KR0146451B1 - Method for stonepowder of farinfrared radiator - Google Patents

Abstract

After attaching silver foil to the inner surface of feldspar (4) and grinding 60% by weight of germanium stone, 10% by weight of zeolite, 10% by weight of jade, 10% by weight of fluorite and 10% by weight of mineral stone to about 325 mesh, Charged and charged with 325 mesh crushed ganbanite between the inner surface of the heat transfer plate (2) and the inner furnace (4), and then heated through the heat transfer plate (2) at about 1000 ° C for 9 days, and in the furnace (4) A multipurpose stone powder which emits far-infrared rays and anions obtained by grinding the above five kinds of thermally denatured stone powder to about 500 mesh or more, and a method of manufacturing the same.

Description

Multipurpose stone powder which emits far infrared rays and anions and its manufacturing method

1 is a schematic view showing a furnace for producing a multipurpose stone powder of the present invention,

2 is a block diagram showing the manufacturing process of the multipurpose stone powder of the present invention.

* Explanation of symbols for main parts of the drawings

2: heating plate 4: inside

5: inner wall

The present invention relates to a multipurpose stone powder which emits large amounts of far infrared rays and anions, and a method for producing the same.

In general, infrared rays are a kind of electromagnetic waves, and infrared rays in the range of 0.76 to 1000 microns, and wavelengths of 0.76 to 1.5 microns are referred to as near infrared, 1.5 to 5.6 microns as mid-infrared, and 5.6 to 1000 microns as far infrared (Far Infrared). Business, Sunmak Publishing, Dec. 25, 1988).

Far-infrared rays have a wide variety of uses, such as heating, drying, maturing, nurturing, and analgesic effects. Also, when applied to the human body, there are sweating and analgesic effects that secrete a large amount of sweat. Known. In addition, there have been many attempts to use far-infrared rays in the health industry or the food industry preferably after clinical trials showing effects on the human body's biological rhythms. ). Therefore, these days, the products using far-infrared rays are sold in large quantities. For example, the far-infrared sauna bath can enhance the human sweating at a lower temperature than the steam sauna bath. In other words, the steam sauna bath supplies hot steam (about 70 to 80 ° C.) to the sauna room, so that a person cannot endure long in the bath. However, the far-infrared sauna room has a higher perspiration than the steam sauna bath even when the internal temperature is maintained at about 40 ° C. This is to use the phenomenon that far infrared rays are absorbed by the human body to cause self-heating by the resonance action of water molecules in the human body.

It is well known that negative ions are opposite to positive ions, and in relation to the human body, the movement of negative ions in cells is based on a joint research published by Bert Sakmann and E. Necher, which won the 1991 Nobel Prize in Physiology and Medicine. Through the disease structure can be identified. In other words, when the neutral human body is externally or internally influenced and has a large amount of positive ions, interest in negative ions is increasing in the intention to supplement negative ions using food or peripheral devices to correct them. .

Appropriately adding negative ions to the body with a large amount of cations is known to have autonomic neuropathy, blood purification, cell reactivation and cell resistance.

The various ions in the air change according to the weather conditions, and when the low pressure such as discontinuous line or cold wire passes, the cation increases and the anion decreases in the human body under the influence of this. It is known that the incidence of diseases such as neuralgia, asthma and stroke increases.

Conventionally, a material that emits far infrared rays using a material called a brand name bio ceramic has been commercially available. It maximizes the effect of certain functions, for example, antibacterial, anti-coloring, deodorization, by mixing or adding chemicals with a specific function to the ceramic material is supplied in powder, particle form, liquid form.

However, the conventional far-infrared anti-fogging materials have the disadvantage of emitting only far-infrared rays or having a low amount of far-infrared radiation. In addition, because various chemicals are mixed, there was a problem that is difficult to utilize in health foods to avoid chemicals.

Accordingly, an object of the present invention is to provide a multi-purpose stone powder and a method for producing the same, which are made of only natural ores excluding any chemicals, and emit a large amount of far infrared rays and anions.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

Referring to FIG. 1, a furnace 1 for producing a multipurpose stone powder according to the present invention includes a heat transfer plate 2, an inner furnace 4, and an inner wall 5 coated with silver (Ag) on an inner surface thereof. have.

The heat transfer plate 2 may be heated by electricity or by gas or other fuel.

The inner furnace 4 is a feldspar furnace, in which about 325 meshes of 60% by weight of germanium stone, 10% by weight of zeolite, 10% by weight of jade, 10% by weight of fluorite and 10% by weight of mineral stone are prepared using a conventional grinder. Pulverize to charge.

Between the inner surface of the heat transfer plate (2) and the outer surface of the inner furnace (4) charges the ganban stone pulverized with about 325 mesh and then heated for about 9 days through the heat transfer plate (2). Then, the elvan starts to burn at an initial temperature of 1000 ° C, and the temperature rises to about 3000 ° C due to self-heating of heat (ore heat) during the combustion process. The above five kinds of ore powder in the inner furnace 4 are thermally denatured due to high heat, and heavy metals harmful to the human body are burned away. As shown in Table 1, it is found in ordinary ores mainly based on 20 kinds of natural minerals. It becomes a lump containing 36 different minerals. Slow cooling after elvan burns.

As shown in FIG. 2, the mass is crushed again to about 500 mesh or more.

The ore powder of Table 1 according to the present invention emits far infrared rays and anions which are very beneficial to the human body.

The multi-purpose stone powder according to the embodiment of the present invention has a far-infrared emissivity of more than 99.0% having a wavelength of 8 to 14 microns at 37 ° C., and releases more than 600,000 anions per kilogram of stone powder, and an oxygen calorific value is 560 kcal. In this case, KS.A 5302-91 for far-infrared ray, anion was measured with MDK-O1C anion measuring device model of Schomandl, Germany, and the calorific value of oxygen was measured with KS.E 3707-90.

The pH of the stone powder is 7.4 ~ 7.9.

Multipurpose stone powder according to the present invention is a very useful invention that can be applied to food, textiles, cosmetics, paints and the like as a large amount of far-infrared and anion generated stone powder.

Claims (2)

(4) Attach silver (Ag) paper to the inside of feldspar and grind 60% by weight of germanium stone, 10% by weight zeolite, 10% by weight jade, 10% by weight fluorite and 10% by weight mineral stone to 325 mesh Then, charged and charged with 325 mesh crushed gangue stone between the inner surface of the heat transfer plate (2) and the inner furnace (4), and then heated to 1000 ° C through the heat transfer plate (2) for 9 days, into the inside (4) Method for producing a multi-purpose stone powder that emits far-infrared rays and anions pulverized by the above five kinds of stone powders at 500 mesh or more. 60% by weight of germanium stone, 10% by weight zeolite, 10% by weight jade, 10% by weight fluorite and 10% by weight of mineral stone were pulverized and mixed with 325 mesh and heated at 1000 ° C. for 9 days through gannetite pulverized with 325 mesh. After that, it is a versatile stone powder that emits far infrared rays and anions pulverized to 500 mesh or more.