JP5061396B2 - Method of painting with diatomaceous earth interior coating material and diatomaceous earth interior coating material used in the painting method - Google Patents

Description

  The present invention relates to a coating method using a diatomaceous earth indoor coating material and a diatomaceous earth indoor coating material used in the coating method.

The interior of the house is a place for daily life, and since it stays there for many hours, it is easily affected by the environment.
In the interior wall and ceiling, in addition to its color and brightness, it should be greatly influenced by the coating material such as the wall material to be constructed there, but it should be positively affected, It may cause environmental allergies, cause wrinkles, and cause various diseases. In addition, with the spread of mobile phones, large screen television receivers, microwave ovens, and the like, they are also more susceptible to indoor electromagnetic waves.
Organic wall materials (vinyl cloth) are used for building interior materials and inner wall materials, but it is known that the adhesive used to bond the wall surface causes sick house syndrome and the like. However, organic adhesives that contain a large amount of volatile organic substances such as formalin, which are harmful to the human body, are harmful to the human body. There is a problem of being.
On the other hand, in Japan where the humidity is high, the interior materials and inner wall materials of buildings are required to have a humidity control function, but in general, the release rate of moisture held inside is small, so After a certain period of time, the amount of water absorption will be saturated and surface condensation will occur again, or it will be inferior to the indoor humidity control function of releasing moisture according to the dryness of the room, so in the interior of highly airtight apartments and buildings, Condensation occurs inside or on the surface of the wall, and moisture from this condensation causes wetting of the wall, generation of stains, reproduction of mold, mites, etc., thereby reducing the durability of the wall and the living environment. There is a problem that.
JP 7-48556 A

In view of the above matters, the present invention aims to provide a coating method using a diatomite-based indoor coating material that can have a positive impact on the environment, and a diatomaceous earth-based indoor coating material used in the coating method. .
Other objects and novel features of the present invention will become apparent from the entire description of the present specification.

The claims of the present invention are as follows.
(Claim 1) A quartz schist containing 80 to 90 wt% of SiO ₂ in a diatomaceous earth-based indoor coating material containing 40 wt% to 95 wt% of diatomaceous earth fossilized with latex as a coating film forming component. A coating method using a diatomaceous earth-based indoor coating material, characterized in that the interior of a building is coated with an indoor coating material to which crushed quartz schist powder is added.
(Claim 2) The quartz schist powder obtained by pulverizing quartz schist is added to a diatomaceous earth-based indoor coating material containing diatomaceous earth at 1 to 10% by weight. How to paint with diatomaceous earth interior coating material.
(Claim 3) The quartz schist is a quartz schist having a composition comprising SiO ₂ 80 to 90 wt%, AL ₂ O ₃ 8 to 9 wt% and Fe ₂ O ₃ 0.7 to 0.8 wt%. The coating method by the diatomaceous earth type indoor coating material of Claim 1 or 2.
(Claim 4) Quartz formed by pulverizing quartz schist and 99-90% by weight of a diatomaceous earth-based indoor coating material containing 40% by weight to 95% by weight of diatomite fossilized by latex, using latex as a coating film forming component. A diatomaceous earth-based indoor coating material comprising 1 to 10% by weight of schist powder.
(Claim 5) The quartz schist is a quartz schist having a composition comprising SiO ₂ 80 to 90 wt%, AL ₂ O ₃ 8 to 9 wt% and Fe ₂ O ₃ 0.7 to 0.8 wt%. The diatomaceous earth indoor coating material according to claim 4.

The interior coating material to be applied to the interior of the building according to the present invention is a diatomaceous earth-based interior coating material containing 40 wt% to 95 wt% of diatomite fossilized by aloe , using latex as a coating film forming component , Six house made by adding quartz schist powder obtained by crushing quartz schist containing 80 to 90 wt% of SiO ₂ , high humidity control effect, no mold stains, good adhesion, and easy coating. As the organic substance is volatilized, it does not affect the human body or pollute the room, and the negative ion effect has no effect. High, far-infrared effect, excellent electromagnetic wave absorption and decomposition effect, and excellent wave effect.

As a diatomite-based indoor coating material containing diatomaceous earth used in the present invention , latex is used as a coating film forming component, diatomaceous earth is used as a filler, other pigments, extender pigments and aggregates, water The coating wall material diluted with is mentioned.

The claims of the present invention are as follows.
(Claim 1) A diatomite-based indoor coating material containing 40% by weight to 95% by weight of diatomite fossilized by latex using a latex as a coating film forming component, SiO ₂ 80-90 wt%, AL ₂ O ₃ 8 The interior of a building is coated with an interior coating material obtained by adding quartz schist powder obtained by pulverizing quartz schist having an ingredient composition of up to 9 wt% and Fe ₂ O ₃ 0.7 to 0.8 wt%. The painting method with the characteristic diatomaceous earth interior coating material.
Including with respect to (claim 2) diatomaceous earth-based indoor coating material comprising diatomaceous _{earth, SiO 2 80~90wt%, AL 2} O 3 8~9wt% and _Fe 2 _O 3 _0.7~0.8wt% The method for coating with a diatomite-based indoor coating material according to claim 1, wherein 1 to 10% by weight of quartz schist powder obtained by pulverizing quartz schist of component composition is added.
(Claim 3) 99 to 90% by weight of a diatomaceous earth-based indoor coating material containing 40% by weight to 95% by weight of diatomite fossilized with latex as a coating film forming component, and SiO ₂ 80 to 90% by weight, A diatomaceous earth comprising 1 to 10% by weight of quartz schist powder obtained by pulverizing quartz schist having an ingredient composition containing 8 to 9% by weight of AL ₂ O ₃ and 0.7 to 0.8% by weight of Fe ₂ O ₃ Interior coating material.

As the latex, aqueous latex is preferably used, and chloroprene latex is preferably used. Chloroprene latex can be diluted with water without using a solvent and can be operated. It has excellent workability and high adhesive ability. The chloroprene latex used here is preferably an aqueous emulsion having a solid content of 30% by weight or more. Chloroprene has fluidity in the emulsion state and can be handled. However, chloroprene is deprived of moisture, becomes a crosslinked polymer, and is dried and solidified. At this time, if the solid content is low, crosslinking is difficult. In the present invention, the amount of chloroprene is preferably 10% by weight or more of the total amount in order to bring out the ability as an adhesive matrix by connecting the inorganic filler, which is a structural material, in a form in which chloroprene is crosslinked.
As the chloroprene latex, those obtained by chemically modifying chloroprene can also be used. Examples include, but are not limited to, carboxylated chloroprene, alcohol-modified chloroprene, sulfonated chloroprene, and isocyanated chloroprene. The carboxylated chloroprene latex is not particularly limited as long as it has a carboxyl group in the molecule, but is usually an unsaturated carboxylic acid that can be copolymerized with 2-chloro-1,3-butadiene, such as acrylic acid and The esters, methacrylic acid and esters thereof, itaconic acid and esters thereof may be mentioned, and these may be obtained by copolymerization using an emulsion polymerization method in the presence of polyvinyl alcohol or a water-soluble polymer having a protective colloid effect. Can do.

The diatomaceous earth interior coating material contains diatomaceous earth as a filler.
In particular, as the diatomaceous earth, a fossilized diatom can be used, but a fossilized aloe is preferably a natural natural material. The diatomite fossilized by the aloe is a porous (thousand times larger than charcoal) choke-like substance mainly composed of silicic acid.
The diatomaceous earth is used, for example, in the range of 40% by weight to 95% by weight , preferably 50% by weight to 80% by weight, based on the total amount of the diatomaceous earth indoor coating material. When the mixing ratio of the diatomaceous earth is out of the above range, the strength of the matrix for adhesion performance becomes insufficient, the diatomaceous earth interior coating material thickens, or the compatibility between the latex and the diatomaceous earth is incompatible. It becomes easy to become enough.

The diatomaceous earth indoor coating material can contain a pigment.
The pigment can be used as a colorant. Examples of the pigment include titanium oxide.
When titanium oxide is added to the diatomaceous earth interior coating material, organic substances can be decomposed and removed by the photocatalytic function of titanium oxide, preventing dirt from accumulating on the wall surface, and the growth of mold and bacteria. Can be blocked. The compounding quantity of a titanium oxide can be set to 0.1 to 10 weight%.

The diatomaceous earth based coating material can contain extender pigments.
An example of the extender pigment is calcium carbonate. The extender pigment reinforces the strength of the coating film and increases the stretchability of the coating. The amount of the extender pigment can be set to 0.1 to 10% by weight.

The diatomaceous earth indoor coating material can contain an aggregate.
As the aggregate, for example, a microceramic can be used.
For example, an expanded peridotite, an expanded perlite, a shirasu balloon or the like known as a lightweight aggregate can be used.
By adding the aggregate, it is possible to increase the extensibility of the application and prevent sagging during application.
The aggregate can be used at 1 to 20% by weight based on the whole diatomaceous earth based coating material.
Yes, and more preferably 5 to 10% by weight. When the addition amount is less than 1 part by weight, the stretchability of the coating is increased, and it is difficult to achieve the effect in the construction workability of preventing the sagging drop during the painting work. Saturated and not economical.

  The diatomaceous earth interior coating material can be diluted with water and used as a coating wall material for coating walls and ceilings in buildings. It is preferable to use distilled water as the water.

As the said diatomaceous earth-type indoor coating material, what is marketed by the name of Diatomas from Ebaur company etc. can be used, for example.
The diatomite-based interior coating material is mainly used as a coating wall material, has a high humidity control effect, is free of mold stains, has good adhesion, makes the coating work easy, and contains almost no formaldehyde that causes Six House. Since it is neither contained nor is it aqueous and does not use an organic solvent, the volatilization of the organic substance does not affect the human body or pollute the room.
In particular, diatomite fossilized by aloe is preferably used as the diatomaceous earth contained as a filler, and diatomaceous earth fossilized by aloe is a natural natural material that is several thousand times larger than charcoal. It is porous and is used as a filtering agent for beer, etc., has excellent humidity control function, has excellent deodorization, heat insulation, heat retention, and cold insulation effects, and has high soundproofing and sound insulation effects. High moldability, no mold stains, good adhesion, easy coating, almost no formaldehyde that causes Six House, and no organic solvent is used because it is water-based. Therefore, the human body is not affected and the room is not polluted.
The diatomaceous earth-based interior coating material containing the diatomite fossilized by the aloe was originally developed on a painted wall with a base material mainly used as a Gibbs material by an American surgeon.
Formaldehyde causing Six House is 0.2 ppm or less, and it is certified not to generate formaldehyde (Japan certified number MFN-1321).
The diatomite-based indoor coating material can be easily used even by an amateur by a coating method such as troweling or spraying.

In the present invention, a quartz schist powder obtained by pulverizing quartz schist is added to the diatomaceous earth-based indoor coating material containing diatomaceous earth to constitute the indoor coating material.
Examples of the quartz schist include natural ceramics produced in the northern area of Kita-saraku-gun, Aichi Prefecture.
The natural ceramics is estimated to have been generated at an ultra-high pressure of 10,000 atmospheres and an ultra-high temperature due to large-scale crustal deformation that occurred when two plates collided about 20 million years ago. It is a kind of quartz schist in the Ryoke metamorphic belt on the structure line, and has a very high hardness and a large amount of far-infrared radiation from the specificity of its crystal structure, and also redox action by such far-infrared rays, It has a negative ion generating action, an adsorption action due to being porous, and the like. In addition, it has excellent wear resistance, impact resistance, heat resistance, and chemical resistance such as acid and alkali. The natural ceramic is mainly composed of quartz, soda feldspar, potassium feldspar, and mica. It has become.
The quartz schist may be referred to as “boiled stone” or “stepped quartzite” in addition to the name of natural ceramics, and the “boiled stone” is SiO ₂ 80-90 wt%, It has a component composition containing AL ₂ O ₃ 8-9 wt % and Fe ₂ O ₃ 0.7-0.8 wt %.
The quartz schist powder obtained by pulverizing the quartz schist includes not only the pulverized raw granite powder itself but also ceramics obtained by molding and sintering the powder obtained by pulverizing the olivine.

    The indoor coating material obtained by adding the quartz schist powder obtained by pulverizing the above quartz schist to the diatomaceous earth based indoor coating material containing the above diatomaceous earth according to the present invention has a high humidity control effect and is free from mold stains. , Good adhesion, easy to apply, almost no formaldehyde that causes Six House, and it is water-free and does not use organic solvents. At the same time, the interior is not polluted, and the negative ion effect is high, the far-infrared effect is excellent, the electromagnetic wave absorption / decomposition effect is excellent, and the wave effect is excellent.

The mixing ratio of the quartz schist powder obtained by pulverizing the quartz schist is calculated by the formula of the quartz schist powder / the diatomite-based indoor coating material X100 = 1 to 10% by weight, and is 1 to 10% by weight.
If the blending ratio of the quartz schist powder obtained by pulverizing the quartz schist is less than 1% by weight, it is difficult to exert negative ion generation, far-infrared effect, electromagnetic wave absorption and decomposition effect, and wave effect. If it exceeds, the effect is saturated and it is not economical.

  The indoor coating material of the present invention may be prepared by adding a quartz schist powder obtained by pulverizing quartz schist to a diatomaceous earth indoor coating material containing diatomaceous earth, or a diatomaceous earth room containing the diatomaceous earth. You may make it contain the quartz schist powder formed by grind | pulverizing a quartz schist at the time of preparation of a coating material.

You may mix | blend ferrite with the diatomaceous earth type indoor coating material used by this invention as needed. If ferrite is blended in the diatomite-based indoor coating material, the function of absorbing electromagnetic waves by the ferrite can be exhibited. Ferrite also has a function to prevent the generation of static electricity.
When foamed glass powder is blended, shrinkage after coating can be prevented.
As described above, diatomaceous earth is excellent in the humidity control function, so it is not necessary, but an inorganic humidity control material may be used. Examples of the inorganic humidity control material include charcoal, activated carbon, siliceous shale, allophane, zeolite, sepiolite, attapulgite, montmorillonite, zonolite, activated clay, silica gel, imogolite, and Otani stone powder.
As the diatomaceous earth, it is preferable to use a diatomaceous earth in which the aloe is fossilized, but a diatomaceous earth having excellent humidity control properties such as Wakkanai diatomaceous earth in Hokkaido may be used in combination.

The diatomaceous earth indoor coating material of the present invention can be used for coating walls, ceilings and the like inside a room of a building.
The diatomite-based indoor coating material of the present invention can be used in place of the wall material made of vinyl cloth, and can be used as a painted wall material.
The painted wall structure is widely used for finishing indoor wall surfaces of Japanese-style houses, etc., and plaster and mortar are sometimes used as the painted wall material, and plaster and mortar are sometimes used.
The plastered plaster wall has a pure white appearance, is beautiful, and has a hygroscopic property, so that it has a function of removing moisture in the room. Stucco is a slaked lime that is easy to paste and has a white appearance and is beautiful, but has no moisture absorption function.
Although the conventional painted wall structure is not hygroscopic or has hygroscopicity, the moisture once absorbed is not easily released, so there was a problem of promoting the generation of condensation and mold. The indoor coating material has a humidity control function, and has a function of absorbing and releasing moisture in the room. The diatomaceous earth indoor coating material of the present invention can be used in place of the plaster, wall soil, plaster, mortar and the like.
The painted wall layer of the diatomaceous earth based indoor coating material of the present invention usually constitutes the finished surface of the wall. The coating wall layer may be a single layer, or may be composed of a decorative layer disposed on the surface side of the wall and an undercoat layer disposed on the back side of the decorative layer. The makeup layer and the undercoat layer have the same basic configuration.
The coating wall layer can be formed by applying a slurry or kneaded coating wall material to a wall surface of a building with a certain thickness and drying and solidifying the coating wall layer.

(Embodiment of the Invention)
In order to provide an understanding of the present invention, examples are described below. Needless to say, the present invention is not limited to the following examples.

Example 1
Diatomus II (Evawol) consisting of acrylic latex as a coating film forming element, diatomite fossilized by aloe as filler, titanium oxide, calcium carbonate, aggregate microceramic, and diluted distilled water Coated wall material is prepared by blending 5% 800g of quartz schist (natural ceramic) powder with an average particle size of 350um obtained by pulverizing quartz schist for 10kg. It applied with "trowel".
Natural ceramics are SiO ₂ 84.16 wt%, AL ₂ O ₃ 8.14% , Fe ₂ O ₃ 0.76%, TiO ₂ 0.22%, CaO 0.71%, MgO 0.21%, KgO 3. The composition was .39%, Na ₂ O 1.94%, and the remaining 5.59%.

Mind-body wave measurement was performed on the quartz schist (natural ceramic) powder. A bathhouse using the quartz schist was created at Omachi Onsen, Nagano Prefecture, and the effects on the body and mind were compared. A positive value in the table indicates that the larger the value, the better the garden condition. In “anger”, +20 has no anger at all.
The results are shown in Table 1.

  It can be seen from Table 1 that the quartz schist bath has a positive effect on the entire mind and body, and can also have a positive effect on emotions.

About the said quartz schist (natural ceramic) powder, deodorizing performance was observed by hydrogen sulfide concentration, ammonia concentration, and residual chlorine concentration measurement.
In the measurement of hydrogen sulfide concentration and ammonia concentration, hydrogen sulfide and ammonia were put in a glass bottle (measurement vessel), and the decrease in the concentration was measured with a semiconductor scent sensor NS700 / NS710 (manufactured by Keyence Corporation). We compared stainless steel and tile.
In the measurement of residual chlorine concentration, 100 g of quartz schist (natural ceramic) powder was put into 50 ml of tap water, and the residual chlorine in the tap water by the quartz schist was measured over time.
The results are shown in Table 2, Table 3 and Table 4.

It can be seen from Tables 2 to 4 that the quartz schist has a deodorizing effect.

The far-infrared radiation energy amount of the quartz schist (solid line 1) at 200 ° C. was measured.
The result is shown in FIG.
FIG. 1 also shows the far-infrared radiant energy amount of quartz schist at 40 ° C. (dashed line 2) and the far-infrared radiant energy amount of synthetic zeolite at 200 ° C. (dashed line 3).

  It can be seen from FIG. 1 that quartz schist has a large amount of far infrared radiation energy.

The far-infrared radiation energy rates of the quartz schist (solid line 4) and synthetic zeolite (dashed line 5) at 60 ° C. were measured.
Here, far-infrared emissivity means that the far-infrared emissivity of a specimen is measured between wavelengths of 4 to 24 μm, and is compared with an ideal black body (a material having a far-infrared emissivity of about 100%) It is shown as a percentage. As such measurement conditions, measuring machine: JIR-5300 manufactured by JEOL Ltd., measuring temperature: 135 ° C. were adopted.
The result is shown in FIG.

The amount of negative ions generated from quartz schist was measured. The graph is shown in FIG.
For comparison, FIG. 4 shows a graph of the negative ion generation amount of tourmaline.
For the measurement of negative ions, water was circulated through a stainless steel column filled with quartz schist and tourmaline fine powder, and the activated water was taken in a beaker. This water was taken out and absorbed by Japanese paper, and placed in a measurement suction port of a KST-900 ion tester manufactured by Kobe Radio Co., Ltd. The amount of negative ions generated was measured while aspirating air.
3 and 4, the vertical axis represents the number of ions / cc, and the horizontal axis represents the measurement time (number of times). In the case of quartz schist, it exceeds the upper limit of measurement of 50,000 and is estimated to be about 70,000 to 80,000. On the other hand, in the case of tourmaline, the maximum number is 10,000, and the average is 5,000. Accordingly, it is understood that quartz schist has a negative ion generation capability at least about 7 to 8 times that of tourmaline, and exhibits a large negative ion effect with a small amount of adhesion.
The negative ion is a negatively charged particle (small ion) in which about 10 to 100 molecules are gathered and floated in the air. This occurs when neutral molecules are irradiated with energy such as radiation, ultraviolet rays, heat rays (far infrared rays), etc., and negative electrons are peeled off, and the peeled negative electrons are captured by other molecules. In addition, when fine water droplets break up in the air, the water droplets are charged to the anode, and the surrounding air is also caused by the ionization phenomenon (Leonard phenomenon) of the air charged to the cathode. Negative ions have excellent effects on stiff shoulders, neuralgia, rheumatism, coldness, low back pain, roughness, bruise, sprains, frostburn and skin burns, fatigue recovery, restful sleep, and constitution improvement (called negative ion effects) It is known.

  The present invention can be applied not only to automobiles but also to building-related products, home appliances, and the like.

It is a graph of the measurement result of far-infrared radiation energy amount. It is a graph of the measurement result of a far-infrared radiation energy rate. It is a graph of the measurement result of the negative ion generation amount of quartz schist. It is a graph of the measurement result of the negative ion generation amount of tourmaline.

Explanation of symbols

1 ... Far-infrared radiation energy of quartz schist at 200 ° C 2 ... Far-infrared radiation energy of quartz schist at 40 ° C 3 ... Far-infrared radiation energy of synthetic zeolite 4 ... Negative ion generation amount of quartz schist 5 ... Synthetic zeolite Negative ion generation

Claims (3)

A diatomite-based indoor coating material containing latex as a coating film-forming component and 40% to 95% by weight of diatomite fossilized by aloe, SiO ₂ 80 to 90 wt%, AL ₂ O ₃ 8 to 9 wt% and Fe diatomite system characterized by applying a coating to the interior of the building at the room painted material formed by adding quartz schist powder obtained by pulverizing a quartz schists component composition comprising ₂ O _{3 0.7~0.8wt%} How to paint with interior paint. Quartz schist with a component composition containing 80 to 90 wt% of SiO _2, 8 to 9 wt% of AL ₂ O ₃ and 0.7 to 0.8 wt% of Fe ₂ O _{3 with} respect to a diatomaceous earth based coating material containing diatomaceous earth. The method for coating with a diatomite-based indoor coating material according to claim 1, wherein 1 to 10 wt% of quartz schist powder obtained by pulverizing is added. 99-90% by weight of a diatomaceous earth-based indoor coating material containing 40% by weight to 95% by weight of diatomite fossilized with latex as a coating film forming component, SiO ₂ 80-90% by weight, AL ₂ O ₃ 8 A diatomaceous earth-based indoor coating material comprising 1 to 10% by weight of quartz schist powder obtained by pulverizing quartz schist having a composition comprising ˜9 wt% and Fe ₂ O ₃ 0.7 to 0.8 wt%.

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