KR101340280B1 - Interior finishging material comprising paper mulberry - Google Patents

Abstract

The present invention relates to a building interior material, and more particularly to a building interior material including a mulberry bast fiber and the core and loess. Building interior materials according to the present invention is an environmentally friendly material without the discharge of environmental pollutants, not only the mechanical strength is greatly improved, but also the building interior materials with excellent moisture control ability through moisture absorption and discharge.

Description

Interior finishing material comprising paper mulberry

The present invention relates to a building interior material containing a mulberry component.

Recently, the new house or building has become a problem of sick house syndrome (Sick House Syndrome), which causes residents to feel health problems and discomfort due to harmful substances from various materials.

The new house syndrome is mainly composed of harmful components such as concrete and cement, which are the basis of building structures, and chemical components used in interior finishing materials such as wallpaper, ceiling materials, and flooring materials, and adhesives used in the process of fixing the interior finishing materials. Hundreds of hazardous substances are known to be emitted. Representative hazardous substances are known to be the main source of formaldehyde and VOC (volatile organic compounds) regulating the acceptance criteria.

In addition, harmful substances such as radon, asbestos, carbon monoxide, carbon dioxide, nitrogen oxides, ozone, fine dust, and floating bacteria generated during construction are not discharged outside the building and accumulate indoors.

Short-term exposure to these harmful substances can cause headache, eyes, nose and throat irritation, flatulence, itching, dizziness, nausea, decreased concentration, fatigue, and sensitivity to odors. It has been reported to cause pneumonia, high fever, heart disease and cancer.

Therefore, various measures to reduce the damage of the sick house syndrome as described above are proposed, such as the method of removing the harmful substances through ventilation or air purification supplies, and the building materials are not eco-friendly The method of replacing with a material is used.

However, the method using ventilation or air purifying products is not a method of post-treatment to quickly remove harmful components that have already occurred, but to prevent the generation of chemical components that are the actual cause of sick house syndrome. Not only does it take a long time to remove it, but the products for air purification also have poor removal efficiency for the unit area, and thus cannot be a fundamental countermeasure.

Recently, development of eco-friendly materials for construction that does not contain chemicals that cause sick house syndrome has been actively conducted. For example, Korean Patent Application No. 2008-2537 has introduced a technology for manufacturing environmentally friendly building interior materials by recycling waste shells, and in Korean Patent Application No. 2007-14659, ocher boards that can be used as a wall or ceiling material and its The manufacturing method has been introduced.

However, when using ocher, there is a cracking phenomenon during drying, and the strength is very weak, so even a small impact is broken or scratched, so there is a problem that frequent exchanges and repairs are required and economical loss occurs. To solve these problems, binders include potassium silicate and pulverized stones, pearlite to improve heat resistance, and calcium carbonate to improve mechanical strength, which improves the disadvantages of ocher products in terms of mechanical strength. In other words, problems such as the weight increase of products are still a problem to be solved.

Inorganic materials such as ocher, white clay, diatomaceous earth, kaolin, etc., which are beneficial to the human body, are mixed with mulberry bast fiber, mulberry bark fiber, or mulberry bast fiber and braid together. In addition to increasing the weight, light weight, and to provide a building construction material with a significant increase in water absorption.

According to another aspect of the present invention, there is provided a building interior material comprising ocher, kaolin, clay, diatomaceous earth, turmeric components.

According to one embodiment of the present invention, the building interior material is provided with a building interior material comprising ocher, kaolin, clay, diatomaceous earth, turmeric components.

According to one embodiment of the present invention, the building material includes 20-32% by weight of ocher, 14-23% by weight of kaolin, 14-23% by weight of clay, 8-14% by weight of diatomaceous earth, 10-40% by weight of mulberry. There is provided a building interior, characterized in that.

According to one embodiment of the present invention, the building interior material is 20-28% by weight of ocher, 14-21% by weight of kaolin, 14-21% by weight of clay, 8-13% by weight of diatomaceous earth, 9-21% by weight of mulberry fiber, mulberry There is provided a building interior material comprising a 9-21% by weight.

According to an embodiment of the present invention, the ocher and kaolin are provided in a built-in building material, characterized in that included in the primary fired form chaebol.

According to another aspect of the present invention, calcining the loess to obtain a loess calcined raw material, calcining kaolin to obtain kaolin calcined raw material, 20-28% by weight of the loess calcined raw material, the kaolin calcined raw material 14-21 Mixing weight%, 14-21% by weight of clay, 8-13% by weight of diatomaceous earth, 9-21% by weight of mulberry bark fiber, 9-21% by weight of mulberry bark to obtain a mixed raw material, molding the mixed raw material There is provided a method for manufacturing the interior decoration materials for building.

Building interior materials according to the present invention is an environmentally friendly material without the discharge of environmental pollutants, not only the mechanical strength is greatly improved, but also the building interior materials with excellent moisture control ability through moisture absorption and discharge.

1 is a reference diagram regarding the strength measurement.

According to an embodiment of the present invention, in the building interior material using the mulberry (a) a method of pulverizing bast fiber of the mulberry wood selected from ocher, clay, diatomaceous earth, kaolin to be the main material of the interior material; (b) a method of pulverizing the genus of mulberry and selecting and mixing among ocher, clay, diatomaceous earth and kaolin, which are the main materials of the interior material; (c) A method of mixing selected bast fibers and bundles of ground mulberry in an appropriate ratio is selected from ocher, white clay, diatomaceous earth, and kaolin, which are the main materials of interior materials.

In particular (a), the interior of the building material utilizing the mulberry, characterized in that the content of 10% by weight of the mulberry bast fiber, 90% by weight of the material selected from loess, clay, diatomaceous earth, kaolin to be the main material of the interior material Is provided.

According to one embodiment, according to (a), 20% by weight of the mulberry bast fiber, the mulberry, characterized in that using 80% by weight of the material selected from loess, clay, diatomaceous earth, kaolin as the main material of the interior material The building interior materials utilized are provided.

According to one embodiment, according to (a), the content of 30% by weight of the mulberry bast fiber, 70% by weight of the material selected from loess, clay, diatomaceous earth, kaolin as the main material of the interior material The building interior materials utilized are provided.

According to one embodiment, according to (a), the content of 40% by weight of the mulberry bast fiber, 60% by weight of the material selected from loess, clay, diatomaceous earth, kaolin as the main material of the interior material The building interior materials utilized are provided.

According to one embodiment, in (b), 10 wt% of the content of the mulberry bark, utilizing the mulberry, characterized in that using 90% by weight of the material selected from loess, clay, diatomaceous earth, kaolin as the main material of the interior material One building interior material is provided.

According to one embodiment, in (b), the content of the mulberry tree 20% by weight, using the mulberry, characterized in that using 80% by weight of the material selected from loess, clay, diatomaceous earth, kaolin as the main material of the interior material One building interior material is provided.

According to one embodiment, in (b), the content of the mulberry bark 30% by weight, using the mulberry, characterized in that using 70% by weight of the material selected from loess, clay, diatomaceous earth, kaolin as the main material of the interior material One building interior material is provided.

According to one embodiment, in (b), the content of the mulberry bark 40% by weight, using the mulberry, characterized in that using 60% by weight of the material selected from loess, clay, diatomaceous earth, kaolin as the main material of the interior material One building interior material is provided.

According to one embodiment, in (c), 80% by weight of the material selected from loess, clay, diatomaceous earth, kaolin, which is the main material of the interior material by mixing 10% by weight of the ground mulberry fiber and 10% by weight of the bark It is provided with a building interior material utilizing a mulberry, characterized in that using.

According to one embodiment, in (c), 70% by weight of the material selected from loess, clay, diatomaceous earth, kaolin, which is the main material of the interior material by mixing 15% by weight of the ground mulberry fiber and 15% by weight of the core It is provided with a building interior material utilizing a mulberry, characterized in that using.

According to one embodiment, in (c), 60% by weight of the material selected from loess, clay, diatomaceous earth, kaolin, which is the main material of the interior material by mixing 20% by weight of the ground mulberry fiber and 20% by weight of the core It is provided with a building interior material utilizing a mulberry, characterized in that using.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. The terms used in the specification or claims of the present application should not be interpreted as having a normal or dictionary meaning. The scope of protection of the present invention should be construed as meaning and concept corresponding to the technical idea of the present invention, and also the application mode presented through the drawings of the present application proposes one embodiment for achieving the object of the present invention. It should be noted that the claims of the present invention are not limited by the drawings and should be broadly protected by the technical idea presented in the present invention.

Manufacturing example  1-11: Fabrication of building materials for construction

The loess powder and kaolin powder were calcined at 800-1,000 ° C. in a high temperature furnace, respectively, to prepare a firing material, pulverizing bask fiber, and then mixing them in a weight ratio as shown in Compositions 1 to 11 in Table 1 below. The composition and 10 L of water were added and mixed and pulverized for 8 hours, and the contents filtered through an 80-100 mesh network were dehydrated by a filter press to obtain 21.5 kg of a raw material of a molded article.

In the present invention, the ocher and kaolin use raw materials calcined at a high temperature, and the clay and diatomaceous earth are used in a non-baked state after firing in order to remove properties that are not easily combined with other materials of ocher and kaolin in the manufacture of the molded article of the present invention. To mix. In addition, the clay and diatomaceous earth are to maintain a high bonding strength with other materials, and in order to reduce the weight of the whole molded article in the case of the bask fiber and the mulberry, and to give mechanical strength, anti-atopic properties, moisture absorption and moisture absorption.

division ocher
Firing raw materials
(weight%) china clay
Firing raw materials
(weight%) Clay
(weight%) Diatomaceous earth
(weight%) Paper mulberry
Bast fiber
(weight%) Mulberry
(weight%) Composition 1 31.5 22.5 22.5 13.5 10 0 Composition 2 28.0 20.0 20.0 12.0 20 0 Composition 3 24.5 17.5 17.5 10.5 30 0 Composition 4 21.0 15.0 15.0 9.0 40 0 Composition 5 31.5 22.5 22.5 13.5 0 10 Composition 6 28.0 20.0 20.0 12.0 0 20 Composition 7 24.5 17.5 17.5 10.5 0 30 Composition 8 21.0 15.0 15.0 9.0 0 40 Composition 9 28.0 20.0 20.0 12.0 10 10 Composition 10 24.5 17.5 17.5 10.5 15 15 Composition 11 21.0 15.0 15.0 9.0 20 20

Example  1-11: Building Interior

In Example 1-11, the molded building material for building interior was manufactured using the molded article raw materials prepared in Preparation Example 1-11, respectively.

In addition, in order to increase the bonding strength of the inorganic molded article of the present invention, after processing into a molded article in the state of Figure 2a after performing the first baking in the range of 850 ± 880 ℃, it is preferable to shake off the dust, apply a surface glaze, and perform the chaebol roasting The glaze used in the present invention is made of 3 kg of persimmon ash and 7 kg of mixed soil (soil made of stone) to make a glaze, and keeps the conglomerate fire temperature 1000 ± 50 ℃ range of 8-10 hours When the molded product is obtained through the step of chaebol, the molded product with strong strength and light weight can be obtained.

Preparation Example 12-13 (Building Interior Material) and Example 12-13 (Building Interior Material)

In Preparation Example 12-13, except that the non-plastic form was used as raw material for loess or kaolin, respectively, building interior materials were manufactured according to the conditions and methods according to Preparation Example 1-11. In addition, in Examples 12-13, the interior materials were manufactured according to the conditions and methods according to Examples 1-11, using the raw materials thus prepared.

Comparative Production Example 1-2 (Building Interior Material) and Comparative Example 1-2 (Building Interior Material)

In Comparative Production Example 1-2, building interior materials were manufactured according to the conditions and methods according to Preparation Example 1-11, except that white clay or diatomaceous earth was used in the calcined form. In Comparative Example 1-2, molded articles were prepared according to the conditions and methods according to Example 1-11, using the raw materials thus prepared.

Test Example  And Comparative test example : Measurement of compressive strength, flexural strength, water absorption

In the above manufacturing examples and comparative examples, the brick-shaped specimens were manufactured according to the method of manufacturing the building interior materials, and the compressive strength, the bending strength, and the absorption rate were measured according to the following methods.

1. Production of specimen

(1) Psalms

a) Floor bricks of the dimensions specified in Table 2 shall be used for the measurement of appearance, dimensions and water absorption. b) For the tests of compressive strength and flexural sensitivity, the face of 190 × 94 mm or 230 × 114 mm specified in Table 2 is to be tested. c) Standards other than Table 2 use floor bricks with dimensions according to the purchaser agreement. d) Five specimens shall be used for the test.

Item Length (L) Butterfly (W) Thickness (H) size 190 94 57 Tolerance ± 3.0 ± 2.5 ± 2.5 size 230 114 50 Tolerance ± 3.5 ± 3.0 ± 2.5 size 230 114 70 Tolerance ± 3.5 ± 3.0 ± 2.5

(2) appearance

The external appearance is visually inspected for the specified specimens and inspected for damages such as cracks.

(3) Dimensions and Dimensional Tolerances

For the measurement of dimensions and dimensional tolerances, the center of the floor brick measurement site is to be measured using a metal straight ruler with a minimum graduation of 1 mm or a length meter with a precision equal to or greater than that specified in KS B 5246.

(4) error

Dimensions and tolerances of floor bricks shall be concluded with the value of each of the five specimens to one decimal place.

2. Compressive strength test

(1) operation

The specimen is dried at 110 ± 5 ° C in advance, taken out after 24 hours, and cooled to room temperature. Using the length of the bottom brick and the surface of the butterfly as the pressing surface, the pressing area A (mm ² ) is obtained. The pressing surface is pressurized evenly by inserting a piece of paper or a rubber plate, if necessary. The pressurization speed is 0.49-0.98 MPa every second, and the maximum load W (N) when the specimen is broken is measured.

(2) calculation

The compressive strength is calculated according to the following formula and ends with one decimal place.

C = P / A (where C stands for compressive strength (MPa), A stands for pressurized area (mm ² ), and P stands for maximum load (N).)

(3) error

The compressive strength of the floor brick is to round off the average of the five calculated values to one decimal place.

3. Flexural Strength Test

(1) operation

Specimens are tested immediately after immersion in water for 24 hours. The specimen is placed as shown in FIG. Apply the load to the extent that does not exceed and measure the maximum load P shown in the tester and calculate the flexural strength according to the following formula.

(2) calculation

Flexural strength is calculated according to the following formula and ends with one decimal place.

Flexural Strength (MPa) = 3PI / 2bd ² (where P is the maximum breaking load (N) indicated by the tester, I is the distance between points (mm), b is the average butterfly in the perpendicular direction between the points (mm), d is the floor brick) Means the average thickness (mm).)

(3) report

The flexural strength of the bottom bricks shall be the average of each of the five specimens and their respective values rounded to one decimal place.

3. Water absorption test

(1) operation

The operation is as follows.

a) Dry the specimen at 110 ± 5 ℃ for 24 hours, cool it to room temperature and weigh it. Let this be mass m₁ (g) at drying.

b) Immediately soak this specimen in water at 20 ± 5 ° C for 24 hours.

c) Remove this specimen from the water and wipe the surface moisture with a damp cloth, weigh it immediately and make it mass m₂ (g) after absorption.

(2) calculation

Absorption rate is calculated according to the following formula and ends at the first decimal place.

a = 100 (m2-m1) / m1 (where a is the water absorption (% by weight), m1 is the mass (g) at drying, and m2 is the mass (g) after absorption)

(3) report

The absorption rate of the bottom bricks is the average of the five calculations of the specimens rounded to one decimal place.

4. Test results

As shown in the table below, Example 1-11 shows improved results in terms of compressive strength, flexural strength, and water absorption compared to Comparative Example 1-2, and in particular, Example 9-11 is more improved than Example 1-8. The result was confirmed.

Examples and Comparative Examples Compressive strength (MPa) Flexural strength (MPa) Absorption rate (% by weight) Example 1 22 3.3 8.3 Example 2 24 3.1 8.1 Example 3 25 3.5 8.0 Example 4 23 3.3 8.1 Example 5 19 3.1 8.1 Example 6 20 2.9 7.9 Example 7 22 2.8 7.9 Example 8 19 2.4 7.5 Example 9 27 3.9 9.2 Example 10 31 4.1 9.7 Example 11 29 3.8 9.3 Example 12 14 2.7 7.2 Example 13 16 2.5 7.1 Comparative Example 1 17 2.3 6.5 Comparative Example 2 15 2.7 7.0

Claims (5)

As a building interior material comprising ocher, kaolin, clay, diatomaceous earth, and mulberry;
The mulberry component includes both mulberry bast fibers and mulberry bundle;
The building interior materials include 20-28% by weight ocher, 14-21% by weight kaolin, 14-21% by weight clay, 8-13% by weight diatomaceous earth, 9-21% by weight of mulberry fiber, 9-21% by weight of mulberry. To;
The loess and the kaolin are contained in a primary calcined form and are grilled chaebol;
The clay and the diatomaceous earth is a building interior, characterized in that the non-fired form. delete delete delete Calcining ocher to obtain an ocher calcined raw material,
Calcining kaolin to obtain kaolin firing raw materials,
Mixing the ocher calcined raw material, the kaolin calcined raw material, clay, diatomaceous earth, bast fiber, and mulberry core to obtain a mixed raw material,
Building construction material manufacturing method comprising the step of molding the mixed raw material.

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