KR20040038610A - Cement sand of infrared radiation and anion occurrence - Google Patents

Abstract

PURPOSE: Cement additives comprising lepidolite and muscovite are provided to emit far infrared rays and anions, remove bad smell and harmful materials, and prevent bacteria from growing. CONSTITUTION: The cement additives, mixed with cement for the production of concrete or mortar, comprise 45-55wt.% of lepidolite and 45-55wt.% of muscovite, wherein lepidolite and muscovite emitting more than 80-93% of far infrared rays at room temperature, are ground to a size of 20-30mesh and thermal treated at 850-950deg.C for increase of strength.

Description

Cement sand of infrared radiation and anion occurrence

The present invention relates to a cement additive used to prepare concrete or mortar by mixing with cement instead of general sand. In particular, the present invention relates to far-infrared rays, which are made of red mica and white mica having excellent far-infrared radiation and anion generating effects. It relates to spinning and anion releasing cement additives.

In recent years, a large number of buildings are using concrete as a structural material and mortar as a finishing material. Concrete used as a structural material of a building is usually formed by mixing sand, gravel and cement evenly and mixed with water, and mortar used as a finishing material of a building is usually formed by mixing sand and cement evenly and mixed with water.

If there is not enough drying in the process of constructing a building using concrete or mortar, bad odor may be generated from cement or harmful emissions (such as radon gas) will be emitted. Even if it is made, the smell of cement can cause fatal harm to the human body, and if the concrete or mortar is not dried enough or the surroundings are moist, various bacteria or molds can grow.

Therefore, in recent years, in order to minimize the damage caused by the cement as described above and to express the beneficial properties to the human body, a mixture containing functional materials such as ocher, elvan, bioceramic, etc. is added to the cement to build the building.

However, the method of constructing a building by mixing a mixture containing functional materials such as ocher, elvan, bioceramic and the like with cement is not economical because it is expensive and expensive, and is not economical. There is also a problem that the solving effect of all problems is not satisfactory. In addition, ocher, elvan, bioceramic and the like do not appear in addition to the far-infrared radiation effect, the actual situation is not applied very much.

The present invention has been made to solve the conventional problems as described above, has a far-infrared radiation function and anion generating function, can easily remove the odor generated from cement, as well as harmful components contained in cement The purpose of the present invention is to provide far-infrared radiation and anion-releasing cement additives, which are excellent in the removal effect, prevent the infestation of various bacteria and fungi, and prevent the access of harmful insects and pests.

In addition, an object of the present invention is to provide far-infrared radiation and anion-emitting cement additive that can improve the durability of the building by excellent electrical insulation, heat resistance, chemical resistance and water resistance.

In order to achieve the above object, the far-infrared radiation and anion-releasing cement additive according to the present invention comprises 45 to 55% by weight of red mica powder and 45 to 55% by weight of mica powder.

In this configuration, the red mica powder and the white mica powder are preferably powdered to 20 to 30 mesh, and further preferably heat-treated to 850 to 950 ° C after being powdered.

Hereinafter, the configuration of the far-infrared radiation and anion-emitting cement additive according to the present invention will be described in more detail.

Far-infrared radiation and anion-releasing cement additive according to the present invention is composed of 45 to 55% by weight of mica powder, and 45 to 55% by weight of mica powder. At this time, the composition ratio of the preferred mica powder and dolomite powder is 50% by weight and 50% by weight.

The aforementioned mica and white mica are powdered into 20-30 mesh to be uniformly mixed with cement prior to mixing with each other. At this time, when the mica and dolomite are powdered to 30 mesh or more, when the mortar is manufactured and used as a finishing material, the finishing surface may be formed more smoothly. However, evenly mixing the raw materials is extremely difficult, and after the construction, far infrared radiation and anion emission efficiency decrease. When powdered to 20 mesh or less, the finish surface becomes rough and the adsorption power in the compounding material is low, so it is easy to cause cracking after mortar construction.

The powdered red mica and white mica are heat treated within the range of 850 ~ 950 ℃ to increase the strength. At this time, when the heating temperature is 850 ° C. or lower, the mica and the white mica cannot obtain the appropriate strengths, and when the heating temperature is 950 ° C. or higher, the mica and the white mica may be lost.

As described above, when the mortar is prepared by mixing the cement additive according to the present invention, which is a mixture of powdered and heat-treated red mica powder and white mica powder with cement, the ratio of the cement additive 30% by weight and the cement 70% by weight It is preferable to mix with. At this time, if the cement additive is mixed at more than 30% by weight, the cracking and shrinkage of the formed film due to shrinkage during curing of the mortar are weakened. If the cement additive is mixed at less than 30% by weight, the effect of far-infrared radiation and anion is released. Is reduced.

On the other hand, the above-mentioned mica and dolomite are both mineral raw materials of silicic acid-alumina-based mineral and belong to the monoclinic system in which the flakes are peeled off one by one, and have the following characteristics.

First, red mica and dolomite have a three-layered mineralogical structure, and when sprayed on contaminated water, the spacing between layers is extended and negatively charged, so cations like heavy metals in the water The fine particles having neutralization are neutralized to coagulate and precipitate, and impurities and the like are adsorbed and removed. Therefore, when mixing the mica and dolomite having such characteristics with the cement it is possible to purify the heavy metals or foreign substances contained in the cement.

Second, red mica and dolomite mica decomposes and deodorizes NH ₃ , SO ₂ , CO, H ₂ S and Cl ₂ , which are harmful gases. Therefore, when the structure is built after mixing the mica and dolomite with cement, it is possible to significantly reduce the amount of harmful gas emitted from the cement.

Third, because the mica and dolomite radiate far infrared rays at 80-93% or more at room temperature, when the far-infrared rays emitted from the mica and dolomite are absorbed by the human body, metabolism is smoothed, blood circulation is activated, body heat is increased, and cell activity is active. Done. Therefore, the construction of the building after mixing the mica and dolomite with cement has a significant effect in preventing and healing various adult diseases caused by blood circulation disorders such as hypertension, chronic fatigue, stress. In addition, since far infrared rays have a bactericidal effect, various bacteria and molds can be prevented from propagating in buildings, and harmful insects and insects can be prevented from approaching.

Fourth, since red mica and dolomite have excellent electrical insulation, heat resistance, chemical resistance and water resistance, when building a structure by mixing red mica and dolomite with cement, it is possible to prevent fire due to short-circuit and moisture caused by rainfall or snowfall. Penetration can be prevented, resulting in increased durability of the building.

Hereinafter, a specific embodiment of the present invention will be described. The following examples illustrate the invention in more detail, but do not limit the scope of the invention.

(Example)

Far infrared ray radiation and anion generating cement additive according to the present invention was prepared by uniformly mixing 50% by weight of mica and 50% by weight of powdered 25mesh and heated to 900 ° C. In the process of preparing a mortar for finishing the building by mixing the cement additive thus prepared with cement, the cement additive and the cement were uniformly mixed with 30 wt% and 70 wt%, respectively.

As a result of comparing a building finished with a mortar prepared as described above and a building finished with a conventional mortar, a finishing layer formed by a mortar prepared by adding a cement additive according to the present invention (hereinafter referred to as A) It was found that there is a remarkable difference from the finishing layer (hereinafter referred to as B) formed by the ordinary mortar.

That is, as a result of analyzing the components through sampling of A and B, the amount of heavy metals and foreign substances contained in A was significantly smaller than that of B, and the amount of harmful gases emitted was significantly smaller than that of A. On the other hand, the amount of far-infrared radiation and anion released in the human body is much higher than that of B. As a result of observing the surface of A and B, it was found that a lot of bacteria or fungi multiply on the surface of B, whereas in the case of A, bacteria or fungi rarely reproduce. In addition, in the case of B, various pests or insects approached a lot, but in the case of A, there were hardly any pests or insects approaching. In addition, A was superior to B in the electrical insulation, heat resistance, chemical resistance and water resistance experiments.

When the present invention constructed as described above by constructing concrete or mortar by mixing the far-infrared radiation and anion-releasing cement additives with cement, the following effects can be obtained.

First, due to the structural characteristics of the mica and dolomite mica to clean the heavy metals or foreign substances contained in the cement, it is possible to prevent various damages caused by heavy metals and foreign substances.

Second, by wet-decomposing and deodorizing the harmful gas discharged from the cement and the red mica and dolomite, it is possible to significantly reduce the amount of harmful gas emitted from the cement to reduce various harmful effects on the human body due to the harmful gas.

Third, because the mica and dolomite radiate far infrared rays at 80-93% or more at room temperature, the metabolism of the human body is smooth, the blood circulation is activated, the body heat is increased, and the cell activity is vigorous, resulting in high blood pressure, chronic fatigue, stress, etc. It can prevent and cure various adult diseases caused by blood circulation disorder. In addition, since the far infrared rays sterilize, various bacteria and fungi can be prevented from propagating on walls, floors, and ceilings, and pests, insects, and the like can also be prevented.

Fourth, due to the excellent electrical insulation, heat resistance, chemical resistance, and water resistance, both mica and dolomite have no fear of fire due to short-circuit, and there is no fear of moisture penetrating due to rainfall or snowfall. There is an advantage.

Claims (3)

Far-infrared radiation and anion-releasing cement additive, characterized in that composed of 45 to 55% by weight of red mica powder, and 45 to 55% by weight of mica powder. The method of claim 1, The mica powder and dolomite powder are far-infrared radiation and anion-emitting cement additive, characterized in that powdered to 20 ~ 30mesh. The method according to claim 1 or 2, The red mica powder and dolomite powder are far-infrared radiation and anion-emitting cement additive, characterized in that the heat treatment at 850 ~ 950 ℃.