KR20060072179A - Composition of construction material for radiating an ultrared line and ion, their process and their material - Google Patents

Abstract

The present invention is a phosphate monazite mineral powder consisting of (Ce, La, Y, Th) PO ₄ excellent in the generation of negative ions and far-infrared radiation efficiency of brick, gypsum board, wood, building materials used in building construction such as houses and apartments In the construction of the composition for the construction of far-infrared radiation and anion, which is sprayed or directly coated on the surface, or sprayed or directly coated on the surface of the wall, floor or ceiling while constructing walls, floors or ceilings of houses and apartments, and methods of constructing the same It is about.

Anion, Far Infrared, Radiation Efficiency, Phosphate Monazite Mineral Powder, Building Finish Composition, Construction Method

Description

Composition of construction material for radiating an ultrared line and ion, their process and their material}

The present invention relates to a building material composition for far-infrared radiation and anion generation, and a construction method thereof, and more particularly, to a phosphate monazite mineral powder composed of (Ce, La, Y, Th) PO ₄ having excellent anion generation and far-infrared radiation efficiency. Spray sprayed or directly coated on the surfaces of bricks, gypsum board, wood and building materials used in construction applications such as houses and apartments, or the walls, floors or ceilings of walls The present invention relates to a building finishing material composition for far-infrared radiation and anion generation, which is spray-sprayed or directly coated on, and a construction method thereof.

Negative ions are negative ions in the air. When pure air is in a stable state, the ratio of anions and cations is about 1: 1.2. However, with the development of human civilization, the industrial development is getting farther away from the natural environment. The change to the advanced industrial society is a condition where the ionic composition ratio of the steady state is destroyed by synthetic polymer, cement, electromagnetic wave, environmental pollution, etc., and the cation is predominant. It becomes a large particle mass that has no biological activity. At this time, the number of ions in the large particle mass is remarkably reduced and worsens headache, tension, and the like.

Normally, city dwellers drink about 200 anions / cc (max.) Of negative ions, which is decreasing. Drinking 1000 / cc negative ions increases the activity of α waves in the brain and inhibits serotonin and free histamine, which is beneficial to the health of relaxation. Negative ions promote the functioning of the whole body by keeping the three principles of health maintenance, such as blood purification, cell activation, and nerve regulation in harmony. If you stay in forests, valleys or waterfalls with a lot of negative ions for a long time, you can feel refreshed, refreshed, and feel better. Thus, negative ions are called 'vitamins in the air'.

Anion functions include deodorization, antibacterial, dehumidification, water softening (water), air cleaning, and the like, and materials for releasing anions have been developed to create an anion atmosphere.

Representative materials for generating anions are known materials containing tourmaline and radioactive elements. Tourmaline is spontaneously polarized, and if water is present, it creates a lag and electrolyzes water and generates negative ions in this process. Radioactive elements decay and emit radiation such as α, β, and γ rays, which are the nucleus of helium, β rays are electron beams, and γ rays are electromagnetic waves with very short wavelengths. It is known that anion is released from radioactive elements and contained substances by ionizing gases and solids. It is also reported that more negative ions are generated when a tourmaline that is spontaneously polarized and a material containing radioactive elements are mixed.

Therefore, a number of anion generating materials and applications to which such tourmaline powder or radioactive element-containing materials are added have been filed. Japanese Laid-Open Patent Publication No. 2002-145611 discloses a mineral mixed powder obtained by mixing a tourmaline powder and a powder of a mineral having a radioactive substance emitting weak radiation. Here, as a kind of ore having radioactivity, barite, pyranurite, phosphate minerals of cerium group metals, brown salts and hexondol are presented. Japanese Laid-Open Patent Publication No. 2001-131529 discloses an ion generator in which a material containing a rare earth element and a polar material having spontaneous polarization are present, and garnet is used as the polar material having spontaneous polarization. Japanese Laid-Open Patent Publication No. 2001-19420 discloses a powder in which a powder having spontaneous polarization and a powder of an excitation agent for generating anions are mixed. In Japanese Laid-Open Patent Publication No. 2001-19420, a tourmaline is presented as a spontaneous polarized powder, and a ferroelectric may be used. In addition, as an exciton generating anion, natural ores that emit radiation are proposed. Korean Patent Publication No. 2001-038856 discloses an antifouling paint additive mixed with tourmaline powder. Korean Patent Publication No. 2003-018026 discloses a paint using a natural mineral containing a radioactive element. Here, as a natural mineral, coarse-grained minerals of hornblende and micas having a radioactivity concentration of 370 Bq / g or less were used.

As the above-mentioned anion generating material or material used as spontaneous polarizing material is inorganic, there are disadvantages such as poor moldability and high import of minerals and difficult supply of stable raw materials since most of them are imported from China. do.

The present invention is used by spray-spraying or directly coating the phosphate monazite mineral powder made of (Ce, La, Y, Th) PO ₄ on the surface of brick, gypsum board, wood, construction materials used in building construction such as houses and apartments Or to construct a wall, floor or ceiling of houses and apartments by spraying or directly coating the surface of the wall, floor or ceiling to be used as a building material for eco-friendly bio.

The present invention consists of (Ce, La, Y, Th) PO ₄ and the composition is 4.7% by weight of fluorine (F), 0.62% by weight of MgO, 0.72% by weight of Al ₂ O ₃ , SiO ₂ Content of 5.2% by weight, content of 2.3% by weight of P ₂ O ₅ , content of 4.4% by weight of SO ₃ , content of 1.1% by weight of Cl, content of 0.074% by weight of K ₂ O, content of 1.8% by weight of CaO, content of Kr 0.019 wt%, SrO content 1.2 wt%, BaO content 4.5 wt%, La ₂ O ₃ content 23 wt%, CeO ₂ content 34 wt%, Pr ₆ O ₁₁ content 3.3 wt%, Nd ₂ O ₃ Phosphate monazite mineral powder with a content of 8.1% by weight, 0.76% by weight of Sm ₂ O ₃ , 0.16% by weight of ThO ₂ , and 4.047% by weight of Y ₂ O ₃ , with an average particle diameter of 1 to 100 μm. Construction material for far-infrared radiation and anion generation, characterized in that consisting of parts by weight, 20 to 30 parts by weight of water-soluble adhesives and 40 parts by weight of water. It relates to the sacred.

The present invention is a building finishing material including cement brick, red brick, gypsum board, plastering wall material, the building finishing material is composed of (Ce, La, Y, Th) PO ₄ on the surface and the composition component is pluor (F) Content of 4.7% by weight, content of 0.62% by weight of MgO, content of 0.72% by weight of Al ₂ O ₃ , content of 5.2% by weight of SiO ₂ , content of 2.3% by weight of P ₂ O ₅ , content of 4.4% by weight of SO ₃ , Cl Content of 1.1% by weight, content of K ₂ O 0.074%, content of CaO 1.8%, content of Kr 0.019%, content of SrO 1.2% by weight, content of BaO 4.5% by weight, content of La ₂ O ₃ 23 % By weight, 34% by weight of CeO ₂ , 3.3% by weight of Pr ₆ O ₁₁ , 8.1% by weight of Nd ₂ O ₃ , 0.76% by weight of Sm ₂ O ₃ , 0.16% by weight of ThO ₂ and Y ₂ O ₃ content of 4.047% by weight and a mean particle size of from 1 to 100㎛ phosphate mineral monazite powder, 20 to 30 parts by weight of a water-soluble adhesive 20 within Regarding the building material for far-infrared radiation and anion generation, which is produced by spraying or direct coating the composition of far-infrared radiation and anion generation having 30 parts by weight and 40 parts by weight of water will be.

The present invention is a construction method of building finishing materials including cement brick, red brick, gypsum board, plastering material, the construction method of the building material is made of (Ce, La, Y, Th) PO ₄ on the surface of the building finishing material The composition comprises 4.7% by weight of fluorine (F), 0.62% by weight of MgO, 0.72% by weight of Al ₂ O ₃ , 5.2% by weight of SiO ₂ , 2.3% by weight of P ₂ O ₅ , S0 4.4% by weight of the content of _3, content of 1.1% by weight of Cl, content of 0.074% by weight of K ₂ O, 1.8% by weight, the content of CaO, the content of Kr 0.019% by weight, 1.2% by weight, the content of SrO, the content of BaO 4.5 wt. %, La ₂ O ₃ content 23%, CeO ₂ content 34%, Pr ₆ O ₁₁ content 3.3%, Nd ₂ O ₃ content 8.1%, Sm ₂ O ₃ content 0.76%, Phosphate monazite mineral powder 2 having a content of 0.16% by weight of ThO ₂ and 4.047% by weight of Y ₂ O ₃ with an average particle diameter of 1 to 100 μm. A far-infrared radiation and anion-generating building finish composition composed of 0 to 30 parts by weight, 20 to 30 parts by weight of water-soluble adhesive and 40 parts by weight of water is spray-sprayed or directly coated to a thickness of 1 to 100 μm, and then dried. It relates to the construction of building materials for far-infrared radiation and anion generation.

The phosphate monazite mineral used in the present invention is an anion-releasing substance and is a phosphate mineral of cerium and lanthanum. For example, the content of monazite used in the present invention includes a content of fluorine (F) of 4.7% by weight, a content of MgO of 0.62% by weight, a content of Al ₂ O ₃ of 0.72% by weight, and a content of SiO ₂ of 5.2% by weight. %, P ₂ O ₅ content of 2,3% by weight, S0 ₃ content of 4,4% by weight, Cl content of 1.1% by weight, K ₂ O content of 0.074%, CaO content 1.8% %, Kr content of 0.019% by weight, SrO content of 1.2% by weight, BaO content of 4.5% by weight, La ₂ O ₃ content of 23% by weight, CeO ₂ content 34% by weight, Pr ₆ O ₁₁ The content of was 3.3% by weight, the content of Nd ₂ O ₃ was 8.1% by weight, the content of 0.76% by weight of Sm ₂ O _3, the content of ThO ₂ was 0.16% by weight and 4.047% by weight of Y ₂ O ₃ was used. . The component and content rate of monazite are not necessarily limited to the said component, The numerical value of a content rate may also differ, and monazite itself always produces an anion.

The average particle diameter of the monazite powder which releases an anion is 1-100 micrometers, and 3-10 micrometers is preferable. If the particle diameter of the powder is too large, there is a problem that the adhesion decreases. On the contrary, if the particle diameter of the powder is made too small, it is not preferable because it causes the cost due to powdering. The water-soluble adhesive used in the present invention is preferably 50% starch or wheat flour paste containing 50% by weight of water.

The tourmaline which can be used in addition to the anionic finish of the present invention is also called tourmalline and is a silicate mineral containing boron. The general formula of the composition is represented by XY ₉ B ₃ Si ₆ O ₂₇ (O, OH, F) ₄ (X = Ca, Na, K, Mn, Y = Mg, Fe, Cr, Mn, Ti, Li). Types of tourmaline include dravite goto tourmaline (calculated from metamorphic rock or pegmatite), schori iron tourmaline (calculated from pegmatart), and Elbaite ritaa tourmaline (lean lipite mica). Is calculated from). In addition to the adsorption action of negative (-) electrons by the electrode, the tourmaline has a piezoelectric effect and a pyroelectric effect, as well as an electrolytic action of water and an interfacial effect of water. Tourmaline is discharged in water instantaneously in contact with water. The surrounding water causes electrolysis, so the water molecules are separated into hydrogen ions and hydroxyl ions. Hydrogen ions combine with the surrounding water molecules and change into a surface active material called hydroxyl ions (H ₃ O ₂ ), and a surface active effect occurs by forming a monomolecular film by hydroxyl ions.

The reason for mixing the monazite powder and the tourmaline powder is that the substance which always releases anions mixes both, and the anion release effect is synergistically increased. In addition, the mixing ratio of the powder of the anion-releasing material and the tourmaline powder is also 60 to 40% by weight of the tourmaline powder with respect to 40 to 60% by weight of the powder of the anion-releasing material. good.

The building finishing material of the present invention is used by spray-spraying or directly coating the surface of the brick, gypsum board, wood, building materials used in the building construction such as houses and apartments, or the wall while building the walls, floors or ceilings of houses and apartments It can be spray sprayed or directly coated on the surface of the floor or ceiling.

Finishing material of the present invention can be used to manufacture bricks, gypsum board, wood or building materials in the state of containing a direct finishing material composition in the manufacture of bricks, gypsum board, wood, building materials used in building construction such as houses and apartments It is.

Superconducting polymers that can be used in addition to the anionic finish of the present invention include polyvinylidene fluoride (PYDF), polyviny fluoride (PVF), polyoropylene, polycrylonitrile (PAN), polyacrylamide, polyvinyl chloride (PVC), Nylone-11, P ( VDFf-TFE) [poly (vinylidene fluoride-co-retrafluoro ethylene) and the like can be used, and the pyroelectric inorganic materials include tourmaline, garnet, tartaric acid or ferroelectric. Ferroelectrics include BaTio ₃ , NaKC ₄ H ₄ O ₆ . 4H ₂ O (rosel salt), KH ₂ PO ₄ (potassium dihydrogen phosphate), PbZrO ₃ (zirconate), C (NH ₂ ) 3 Al (SO ₄ ) ₂ .6H ₂ O (GASH), (NH ₂ .CH ₂ COOH) ₃ H ₂ SO ₄ (TGS), lead iron carbonate, NH ₄ H ₂ PO ₄ (ammonium dihydrogen phosphate), SbSI (antimony iodide sulfide), PbTiO ₃ (lead titanate) and the like.

Radioactive elements that can be used in addition to the anionic finish of the present invention are potassium (K), selenium (Se), vanadium (V), rubidium (Rb), indium (In), tellurium (Te), lanthanum (La), Cerium (Ce), Neodymium (Nd), Samarium (Sm), Cadolinium (Gb), Ruthelium (Lu), Hafnium (Hf), Tantalum (Ta), Rhenium (Re), Osmium (Os), Platinum ( Pt), polonium (Po), astatin (At), francium (Fr), radium (Ra), actinium (Ac), thorium (Th), protac (Pa), uranium (U) and the like. Examples of the substance containing radioactive elements include potassium (K) -containing minerals, rare earth element-containing minerals, rare earth element oxides, uranium-containing minerals, and thorium-containing mineral zirconium minerals.

Rare earth-containing minerals that can be used in addition to the anionic finish of the present invention include fluocerite (tysonite), fluorspar (ytttofluorite, yttrocerit), gagarinite, tveitite, ancylite, buban kite, calkinsite, carvocernaite, donnayite, ewaldite, lanthanite, mckelvyite, sahamalite, tengerite, bastnasite, parisite, corisite, cardylite, huanghoite, parisite, synchysite, zhonghuacerite, aeschynite-priorite, betafite, brannerite, cerianite, cerotungsitite, davidite, alanite, phosphorite monazite) and zircon.

Uranium-containing minerals that can be used in addition to the anionic finish of the present invention include uraninite (UO ₂ ), pitchblend (UO ₂ + U ₃ O ₈ ), coffinite, brannerite (UTi ₂ O ₆ ), carnotite (K ₂ (UO) ₂ ) ₂ (VO ₄ ) ₃ , H ₂ O), tyuyamunite, torbernite, autunite. uranophan etc. are mentioned.

Thorium-containing minerals that can be used in addition to the anionic finish of the present invention are monazite (Ce, La, Nd, Th) PO), thorite (ThSiO), thorianite (ThUO) , Branite (U, Ca, Ce) (Ti, FeO), ceriaite, loparite, polymignite, ytrocrasite, zirkelite ( zirkelite, apatite, britholite, grayite, huttonite and the like.

When anion is generated in the anion generating material containing the anionic finish of the present invention, the positive and negative charges appearing when the crystal plate temperature is changed are also called pyro electricity. This property of crystals is also called superelectricity. Crystals are microscopically composed of several types of fine particles with positive and negative charges. Since the crystal is electrically neutral as long as it is not externally charged, the total amount of positive and negative charges in the crystal has the same absolute value. However, the center of gravity of positive and negative charges may not coincide with the case of coincidence depending on the symmetry of the crystal. Inconsistent crystals are called polar crystals, which have electrical polarization in their natural state and are called spontaneous polarization in a broad sense. Since spontaneous polarization is generally temperature dependent, spontaneous polarization changes when the temperature of the polar crystal plate changes, and positive and negative charges corresponding to the change appear on both sides of the plate. Such polar crystals all exhibit pyroelectricity. Representative pyroelectric materials include tourmaline. When tourmaline is heated, tourmaline crystal is polarized to (+) and (-) poles, and when moisture reaches the tourmaline, it discharges momentarily. At this time, water is electrolyzed and water molecules (H ₂ O) are separated into hydrogen ions (H ⁺ ) and hydroxyl ions (OH ⁻ ). The separated hydrogen ions are attracted to the negative electrode and are combined with the electrons emitted therefrom to be neutralized and become hydrogen gas (H ₂ ) to evaporate. That is, water becomes alkaline ionization. In addition, hydroxyl ions (OH ⁻ ) are bonded to surrounding water molecules to form a surfactant (H ₃ O ₂ ) anion. The anion is released by such a process. The anionic finish used in the present invention has a superelectricity, such as tourmaline, so that the anion can be released like tourmaline and used for tourmaline. However, since most of the pyroelectric material alone does not generate anion or is extremely weak even if it is generated, the pyroelectric material alone cannot be used as an anion generating material.

On the other hand, the radioactive element that can be used in addition to the anionic finish of the present invention collapses and emits radiation such as α-ray, β-ray, γ-ray, α-ray is the atomic nucleus of helium, β-ray is a particle beam of electrons, γ-rays are very short-wave electromagnetic waves, all of which act to ionize gases and solids. The emission of radiation from radioactive elements is independent of the chemical form or physical state of the radioactive element. The anionic finish of the present invention contains radioactive elements and the amount of anions generated is related to the total content of radioactive elements.

Except for the concentration of radioactive elements that form a decay series, such as uranium, most of the radioactive element-containing minerals contain trace amounts of radioactive elements that form a decay series or emit weak radioactivity that is harmless to the human body. Although it is considered that it is preferable to use a substance containing a radioactive element that emits radiation below the allowable radiation dose. For this reason, all materials containing radioactive elements can be used in the anion generating material of the present invention, and the amount of anions can be controlled by using radioactive element-containing materials having different kinds or contents of radioactive elements. However, radioactive elements alone do not have enough anions or are not reasonable in terms of price.

As mentioned in the prior art, the generation of negative ions from an anionic material is caused by the formation of a superconducting inorganic material such as tourmaline and a radioactive element-containing material. By promoting the ionization of the anion is easy to release the anion and thus the amount of anion is increased. Since the anionic finish of the present invention is superelectric, when mixed with a radioactive element-containing material, anions are generated.

On the other hand, the control of the amount of negative ions can be made by changing the type of the superconducting polymer and the content of the superconducting inorganic substance added. In consideration of material aspects such as price, raw material supply, and color, it is possible to select a superelectric polymer and a superelectric inorganic material.

By adding the anion generating material according to the present invention, it is possible to manufacture various products such as containers, textiles, paints, ceramics, etc. The anionic finish of the present invention has excellent chemical resistance and good mechanical, thermal, and electrical properties, As it is widely used in various fields such as electronics, pharmaceuticals, food, paper, etc., it is possible to widen the choice in terms of price, raw material supply, and color.

Example 1

On the surface of the brick used in the construction of the apartment, 10 parts of eco-friendly bio finishes composed of 30 parts by weight of phosphate monazite mineral powder consisting of (Ce, La, Y, Th) PO ₄ , 30 parts by weight of water-soluble adhesives and 40 parts by weight of water are used. The interior wall of the apartment was constructed by spray-spraying to a thickness of 탆 and then drying the brick.

Example 2

On the surface of the gypsum board used in the construction of the apartment, 30 parts by weight of phosphate monazite mineral powder consisting of (Ce, La, Y, Th) PO ₄ , 30 parts by weight of water-soluble adhesive, and 40 parts by weight of water are used. The interior wall of the apartment was constructed using a spray board sprayed to a thickness of 10 ㎛ and dried.

Example 3

After constructing the inner wall of the apartment during construction of the apartment, 30 parts by weight of phosphate monazite mineral powder consisting of (Ce, La, Y, Th) PO ₄ , 30 parts by weight of water-soluble adhesive and 40 parts by weight of water Spraying the finishing material for sex bio to a thickness of 10㎛ and dried to construct the inner wall and the wall surface on the inner wall surface.

Example 4

When manufacturing cement bricks used in the construction of apartments, the cement bricks are prepared by containing 1.00 wt% of phosphate monazite mineral powder composed of (Ce, La, Y, Th) PO ₄ based on the total amount of cement bricks. The interior wall of the apartment was constructed using.

Example 5

When manufacturing the gypsum board used in the construction of the apartment, the gypsum board is made by containing 1.00% by weight of phosphate monazite mineral powder composed of (Ce, La, Y, Th) PO ₄ based on the total amount of the gypsum board. Boards were used to construct the interior walls of the apartments.

Example 6

In the construction of the apartment, the masonry wall contains 1.00 wt% of phosphate monazite mineral powder composed of (Ce, La, Y, Th) PO ₄ based on the total amount of the barrier material for plastering the interior wall of the apartment. After the material was manufactured, the interior wall of the apartment was constructed using the barrier material.

Test Example 1 Far-infrared Radiation Efficacy and Anion Generation Experiment

As in Example 1, the result of examining the characteristics of the brick construction building material is as follows. The far-infrared radiation efficacy and negative ion generating effect of the samples are shown in Table 1. This experiment was carried out by FT-IR spectrometer at a temperature of 40 ℃.

Table 1. Far Infrared Radiation Efficacy and Anion Generation Number of the Present Invention

Far Infrared Emissivity Radiant energy Anion generating water Sample of the Invention 1.92 6.70 × 10² 2502 pcs / cm3

Test Example 2: Far-Infrared Radiation Efficacy and Anion Generation Experiment

As in Example 2, the characteristics of the gypsum board constructed with the building finishing material were tested as in Experimental Example 1, and the results are as follows. The far-infrared radiation efficacy and negative ion generating effect of the sample are shown in Table 2.

Table 2. Far Infrared Radiation Efficacy and Anion Generation Number of the Present Invention

Far Infrared Emissivity Radiant energy Anion generating water Sample of the Invention 1.91 6.69 × 10² 2362 pcs / cm3

Test Example 3 Far-infrared Radiation Efficacy and Anion Generation Experiment

As in Example 3, the result of experimenting and examining the characteristics of the inner wall constructed with the building finishing material as in Experimental Example 1 is as follows. The far-infrared radiation efficacy and negative ion generating effect of the sample are shown in Table 3.

Table 3. Far Infrared Radiation Efficacy and Anion Generation Number of the Present Invention

Far Infrared Emissivity Radiant energy Anion generating water Sample of the Invention 1.90 6.68 × 10² 2461 pcs / cm3

Experimental Example 4: Far Infrared Radiation Efficacy and Anion Generation Experiment

As in Example 4, the result of experimenting and examining the characteristics of the brick constructed with the building finishing material as in Experimental Example 1 is as follows. The far-infrared radiation efficacy and negative ion generating effect of the samples are shown in Table 4.

Table 4. Far Infrared Radiation Efficacy and Anion Generation Number of the Present Invention

Far Infrared Emissivity Radiant energy Anion generating water Sample of the Invention 2.89 6.12 × 10² 4017 pcs / cm3

Test Example 5: Far-infrared radiation efficacy and anion generation experiment

As in Example 5, the characteristics of the gypsum board constructed with the building finishing material were tested as in Experimental Example 1, and the results are as follows. The far-infrared radiation efficacy and negative ion generating effect of the samples are shown in Table 5.

Table 5. Far Infrared Radiation Efficacy and Anion Generation Number of the Present Invention

Far Infrared Emissivity Radiant energy Anion generating water Sample of the Invention 2.88 6.78 × 10² 4965 pcs / cm3

Experimental Example 6: Far-Infrared Radiation Efficacy and Anion Generation Experiment

As in Example 6, the result of experimenting and examining the characteristics of the inner wall constructed with the building finishing material as in Experimental Example 1 is as follows. The far-infrared radiation efficacy and negative ion generating effect of the samples are shown in Table 6.

Table 6. Far Infrared Radiation Efficacy and Anion Generation Number of the Present Invention

Far Infrared Emissivity Radiant energy Anion generating water Sample of the Invention 2.87 6.47 × 10² 4877 pcs / cm3

From the above results, the eco-friendly bio finish of the present invention showed far-infrared emissivity and the number of negative ions generated by the human body, which is very beneficial to the physical properties, and has excellent antibacterial function.

The present invention is treated with a phosphate monazite mineral powder composition consisting of (Ce, La, Y, Th) PO _{4 or} the surface of the building finishing material including cement bricks, red bricks, gypsum boards, plastering materials, cement bricks, red bricks, In the manufacture of building finishing materials including gypsum board and plastering wall materials, the building finishing materials containing the phosphate monazite mineral powder composition are used to show far-infrared emissivity and the number of anion generation. The construction can be very useful in the construction industry.

Claims (3)

It consists of (Ce, La, Y, Th) PO ₄ , and its composition is 4.7 wt% of fluorine (F), 0.62 wt% of MgO, 0.72 wt% of Al ₂ O ₃ , and 5.2 of SiO ₂ . % By weight, 2.3% by weight of P ₂ O ₅ , 4.4% by weight of SO ₃ , 1.1% by weight of Cl, 0.074% by weight of K ₂ O, 1.8% by weight of CaO, 0.019% by weight of Kr , 1.2 wt% SrO, 4.5 wt% BaO, 23 wt% La ₂ O ₃ , 34 wt% CeO ₂ , 3.3 wt% Pr ₆ O ₁₁ , 8.1 wt% Nd ₂ O ₃ 20 to 30 parts by weight of phosphate monazite mineral powder having a weight percentage of 0.76 wt% of Sm ₂ O ₃ , 0.16 wt% of ThO ₂ , and 4.047 wt% of Y ₂ O ₃ , with an average particle diameter of 1 to 100 μm, A construction finish composition for far-infrared radiation and anion generation, comprising 20 to 30 parts by weight of a water-soluble adhesive and 40 parts by weight of water. In a building finishing material including cement brick, red brick, gypsum board, and plastering material, the building finishing material is composed of (Ce, La, Y, Th) PO _{4 on the surface} , and its composition is contained in a content of fluorine (F) 4.7 Weight%, MgO content 0.62 wt%, Al ₂ O ₃ content 0.72 wt%, SiO ₂ content 5.2 wt%, P ₂ O ₅ content 2.3 wt%, S0 ₃ content 4.4 wt%, Cl content 1.1 Weight%, K ₂ O content 0.074 weight%, CaO content 1.8 weight%, Kr content 0.019 weight%, SrO content 1.2 weight%, BaO content 4.5 weight%, La ₂ O ₃ content 23 weight%, 34% by weight of CeO ₂ , 3.3% by weight of Pr ₆ O ₁₁ , 8.1% by weight of Nd ₂ O ₃ , 0.76% by weight of Sm ₂ O ₃ , 0.16% by weight of ThO ₂ and Y ₂ O ₃ 20 to 30 parts by weight of phosphate monazite mineral powder having a content of 4.047% by weight and an average particle diameter of 1 to 100㎛, and 20 to 30 parts by weight of water-soluble adhesive And a building material for far-infrared radiation and anion generation composed of 40 parts by weight of water, sprayed or directly coated to a thickness of 1 to 100 μm, and then dried to produce a building material for far-infrared radiation and anion generation. In the construction method of construction finishes including cement bricks, red bricks, gypsum boards, plastering materials, the construction method of the construction finishes consists of (Ce, La, Y, Th) PO ₄ on the surface of the construction finishes and the composition 4.7% by weight of this Fluor (F), 0.62% by weight of MgO, 0.72% by weight of Al ₂ O ₃ , 5.2% by weight of SiO ₂ , 2.3% by weight of P ₂ O ₅ , and S0 ₃ . 4.4 wt%, 1.1 wt% Cl, 0.074 wt% K ₂ O, 1.8 wt% CaO, 0.019 wt% Kr, 1.2 wt% SrO, 4.5 wt% BaO, La 23% by weight of ₂ O ₃ , 34% by weight of CeO ₂ , 3.3% by weight of Pr ₆ O ₁₁ , 8.1% by weight of Nd ₂ O ₃ , 0.76% by weight of Sm ₂ O ₃ , of ThO ₂ content of 0.16 wt% and Y ₂ O ₃ content of 4.047% by weight and the average particle size of 1 to 100㎛ phosphate mineral monazite powder 20-30 Far-infrared radiation and anion characterized in that the construction of the far-infrared radiation and anion generating composition composition consisting of 20 parts by weight to 30 parts by weight and 40 parts by weight of water is sprayed or directly coated to a thickness of 1 to 100㎛ Construction method of building finishing materials for generation.