KR100686592B1 - Manufacturing method of ceramic accessaries having infrared and anion emissive property - Google Patents

Abstract

The present invention provides a method for producing a ceramic product having both far-infrared and anion emission properties, comprising: a first raw material mixing step of mixing tourmaline, an organic binder and an inorganic binder; A first molding step of heat-treating the first raw material mixture and forming a spherical shape at a pressure of 10-100 kg / cm ² ; A second raw material mixing step of preparing a slurry by mixing PO to control moldability and sinterability with CeO ₂ (ceria); A secondary molding step of coating the second raw material mixture slurry on the calcined material as a result of the primary molding; And heat-treating the secondary molding result at 1000 to 1200 ° C. for 1 to 10 hours.

Therefore, a large amount of far-infrared rays and anions are simultaneously radiated to high levels, have antimicrobial activity, are harmless to the human body, and can produce functional ceramic products that can be applied in various areas. Functional ceramic products prepared by the present invention is harmless to the human body can be applied to the additives of interior paints, cooking industry, deodorant antibacterial products, etc., and can be used continuously by reheating after use.

Far Infrared, Anion, Ceramic.

Description

MANUFACTURING METHOD OF CERAMIC ACCESSARIES HAVING INFRARED AND ANION EMISSIVE PROPERTY}

1 is a manufacturing process diagram of a ceramic product having both far infrared and anion radiation characteristics according to the present invention,

2 is a cross-sectional view of the ceramic product of the present invention according to the molding process of the manufacturing process of FIG.

The present invention relates to a method for producing ceramics that emit far infrared rays or anions.

Far-infrared refers to a long wavelength among infrared rays. It is invisible, absorbed well by materials, and has strong resonance and resonance effects on organic compound molecules. In addition, light generally reflects well when the wavelength is short and absorbs well when it reaches the object because the wavelength is long. For example, you can hardly feel the warm energy in the water at 30 ℃, but sitting in the sun at the same temperature can feel warm because the infrared rays contained in the sun penetrates deep into the skin to create heat.

This heat action helps to eliminate the bacteria that cause various diseases, and helps to expand the capillaries and blood circulation and tissue formation. In addition, by touching the water and protein molecules that make up the cells, the cells are shaken finely 2,000 times per minute to activate cell tissue, which is effective in preventing various adult diseases such as aging, promoting metabolism, and chronic fatigue. In addition, it promotes sweating, pain relief, heavy metal removal, sleep, deodorization, antibacterial, mold propagation prevention, dehumidification, and air purification, so it is effective in housing and building materials, kitchen utensils, textiles, clothing, bedding, medical equipment, jjimjilbang. It is used in many fields.

Anions are one of the atoms with electronic components. Known on the market as "vitamin in the air," it is a charge-bearing atom in outer space or on earth, or ultrafine particles with negative charge floating in the air. These ions have a great impact on the existence of matter or life. Negative ions neutralize or purify the toxicity of contaminated cations in the air. There are several kinds of anion air ions, such as free electrons, atoms, light ions, heavy ions, large ions, and small ions, among which are charged with negative ions. It is known as anionic air ion. However, I didn't know in detail what kind of substance it actually consisted of, and only recently did research on anion air ions proceed to clinical experiment in medical field, and it is common sense that anion air ion has a good effect on human body. )

 The anion absorbed in the body acts on the cell membrane and activates the cell by helping the cell's ion exchange. When metabolism becomes active by cell activation, blood remains purified. It has also been confirmed that anions act directly, such as by inhibiting serum cholesterol, which causes adult diseases such as arteriosclerosis. It also has the effect of enhancing the immune system by activating the production of substances that surround and sterilize bacteria in the blood. In addition, when negative ions are absorbed into the body, the body fluid becomes weakly alkaline, and the metabolism of the whole body of the body becomes active. As a result, the body recovers fatigue by completely burning the accumulated fatigue substance. It acts on the negative autonomic nerves to stabilize its activity, stabilize the mind, increase immunity, relieve pain and improve allergic constitution.

However, generally used ceramics that emit far infrared rays or anions emit only one characteristic of emitting far infrared rays or anions, and the products manufactured therefrom have been generated by only one characteristic.

In addition, the material of the conventional far-infrared and anion radiation products is generally manufactured by performing only physical treatment of the raw materials generated in nature without chemical pretreatment, there is a problem that the characteristics possessed by itself are not sufficiently expressed.

Therefore, there has been a need to develop ceramic products having the characteristics of far-infrared and anion radiation evenly.

In order to solve the above problems, the present invention simultaneously provides complementary characteristics of far-infrared radiation and anion radiation by appropriate mixing of raw materials, manufactures a multifunctional ceramic raw material including antibacterial activity by the addition of silver, and uses a product using the same. It aims to develop.

In addition, the raw material having the characteristics of far-infrared radiation and anion radiation produced in nature is formed by using an inorganic or organic binder and heat-treated at a high temperature to simultaneously express the characteristics possessed by itself to a high level.

In addition, the ceramic manufacturing process of the present invention in particular to form a glaze layer in the final step to be able to express a variety of colors and textures when used as ornaments, while foreseeing skin troubles when in contact with the human body, while the characteristics of far infrared radiation and anion radiation It is an object to enable the expression of the properties at a high level.

The present invention provides a method for producing ceramic ornaments having both far-infrared and anion emission characteristics, comprising: a first raw material mixing step of mixing tourmaline, an organic binder and an inorganic binder; A first molding step of heat-treating the first raw material mixture and molding the sphere at a pressure of 10-100 kg / cm ² ; A second raw material mixing step of preparing a slurry by mixing PO to control moldability and sinterability with CeO ₂ (ceria); A second molding step of coating the second raw material mixture slurry on the material calcined as a result of the first molding; heat treating the second molding result at 1000 to 1200 ° C. for 1 to 10 hours; and varying colors and textures. Forming a glaze layer on the final surface of the ceramic product produced by the process so as to represent.

In general, the far-infrared and anion-emitting ceramic products manufactured are molded and then fired and then subjected to a second process after firing. However, in the present invention, in order to provide plasticity of the raw material in the first step, spherical ceramic particles are prepared by adding an organic binder and an inorganic binder according to the characteristics of the product. Through the process of molding at high pressure, the two baking processes were shortened to one baking. The bonding layer formed in the intermediate layer used a reaction in which the unreacted material was partially eluted by the density difference during the heat treatment of the primary raw material.

Therefore, it shows the effect of far infrared rays at room temperature, but when it contains water or oil, it shows antibacterial and deodorization characteristics by radiation of anion.

Meanwhile, the present invention used tourmaline with high far-infrared radiation and cerium-based oxide with high anion radiation as main raw materials, and additionally, elvan, noble, jade and loess were used as additives and clay was used as an inorganic additive. And in order to improve moldability, it was molded in the form of uniform spherical particles using an organic binder.

In addition, the raw materials of the ceramic ornaments are mixed in a composition ratio of 20 to 80% by weight of tourmaline, 10 to 50% by weight of CeO ₂ and 20 to 40% by weight of an organic binder and an inorganic binder additive.

Hereinafter, with reference to Figure 1 will be described step by step the manufacturing process of the present invention.

1. First Mixing Process

In order to provide plasticity of the tourmaline raw material, an organic binder and an inorganic binder are added and mixed. In other words, the process of optimizing far-infrared radiation using tourmaline that emits far-infrared rays is insufficient for molding and plasticity with tourmaline alone. Add and mix.

2. Heat treatment

The raw materials mixed in the first mixing process are generally heat treated at 1000 to 1200 ° C. for 1 to 10 hours. At this time, the unreacted material is partially eluted by the density difference to form a bonding layer.

3. Primary molding

Far infrared rays have high transmittance compared to other wavelengths, so even if they are located inside the finished product, they are radiated at a temperature similar to the human body (30 ° C). Therefore, it can be processed by molding into spherical or various shapes. Primary molding is performed in a spherical shape using the raw materials mixed in the first mixing step. At this time, in order to coat the slurry of the second raw material mixture on the outside of the primary molding result, the pressure is molded at a pressure of 10 to 100 kg / cm ² so as to suppress expansion upon absorption of moisture and undergoes one calcination. .

4. Second raw material mixing process

Only CeO ₂ (Ceria) and CeO ₂ (Ceria) prepare a slurry in which P component is added and mixed in order to control weak moldability and sinterability.

5. Secondary molding

The slurry of CeO ₂ and P component, which is the result of the second mixing process, is coated on the material calcined as a result of the primary molding, and in this case, the coating process is not affected by the pressure. Thus, the final ceramic product is coated with a slurry mixture in which tourmaline, which emits far infrared rays in a spherical shape, emits anions, as shown in FIG.

6. Heat treatment

After completion of the secondary molding, heat treatment is carried out. The heat treatment temperature has a different effect depending on the type and amount of additives added during the mixing of the first raw material and the second raw material. The time is about 1 to 10 hours.

7. Glaze layer formation

By forming a glaze layer on the final surface of the ceramic manufactured in the above process, it is possible to express a variety of colors and textures in the manufacturing of accessories and ornaments, etc. and can be applied to various products. The glaze layer does not have a great influence on negative ions and far-infrared radiation, and also has a function of suppressing allergy generated in contact with the human body.

Hereinafter, the far-infrared and anion radiation effects and the detection of harmful substances of the present invention were tested through the examples.

Table 1 measured far-infrared and anion emission by varying the composition ratio of the raw materials used. This experiment was carried out in various composition ranges using tourmaline, cerium-based oxide, elvan, loess, jade, and precious stone. In general, tourmaline is widely used in products such as bras and panties used at room temperature due to its excellent far-infrared effect. The raw materials were first calcined by combining the expensive jade and the like at a constant ratio, thereby partially preparing the raw materials and completely sintering them at the temperature at which they were finally synthesized.

Far-infrared and anion emission measurement results according to the composition mixing ratio of the product Example Tourmaline (wt%) Cerium system (wt%) Ocher (wt%) Elvanite (wt%) Jade (wt%) Molding density (%) Emissivity (5 ~ 20㎛) Anion Radiation (pcs / cc) No.1 100 - - - 95 0.96 682 No.2 - 100 - - - 95 0.923 9300 No.3 60 40 - - - 95 0.923 8500 No.4 60 30 5 5 - 94 0.915 6590 No.5 60 30 - 5 5 91 0.863 5600 No.6 60 30 5 - 5 91 0.893 530 No.7 50 30 10 10 - 95 0.832 5200 No.8 50 30 5 5 10 83 0.898 4400 No.9 50 20 10 15 5 94 0.812 3600 No.10 50 30 10 5 15 96 0.835 4130

Table 2 shows the results of the hazardous substance dissolution test on the ceramic products produced by these manufacturing processes. If harmful substances are eluted from these substances, they cannot be used for cooking utensils, sanitary containers, and products that come in direct contact with the human body. there was.

Hazardous substance dissolution test results of manufactured ceramic products Pb CD Cr As Hg No.1 - - - - - No.2 - - - - - No.3 - - - - - No.4 - - - - - No.5 2 - - - - No.6 - - - - - No.7 - - - - - No.8 One - _ - -

(Unit: ppm)

Commonly used far-infrared and anion-radiation ceramics are the manufacture of products using optimal far-infrared and anion radiation using specific materials, but the present invention allows these materials to have optimal properties by the appropriate formulation and also to the added process. There is an advantage that these properties are expressed at the same time.

Using a tourmaline material with high emissivity as far-infrared material, and using ceria (CeO ₂ ) as an anion material, a special process is used to maintain the high characteristics. Especially, in order to use these materials as accessories and jewelry, In this case, there was a problem in that the color is restricted, but in the present invention, the glaze layer is formed on the final surface to express various colors and textures.

 In addition, the glaze layer also has the effect of suppressing allergy generated in the process of contact with the human body without significantly affecting the anion and far-infrared radiation.

In the above description of the preferred embodiment of the present invention, those skilled in the art may make various modifications without departing from the gist of the present invention, and such modifications belong to the protection scope of the present invention. The protection scope of the invention should be construed as described in the claims.

Claims (2)

A first raw material mixing step of mixing tourmaline, an organic binder and an inorganic binder; A first molding step of heat-treating the first raw material mixture and molding at a pressure of 10 to 100 kg / cm ² ; A second raw material mixing step of preparing a slurry by mixing PO to control moldability and sinterability with CeO ₂ (ceria); A secondary molding step of coating the slurry of the second raw material mixture on a material calcined as a result of the primary molding; Heat treating the secondary molded product at 1000 to 1200 ° C. for 1 to 10 hours; and forming a glaze layer on the final surface of the ceramic product manufactured by the process to express various colors and textures. Method for producing far-infrared and anion-emitting ceramic ornaments, characterized in that. The method of claim 1, The raw material is mixed with 20 to 80% by weight of tourmaline, 10 to 50% by weight of CeO ₂ and 20 to 40% by weight of an organic binder and an inorganic binder additive. .

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