porous sound absorbing and insulating material on the concrete slab by curing and pouring the mixture of the porous sound absorbing and insulating material on the concrete slab. Provide a method.

Building interlayer floor structure, building sidewall structure, porous sound absorbing and insulating material

Description

TECHNICAL FIELD OF MANUFACTURING BOTTOM STRUCTURE BETWEEN FLOORS OF BUILDING USING POROUS MATERIAL FOR INSULATION AND ABSORPTION OF SOUND, METHOD FOR MANUFACTURING SIDE WALLSTR OF BUILDING USING THE SAME}

The present invention relates to a porous sound absorbing and insulating material having a high strength and excellent sound absorption and sound insulation, and a method for producing the same, by containing a uniformly distributed pores therein, which can provide a light and excellent heat insulating effect.

In general, a multi-storey apartment or multi-family house has a side wall structure that partitions the same floor and a floor wall that partitions the upper floor and the lower floor, so that various sounds of the lower floor are raised up through the floor wall, and the impact sound of the upper floor is lowered down. In addition to the transmission, there is a problem that noise and impact sound are transmitted as it is through the side wall between the same layer.

In order to solve this problem, in the case of a reinforced concrete building, lightweight foamed concrete is applied on the reinforced concrete slab and then finished with cement mortar or artificial mortar.

Here, although the lightweight foam concrete built on the upper surface of the reinforced concrete slab is responsible for attenuating the noise, in the case of lightweight foam concrete, since the size of the foam is non-uniform and bubbles of the appropriate size are not formed, There is a problem that can not properly block the noise absorbed.

In addition, after pouring lightweight foam concrete, low compressive strength due to cracking causes delays in subsequent processes due to poor fixation of the heating pipe, sinking due to punching breakage and cracking, and the like.

As such, the conventional method for placing lightweight foam concrete cannot provide sufficient noise reduction effect, and inevitably increases air and construction cost.

Accordingly, an object of the present invention is to produce a porous sound absorbing and insulating material having excellent sound absorption and sound insulation by uniformly containing a plurality of bubbles at a low cost, by mixing a main material and a blowing agent comprising at least one selected from vermiculite and pearlite It is to provide a method for producing the same.

The present invention provides a method for producing a building interfloor structure comprising a concrete slab, comprising: a) a main material comprising vermiculite powder, perlite powder, coal ash, and far infrared ray generating material; Foaming additives including at least one metal powder blowing agent selected from aluminum powder and zinc powder, at least one foaming catalyst selected from slaked lime and quicklime and sodium bicarbonate, and at least one foam stabilizer selected from crystalline cellulose and carboxymethylcellulose (CMC); At least one binding enhancer selected from kaolin and bentonite; And b) preparing at least one ion coagulant selected from montmorillonite and calcium chloride, and b) simultaneously mixing the main material, the foaming additive, the binder strengthening agent, the ion coagulant, and water together. Producing a building interlayer floor structure using a porous sound absorbing and insulating material, characterized in that it comprises the step of forming a porous sound absorbing and insulating material on the concrete slab by curing and pouring the mixture of the porous sound absorbing and insulating material on the concrete slab. Provide a method.

The present invention provides a method for producing a building sidewall structure comprising a concrete slab, comprising: a) a main material comprising vermiculite powder, perlite powder, coal ash, and far-infrared ray generating material; Foaming additives including at least one metal powder blowing agent selected from aluminum powder and zinc powder, at least one foaming catalyst selected from slaked lime and quicklime and sodium bicarbonate, and at least one foam stabilizer selected from crystalline cellulose and carboxymethylcellulose (CMC); At least one binding enhancer selected from kaolin and bentonite; And b) preparing at least one ion coagulant selected from montmorillonite and calcium chloride, and b) simultaneously mixing the main material, the foaming additive, the binder strengthening agent, the ion coagulant, and water together. A method of manufacturing a building sidewall structure using a porous sound absorbing and insulating material, comprising: forming a porous sound absorbing and insulating material on the concrete slab by curing and pouring the mixture of the porous sound absorbing and insulating material on the concrete slab. To provide.

As described above, according to the present invention, by containing voids uniformly distributed therein, it is possible to provide a lightweight and excellent heat insulating effect, it is possible to provide a porous sound absorbing and insulating material having high strength and excellent sound absorption and sound insulation. have.

In addition, when the porous sound absorbing and insulating material according to the present invention is applied to a building, the purchase cost of the main material is cheap, and the construction is simple, which can shorten the manpower and air, thereby reducing the construction cost, and between the spaces of the building. The noise transmitted can be eliminated. And, if the far infrared ray generating material is further included, far infrared rays are emitted from the building, it is possible to provide a comfortable living space.

In addition, in the case of manufacturing the porous sound absorbing and insulating material as a building material it is possible to provide a building material with a low manufacturing cost as the purchase price of the main material is low, thereby greatly reducing the building cost.

As one embodiment of the present invention for achieving the above object, porous absorption, characterized in that prepared by mixing a foaming additive comprising a main material and a blowing agent comprising at least one selected from vermiculite powder and perlite powder (perlite) powder Providing sound insulation

The main material is 78 to 99% by weight, preferably 85 to 95% by weight, and the foaming additive is 1 to 22% by weight based on the total weight. Here, when the foaming additive is added in a smaller amount than the one provided, it is not possible to provide a porous sound absorbing and insulating material containing pores uniformly distributed therein. The strength of the sound absorbing and insulating material may be lowered.

In addition, the porous sound absorbing and insulating material may be prepared by further including an additive for strengthening bonds.

At least one selected from the vermiculite powder and the pearlite powder may be prepared by being pulverized to have a particle size of 70 to 150 mesh, and the powder degree of at least one selected from the vermiculite powder and the pearlite powder is 3000 to 7000 cm 2 / g. It may be arranged.

The main material may further include at least one selected from coal ash powder and far infrared ray generating material in addition to the vermiculite powder and pearlite powder.

The coal ash powder is preferably 6 to 14% by weight based on the total weight, and the far-infrared ray generating material uses at least one selected from the group consisting of vermiculite powder, pearlite and loess, and 5 to 10% by weight based on the total weight. It is preferable that it is weight%.

The foaming additive may include a metal powder or a vegetable blowing agent, and may further include at least one selected from a foaming catalyst and a bubble stabilizer.

As the blowing catalyst, one or more selected from the group consisting of 1 to 5% by weight of hydrated lime, quicklime and sodium bicarbonate may be used.

As the bubble stabilizer, one or more selected from 1 to 3% by weight of crystalline cellulose and carboxymethylcellulose (CMC) based on the total weight may be used.

When using 1 to 5% by weight of the metal powder with respect to the total weight as the blowing agent, the main material, the blowing agent and water are mixed together.

As the blowing agent, when using a vegetable blowing agent of 0.8 to 1.5L / ㎡ with respect to the total weight, at least one selected from the vermiculite powder and the pearlite powder and the binding strengthening additive including a bond strengthening agent is mixed to form a main material in the form of a slurry To prepare a first, by mixing the blowing agent and water is first mixed with the air bubbles generated in the slurry.

It is preferable to use at least one selected from 1 to 5% by weight of kaolin and bentonite with respect to the total weight as the binding strengthening agent.

The additive for strengthening the bond may further include an ionic coagulant, and it is preferable to use at least one selected from 1 to 4% by weight of montmorillonite and calcium chloride as the ionic coagulant.

Another embodiment of the invention is a concrete slab; It is provided on the concrete slab, the porous sound absorbing and insulating material; A heating pipe provided on the porous sound absorbing and insulating material; It provides an interlayer floor structure of the building, characterized in that it comprises a finishing malta layer that is poured over the heating pipe.

Another embodiment of the invention is a concrete slab; It is provided on the concrete slab, and provides a side wall structure of the building comprising the porous sound absorbing and insulating material.

Another embodiment of the present invention is a method of manufacturing a building interlayer floor structure comprising a concrete slab, a) a main material comprising vermiculite powder, perlite powder, coal ash, and far-infrared generating material kaolin and bentonite First mixing with at least one binding strengthening agent and at least one ionic coagulant selected from montmorillonite and calcium chloride to form a slurry, and b) mixing the vegetable blowing agent and water to generate bubbles, and then generating the bubbles. Mixing step of preparing a porous sound absorbing and insulating material comprising the step of supplying and mixing; And forming a porous sound absorbing and insulating material on the concrete slab by pouring the mixture of the porous sound absorbing and insulating material on the concrete slab, thereby curing the porous slab. do.

Here, the method may further include installing a heating pipe on the porous sound absorbing and insulating material, and forming a finishing mortar layer on the heating pipe.

78 to 95% by weight of the main material, 1 to 15% by weight of the foaming additive including the foaming agent, the foaming catalyst and the bubble stabilizer, 1 to 5% by weight of the binder strengthening agent, and the ion coagulant 1-4% by weight, and residual water, may be added.

Yet another embodiment of the present invention provides a method of manufacturing a building interlayer floor structure including a concrete slab, comprising: a) a main material comprising vermiculite powder, perlite powder, coal ash, and far infrared ray generating material; Foaming additives including at least one metal powder blowing agent selected from aluminum powder and zinc powder, at least one foaming catalyst selected from slaked lime and quicklime and sodium bicarbonate, and at least one foam stabilizer selected from crystalline cellulose and carboxymethylcellulose (CMC); At least one binding enhancer selected from kaolin and bentonite; And b) preparing at least one ion coagulant selected from montmorillonite and calcium chloride, and b) simultaneously mixing the main material, the foaming additive, the binder strengthening agent, the ion coagulant, and water together. Producing a building interlayer floor structure using a porous sound absorbing and insulating material, characterized in that it comprises the step of forming a porous sound absorbing and insulating material on the concrete slab by curing and pouring the mixture of the porous sound absorbing and insulating material on the concrete slab. Provide a method.

Here, the method may further include installing a heating pipe on the porous sound absorbing and insulating material, and forming a finishing mortar layer on the heating pipe.

78 to 95% by weight of the main material, 1 to 15% by weight of the foaming additive including the foaming agent, the foaming catalyst and the bubble stabilizer, 1 to 5% by weight of the binder strengthening agent, and the ion coagulant 1-4% by weight, and residual water, may be added.

 Yet another embodiment of the present invention provides a method of manufacturing a building sidewall structure including a concrete slab, the method comprising: a) a main material comprising vermiculite powder, perlite powder, coal ash, and far-infrared generating material in kaolin and bentonite First mixing with at least one binding enhancer and at least one ionic coagulant selected from montmorillonite and calcium chloride to form a slurry, and b) mixing the vegetable blowing agent with water to generate bubbles, and then generating bubbles into the slurry. Mixing step of preparing a porous sound absorbing and insulating material comprising the step of supplying and mixing; And forming a porous sound absorbing and insulating material on the concrete slab by pouring the mixture of the porous sound absorbing and insulating material on the concrete slab, thereby curing the composite slab. Can be.

Here, the main material is 78 to 95% by weight based on the total weight, 1 to 15% by weight of the foaming additive containing the blowing agent, the foaming catalyst and the bubble stabilizer, 1 to 5% by weight of the bonding enhancer, the ion Coagulant may be added 1 to 4% by weight, and the balance of water.

Yet another embodiment of the present invention provides a method of manufacturing a building sidewall structure comprising a concrete slab, comprising: a) a main material comprising vermiculite powder, perlite powder, coal ash, and far infrared ray generating material; Foaming additives including at least one metal powder blowing agent selected from aluminum powder and zinc powder, at least one foaming catalyst selected from slaked lime and quicklime and sodium bicarbonate, and at least one foam stabilizer selected from crystalline cellulose and carboxymethylcellulose (CMC); At least one binding enhancer selected from kaolin and bentonite; And b) preparing at least one ion coagulant selected from montmorillonite and calcium chloride, and b) simultaneously mixing the main material, the foaming additive, the binder strengthening agent, the ion coagulant, and water together. A method of manufacturing a building sidewall structure using a porous sound absorbing and insulating material, comprising: forming a porous sound absorbing and insulating material on the concrete slab by curing and pouring the mixture of the porous sound absorbing and insulating material on the concrete slab. Can be provided.

Here, the main material is 78 to 95% by weight based on the total weight, 1 to 15% by weight of the foaming additive containing the blowing agent, the foaming catalyst and the bubble stabilizer, 1 to 5% by weight of the bonding enhancer, the ion Coagulant may be added 1 to 4% by weight, and the balance of water.

Hereinafter, a porous sound absorbing and insulating material according to the present invention will be described in detail. The present invention is not limited to the following examples but can be modified in various forms.

The porous sound absorbing and insulating material according to the present invention comprises a main material comprising at least one selected from vermiculite powder and pearlite powder; It is prepared by mixing a foaming additive including a foaming agent to generate bubbles and a binding strengthening additive including a binding strengthening agent to improve the bonding strength, if necessary.

Vermiculite is porous, typically produced by the alteration of biotite, resulting in large virtual alternation of biotite, or as small particles in soil and old sediments. When heated rapidly to about 300 ℃, the material can expand up to 20 times the original thickness, the expanded vermiculite is very light.

Vermiculite is a weak basic substance having a specific gravity of about 0.2 and a pH of about 8, and the components are shown in Table 1, and have the property of adsorbing organic substances by exchangeable cations, and moderate thermal insulation while reducing temperature sharpening. Can be effective.

Perlite is porous, also known as pearl rock, and is formed by the rapid cooling of highly viscous lava or magma. Rapid heating of crushed pearlite converts the contained water to water vapor, forming small bubbles in the softened rock, which expands to 20 times its original volume. Heat treated pearlite has a very low specific gravity (see Table 2).

Such vermiculite and perlite are finely powdered and water is removed to prepare activated vermiculite powder and perlite powder with many pores remaining, and the two powders are mixed and used as a main material.

Vermiculite powder or pearlite powder is preferably included in 20 to 79% by weight based on the total weight.

That is, vermiculite and pearlite are pulverized and formed by rapid thermal expansion at a temperature of 800 ° C. or higher. This rapid heating rapidly expands into a porous body containing countless pores. In particular, the pearlite powder is a crystal of pores having a large number of pores, and the mineral component is contained as it is.

The vermiculite powder and the pearlite powder are preferably prepared by grinding the vermiculite powder and the pearlite powder to have a particle size of 70 to 150 mesh according to the sieve analysis method, and according to Blaine's method It is preferable that it is 3000-7000 cm <2> / g.

Vermiculite and pearlite used here is preferable because the material cost can be reduced by recycling vermiculite or pearlite generated as a by-product while producing various industrial and horticultural improvement materials. Such vermiculite or pearlite also serves as a mixed material for controlling coagulation.

The main material having such a configuration may further include a coal ash for improving strength and / or a far infrared ray generating material for generating far infrared rays, which is beneficial to the human body.

Coal ash is added to improve the strength, it is preferable to use the fly ash recovered by the dust collector after the pulverized coal is burned at a high temperature of about 1500 ℃ in the combustion boiler of the thermal power plant.

The specific gravity of the fly ash is about 1.9 to 2.4, which is about 2/3 of the vermiculite and pearlite specific gravity, and the main components are SiO ₂ , Al ₂ O ₃ , Fe ₂ O ₃ , and the like, and CaO, MgO, SO ₃ , and Na ₂ O. And small amounts of oxides such as K ₂ O.

The fly ash is preferably dried to 100 to 150 ° C., and then ground to use a powder having a particle size of 70 to 150 mesh. The content of such fly ash is preferably 6 to 14% by weight based on the total weight.

In this way, since the vermiculite, pearlite and fly ash of the porous material is used, the manufacturing cost can be reduced, and the sound absorbing and insulating material according to the present invention formed therein can contain bubbles of a suitable and uniform form. In addition, the same volume can be made more porous, and the sound absorbing and blocking properties of the sound absorbing material are enhanced by the bubbles inside the sound absorbing material, thereby significantly reducing the noise of the adjacent space and improving the heat insulating effect.

Far-infrared ray-generating materials use materials that generate far-infrared rays when they absorb an appropriate amount of heat.

The far-infrared ray generating material uses at least one selected from vermiculite powder, pearlite powder, and ocher powder, and the content of the far-infrared ray generating material is preferably 5 to 10% by weight of the total weight.

Vermiculite used as far-infrared-generating raw material not only emits far-infrared rays, but also has various functions such as heat insulation, heat storage, and humidity control (see Table 3). Accordingly, in the building to which the porous sound absorbing and insulating material is applied according to the present invention, far-infrared rays which are beneficial to a person can be emitted to provide a comfortable living space.

The foaming additive may include a foaming agent mixed with the aforementioned main material to generate bubbles, and may further include at least one selected from a foaming catalyst for foaming and a bubble stabilizer.

The foaming agent is an additive that generates bubbles of a proper size in the porous sound absorbing and insulating material. After the porous sound absorbing and insulating material is cured and hardened, the entire inside of the porous sound absorbing and insulating material becomes a combination of pores and pores generated by bubbles. That is, the bubbles generated by the foaming agent form voids, and the voids provide the porous sound absorbing and insulating material according to the present invention with the ability to absorb and absorb various fine lightweight sounds.

Such a foaming agent may use a metal powder such as aluminum (Al) or zinc (Zn), or may use a liquid vegetable foaming agent.

As the blowing agent, aluminum powder and / or zinc powder may be used in an amount of 1 to 5% by weight based on the total weight, and a vegetable blowing agent may be used in an amount of 0.8 to 1.5 l / m 2 based on the total weight.

Foaming catalyst is added to facilitate the foaming action of the blowing agent, it is preferable to use at least one selected from slaked lime, quicklime and sodium bicarbonate in 1 to 5% by weight based on the total weight.

Bubble stabilizers are added for stable generation of bubbles and uniform distribution of bubbles, and preferably at least one selected from crystalline cellulose and CMC (carboxymethylcellulose). It is preferable that the content is 1-3 weight% with respect to the total weight. Here, it is preferable that cellulose and CMC have a viscosity of 2,000 cps or more. In addition, such a bubble stabilizer is excellent in affinity with vermiculite and pearlite, and as a result of high adhesion, it is possible to give a high elastic modulus and tensile force.

The binding strengthening additive may include a binding strengthening agent to have a strong binding force between the components in powder form, and may further include an ionic coagulant. That is, the additive for strengthening the bond serves to form a solid structure by firmly bonding the blowing agent and the main material in the powder state.

Here, it is preferable to use at least one selected from 1 to 5% by weight of kaolin and bentonite with respect to the total weight of the binder.

Kaolin is an iron-rich binder, an eco-friendly material with adsorption-and-desorption, breathability, and humidity control. Bentonite is used as a strength imparting agent to enhance the strength of inorganic materials due to the properties of montmorillonite, the main mineral. The addition of such a binding enhancer can improve the strength of the porous sound absorbing and insulating material of the present invention.

It is preferable to use any one selected from montmorillonite and calcium chloride as an ionic coagulant.

On the other hand, the (negative) ion coagulant serves to remove the positive and negative ions generated when the porous sound absorbing and insulating material is manufactured. If the negative and positive ions present in the porous sound absorbing and insulating material, the crack may occur due to dry shrinkage, thereby preventing the strength. Well, cationic coagulants include montmorillonite and calcium chloride because they can be used as excellent cation trapping agents as colloidal minerals with high specific surface area. The content of the ionic coagulant is preferably 1 to 4% by weight relative to the total weight.

Hereinafter, a method of manufacturing a porous sound absorbing and insulating material according to the present invention will be described in detail.

One embodiment of the method for manufacturing a porous sound absorbing and insulating material according to the present invention comprises the steps of: a) mixing a main material including activated vermiculite powder, pearlite powder, coal ash and far-infrared ray generating material with a binding strengthening additive to form a slurry; b) mixing the foaming agent and water to generate bubbles, and then supplying the generated bubbles to the slurry and mixing them.

When mixing the powdered main material and the additive for strengthening the bonding in step a), the binder strengthening agents such as kaolin and bentonite are mixed into the colloidal form in the liquid form so as to be evenly mixed with the main materials together with the ionic coagulant. The main materials are then mixed with the binder strengthening agent to form a slurry.

In step b), the liquid vegetable blowing agent and water are mixed to generate air bubbles in advance, and the air bubbles are supplied to the main material in the form of a slurry using a compressor bubble generator. This method is not only easy to control the amount of bubbles, but also easy to foam at the construction site, it is possible to obtain a relatively uniform independent bubble.

Another embodiment of the method for manufacturing a porous sound absorbing and insulating material according to the present invention comprises the steps of: a) preparing a main material, including an activated vermiculite powder, pearlite powder, coal ash and far-infrared ray generating material, an additive for strengthening a strengthening and an additive for foaming; b) mixing the main material, the bonding strengthening additive, the foaming additive and water.

In step a), vermiculite powder, perlite powder, coal ash and far-infrared ray generating material are mixed in the mixer and stored in the storage tank, the binder strengthening agent and the ion coagulant are stored in the storage tank in the mixer, and the foaming agent, foam catalyst and foam stabilizer are Mix and store in storage tank.

In step b), as shown in Figure 1, the main material powder, the binding reinforcing additive, the foaming additive and the water stored in each storage tank are mixed at the same time in a mixer.

In this case, the foaming agent uses a metal powder such as aluminum powder and / or zinc powder, and the aluminum powder and / or zinc powder mixed with the main material in the form of powder is hydrogen in the process of curing after pouring the porous sound absorbing and insulating material according to the present invention. It generates a bubble generating reaction that generates. Then, bubbles having a predetermined size are generated at the sites where these metal powders are present so that the porous sound absorbing and insulating material according to the present invention has a plurality of pores.

The porous sound absorbing and insulating material produced by the above-mentioned method is transported from the mixer to the weighing and packaging process and shipped in a packaged state.

Next, a method of placing the porous sound absorbing and insulating material manufactured by such a manufacturing method in a building will be described.

The mixture of the porous sound absorbing and insulating material completed by the above-described method is filled into the formwork installed on the concrete slab of the building through a slurry supply device (ex. Compression pump), and then cured for a predetermined time, according to the present invention on the concrete slab. Porous sound absorbing and insulating material is completed. That is, when the mixture of the porous sound absorbing and insulating material according to the present invention, which has been mixed by the above-described method, is filled into the formwork through a slurry supply device (compression pump, etc.), it has many pores as it is caked like cement concrete while leaving numerous pores. It is completed with a porous sound absorbing and insulating material.

And if the finishing mortar after installing the heating pipe immediately without installing other sound absorbing and insulating sheets on the porous sound absorbing and insulating material, the construction of the interlayer floor structure of the building is completed.

In order to prevent lightweight noise between floors, various sound absorption and sound insulation sheets are laid on the concrete slab that divides the space of the building up and down, lightweight foam concrete layer is formed on it, heating piping is placed, and finishing mortar is used. Unlike the conventionally required additionally, by constructing the porous sound absorbing and insulating material directly on the concrete slab can provide the effect of the construction cost, manpower and air shortening.

In addition, the porous sound absorbing and insulating material according to the present invention constructed as described above contains a large number of bubbles in a uniform form, and is not only lightweight, but also absorbs vibrations and noise generated in the building through the bubbles, thereby providing excellent sound insulation effect. Can be provided. In addition, due to the bubbles present in the porous sound absorbing and insulating material, the thermal insulation effect can be greatly improved. In addition, since the strength of the porous sound absorbing and insulating material is improved by the added binding reinforcing agent, it is possible to prevent cracking due to cracks during construction.

On the other hand, the materials used in the porous sound absorbing and insulating material according to the present invention, such as vermiculite, pearlite and fly ash, as well as the low cost, as well as the already discharged after being used in other industrial materials, that is, by recycling the already used material Because of the use, the eco-friendly effect is large, the purchase price is cheaper, it provides an effect that can significantly reduce the manufacturing cost.

In the above-described embodiment, the porous sound absorbing and insulating material according to the present invention is described as being placed on the floor partitioning the upper and lower spaces of the building, but may be applied to the side wall structure partitioning the same side of the building, the porous sound absorbing and insulating material according to the present invention It can be molded into blocks like bricks and commercialized into general building materials.

1 is a view showing a schematic manufacturing process diagram of a porous sound absorbing and insulating material according to the present invention.

Claims (5)

In the method of manufacturing a building interlayer floor structure comprising a concrete slab, a) a main material comprising vermiculite powder, perlite powder, coal ash, and far infrared ray generating material; Foaming additives including at least one metal powder blowing agent selected from aluminum powder and zinc powder, at least one foaming catalyst selected from slaked lime and quicklime and sodium bicarbonate, and at least one foam stabilizer selected from crystalline cellulose and carboxymethylcellulose (CMC); At least one binding enhancer selected from kaolin and bentonite; And b) preparing at least one ion coagulant selected from montmorillonite and calcium chloride, and b) simultaneously mixing the main material, the foaming additive, the binder strengthening agent, the ion coagulant, and water together. Mixture preparation step and Forming a porous sound absorbing and insulating material on the concrete slab by curing after pouring the mixture of the porous sound absorbing and insulating material on the concrete slab. Method of manufacturing a building interlayer floor structure using a porous sound absorbing and insulating material comprising a. The method according to claim 1, Installing a heating pipe on the porous sound absorbing and insulating material; Forming a finishing mortar layer on the heating pipe Method of manufacturing a building interlayer floor structure using a porous sound absorbing and insulating material further comprising. The method according to claim 2, 78 to 95% by weight of the main material, 1 to 15% by weight of the foaming additive including the foaming agent, the foaming catalyst and the bubble stabilizer, 1 to 5% by weight of the binder strengthening agent, and the ion coagulant 1 to 4% by weight, and the remaining amount of water is added to the method of manufacturing a building interlayer floor structure using a porous sound absorbing and insulating material. In the method of manufacturing a building sidewall structure comprising a concrete slab, a) a main material comprising vermiculite powder, perlite powder, coal ash, and far infrared ray generating material; Foaming additives including at least one metal powder blowing agent selected from aluminum powder and zinc powder, at least one foaming catalyst selected from slaked lime and quicklime and sodium bicarbonate, and at least one foam stabilizer selected from crystalline cellulose and carboxymethylcellulose (CMC); At least one binding enhancer selected from kaolin and bentonite; And b) preparing at least one ion coagulant selected from montmorillonite and calcium chloride, and b) simultaneously mixing the main material, the foaming additive, the binder strengthening agent, the ion coagulant, and water together. Mixture preparation step and Forming a porous sound absorbing and insulating material on the concrete slab by curing after pouring the mixture of the porous sound absorbing and insulating material on the concrete slab. Method of manufacturing a building sidewall structure using a porous sound absorbing and insulating material comprising a. The method according to claim 4, 78 to 95% by weight of the main material, 1 to 15% by weight of the foaming additive including the foaming agent, the foaming catalyst and the bubble stabilizer, 1 to 5% by weight of the binder strengthening agent, and the ion coagulant 1 to 4% by weight, and a residual amount of water is added, the manufacturing method of the building sidewall structure using a porous sound-absorbing sound insulating material.

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