KR100352041B1 - Earthenware Pot for Storage of Water Containing Germanium - Google Patents

Abstract

The present invention relates to a water poison containing germanium, and ground the germanium ore containing 0.36 to 1.05% germanium and 10 to 15% alumina into 800 to 1000 mesh and 70 to 85% by weight of the pulverized germanium powder, Blending 5 to 15% by weight of kaolin and 10 to 25% by weight of clay and classifying using a sieve, followed by filter pressing and blending to prepare a raw material powder; Aging the raw material powder and then molding by mixing 70 to 80% by weight of the raw material powder and 20 to 30% by weight of water; Naturally drying the molded poison at room temperature and atmospheric pressure in air; Baking the molded poison at 700 to 800 ° C .; And glazing the germanium ore into 300 to 400 mesh in a poison prepared by applying glaze to the first roasted poison and baking at a temperature of 1050 to 1100 ° C., and then forming a ball shape having a radius of 10 to 30 mm to 1050. It is characterized in that it comprises 0.4-0.6 kg of germanium balls produced by primary firing at -1100 ° C and secondary firing at 600-800 ° C. The living poison of the present invention can provide fresh and beneficial water to the human body by forming a hexagonal structure of water having excellent far-infrared emission effect and storing.

Description

Germanium-containing water poison {Earthenware Pot for Storage of Water Containing Germanium}

The present invention relates to living water poison. More specifically, the present invention relates to a water poison prepared by using germanium ore as a main raw material and kaolin, clay, and the like as an auxiliary raw material.

Since the human body is made up of more than 80% of water, the state of health is greatly affected by the water ingested by the human body. In recent years, as the speed of industrial development increases rapidly, industrial wastewater generated from various plant facilities, etc., is introduced into a drinking water source, thereby degrading water quality. Generally, tap water supplied to each household is withdrawn from the water system of each stream through the intake station, and the contaminated water from the water treatment plant is supplied through the water pipe through filtration and water purification process, but as a result of using a large amount of disinfectant in the water purification process If you do not handle without the problem of odor occurs. Accordingly, the tendency to make drinking water or purified water edible is common. However, commercially available bottled water can be prevented from being contaminated by microorganisms in a bottled water bottle | sealed state. However, when the container is opened at home and stored and eaten for a certain period of time, the freshness is deteriorated to cause odor. And there is a problem that the sound is also reduced.

On the other hand, it is widely known that food and drinking water has a great effect on the human body depending on the container for storing water. In this regard, when food is stored in a container in which far-infrared rays are radiated, it is possible to obtain an effect of maintaining its freshness by providing the object with a wavelength beneficial to the human body. Far infrared rays are absorbed rays of organic compounds having a wavelength band of 6 to 14 μm and are highly efficient heat rays. Since they have self-heating properties, they have an effect of promoting metabolism when radiated to the human body. On the other hand, it is known that water can exist in various structures in a natural state. Among them, when water molecules form a hexagonal structure, the most beneficial to the human body and the structure of the water has a hexagonal shape according to the radiation of far infrared rays. Was released. Therefore, studies have been conducted to maintain the freshness of water even after long-term storage by providing a function of emitting far infrared rays to the water storage container. Ocher or elvan are known as far-infrared radiation materials. However, when these materials are used, the effect of blocking electromagnetic waves or water waves that are harmful to the human body is excellent, but the effect of emitting far-infrared rays beneficial to the human body is not satisfactory. Recently, it has been known that germanium has an excellent far-infrared radiation effect, and there has been an attempt to store water for food and beverages using the same. For example, Korean Utility Model Registration No. 1997-1483 houses permanent magnets with magnetic density of several thousand gauss that magnetizes water in storage vessels, which are part of the bottle holder, and coral sand, which has sterilization and mineral generation functions. Although the present invention discloses a bottle holder pedestal equipped with a sterilization and magnetization mineral generating device capable of maintaining good water quality without bacterial propagation even after long-term storage by installing a mineral ceramic filter, the above-described design has an excessively complicated problem. In addition, Korean Utility Model Publication No. 1999-33352 discloses a bottled water bottle that can prevent the deterioration of water by containing germanium in the material of the conventional plastic bottled water in view of the fact that germanium emits far infrared rays, the bottled water The bottle was made of plastic and its appearance was unsuitable for home use, and the amount of far-infrared radiation emitted was insufficient. Similarly, Korean Utility Model Publication No. 1999-38417 forms a portion into which water is introduced into the ocher layer, and the water passed through the ocher layer is stored in a storage tank through a ceramic filter, and various mineral components are formed by elvans located under the storage tank. Although a water purifier to elute is disclosed, it is also difficult to expect a beneficial effect on the human body substantially because of the low infrared emission performance. In particular, in order to absorb energy beneficial to the human body and emit far infrared rays into the water to be stored, the far-infrared radiant minerals and other components should be mixed and formed in an appropriate ratio. Has been going on.

Therefore, the present inventors have conducted extensive research to solve the problems of the prior art, the result is a germanium component excellent in far-infrared emission effect as a main component and the mineral water as a secondary component in the manufacture of ceramics, such as kaolin, clay as a minor component By preparing the poison and injecting germanium balls into the water, the organic germanium component is sufficiently eluted to be contained in the water. Thus, it is possible to develop a water poison that can maintain the freshness of the water for a long time and maximize the far-infrared radiation effect.

Accordingly, it is an object of the present invention to provide a germanium-containing bottled water poison which is excellent in far-infrared radiation effect and can maintain the freshness of water stored for a long time.

In order to achieve the above object, the germanium-containing bottled water of the present invention grinds germanium ore containing 0.36 to 1.05% germanium and 10 to 15% alumina into 800 to 1000 mesh and 70 to 85% by weight of the pulverized germanium powder. Preparing a raw material powder by mixing 5-15% by weight of kaolin and 10-25% by weight of clay and classifying using a sieve, followed by filter pressing and blending; Aging the raw material powder and then molding by mixing 70 to 80% by weight of the raw material powder and 20 to 30% by weight of water; Naturally drying the molded poison at room temperature and atmospheric pressure in air; Baking the molded poison at 700 to 800 ° C .; And glazing the germanium ore into 300 to 400 mesh in a poison prepared by applying glaze to the first roasted poison and baking at a temperature of 1050 to 1100 ° C., and then forming a ball shape having a radius of 10 to 30 mm to 1050. It is characterized in that it comprises 0.4-0.6 kg of germanium balls produced by primary firing at -1100 ° C and secondary firing at 600-800 ° C.

1 is a perspective view schematically showing an embodiment of the living poison of the present invention.

2 is a cross-sectional view illustrating the living poison of the present invention by way of example.

Hereinafter, the present invention will be described in more detail.

Germanium is an off-white mineral, which generally emits far infrared rays, absorbs toxic substances and chemically combines them into other non-toxic substances, and has excellent far-infrared radiation effect, making it a popular food storage container material. .

Germanium ore used in the present invention is a natural germanium ore having a Cu ₃ (GeFe) S ₄ type (germanite type) structure, containing 0.36 to 1.05% germanium and 10 to 15% alumina, Table 1 Contains ingredients such as

ingredient content(%) Cu 0.044 Pb 4.72 Zn 0.42 Fe 25.8 Mn 0.36 Ni 0.56 CD 0.018 Ge 0.36-1.05 Mg 6.6 C 0.6 As 15.4 S 17.6 SiO ₂ 17.2 CaO 0.61 Al ₂ O ₃ 10-15 moisture 0.6

The natural ore is 500,000 won per ton, there is an advantage that can significantly lower the manufacturing cost than when using the pure GeO ₂ international price of 12,000 won per 1g. In addition, Cu ₃ (GeFe) S ₄ germanium of the above components emits far infrared rays 94%, supplying energy of 1.36 × 10 ^{3 ~} 5.5 × 10 ³ Hz, which is a beneficial wavelength to the human body to store the water beneficial to the human body In case water has a structure that has beneficial energy to the human body. In particular, the pH of the water is alkaline due to other rare elements other than trace essential minerals such as potassium, calcium, silicon, iron, and manganese, so that the redox potential (ORP) is similar to the ice structure. It is to have about 50% of the hexagonal water is synthesized is to form a water structure beneficial to the human body.

The method for producing the germanium-containing bottled water poison of the present invention is as follows.

First, the above-mentioned germanium gemstone is pulverized into 800-1000 mesh. At this time, if less than 800 mesh, there is a problem of uneven plasticity, and if it exceeds 1000 mesh, pore formation is difficult. 70 to 85% by weight of the crushed germanium ore, 5 to 10% by weight of kaolin and 10 to 25% by weight of clay are blended and classified. At this time, it is preferable to use a vibrating body. In particular, other components, such as silica, feldspar, limestone, and feldspar, which are conventionally mixed in the manufacture of ceramics, may also be added in small amounts depending on conditions. Then, filter pressing to first remove impurities contained in the mixture and use a scouring machine to uniformly mix each component.

After the raw material powder obtained as described above is aged to an appropriate degree, the aged raw powder is mixed with 70 to 80% by weight and water to 30 to 30% by weight to prepare a dough, followed by molding. This molding process can be accomplished by hand forming, for example, using a wheel. When the molding process is finished, it is dried in a natural state at room temperature and atmospheric pressure for 20 to 80 hours.

The molded poison thus prepared is first roasted at 700 to 800 ° C. If the initial roasting temperature is less than 700 ° C, pore formation is difficult, and if it exceeds 800 ° C, a problem of cracking occurs. Then, the glaze is applied to the primitive grilled poison, which can be put in a suitable pattern prior to this. Such a pattern can be introduced by various methods, for example, by writing. After the glaze is applied, the poison is calcined again at 1050 to 1100 ° C. At this time, heavy metals such as Cr, Cd and As, and other metal salts such as salts thereof are evaporated to form a large amount of pores in the poison.

On the other hand, the present invention includes a germanium ball of a certain size in the living poison. The manufacturing method of the ball is first pulverized germanium ore into 300 to 400 mesh to form a ball shape with a radius of 10 to 30 mm, and then primary firing at 1050 to 1100 ℃, as described above in the heavy metals Harmful components are removed by evaporation. After the primary firing process, the secondary firing is performed at 600 to 800 ° C. to process the organic germanium component in a state where it can be eluted. About 0.4 to 0.6 kg of the germanium ball prepared as described above is placed in bottled water.

Germanium balls prepared as described above are to contain a large amount of hexagonal water by releasing far infrared rays and germanium components contained in the poison and ionizing the water appropriately.

The bottled water of the present invention can be installed in the lid, used in the conventional bottled water, inlet to put water, the handle valve can be installed on the lower portion of the bottled water to discharge the water from the bottled water, these attachments are easily made by those skilled in the art Can be installed.

Hereinafter, the present invention will be described in more detail with reference to Examples, but the scope of the present invention is not limited to the following Examples.

Example

100 parts by weight of natural germanium ore containing about 0.7% germanium and about 15% alumina was pulverized to about 900 mesh. About 80% by weight of the pulverized germanium powder, about 9% by weight of kaolin and about 11% by weight of clay were blended and classified using a vibrating body, followed by filter pressing. Thereafter, the mixture was mixed using a refining machine to prepare a raw material powder and to be aged. 30 parts by weight of water was kneaded with respect to 70 parts by weight of the aged raw powder, and then molded into a desired shape, followed by natural drying at room temperature and atmospheric pressure. Glaze was applied to the first roasted poison and calcined at a temperature of 1050 ℃ to prepare a poison. Separately, the germanium ore is pulverized into 350 mesh and shaped into a ball shape having a radius of 20 mm, and then calcined at 1050 ° C. first and then calcined at 700 ° C. for several times so as to have a weight of about 0.5 kg. Put into the final product.

In the dock manufactured as described above, 94% of far infrared rays having a wavelength of about 6 to 14 μm, which are generally known as far infrared wavelengths useful for the human body, were emitted and about 4.1 × 10 ³ Hz as a result of measuring the wavelength of emitted energy. Was measured.

The germanium-containing bottled water of the present invention has far-infrared emission effect compared to a conventionally known water storage container when storing water, and has a beneficial effect on the human body by generating water having a hexagonal structure.

Simple modifications and variations of the present invention can be readily used by those skilled in the art, and all such variations or modifications can be considered to be included within the scope of the present invention.

Claims (2)

Germanium ore containing 0.36 to 1.05% germanium and 10 to 15% alumina is pulverized into 800 to 1000 mesh and 70 to 85% by weight of the pulverized germanium powder, 5 to 15% by weight kaolin and 10 to 25% by weight clay. Formulating and classifying using a sieve, filter pressing and admixing to prepare a raw powder; Aging the raw material powder and then molding by mixing 70 to 80% by weight of the raw material powder and 20 to 30% by weight of water; Naturally drying the molded poison at room temperature and atmospheric pressure in air; Baking the molded poison at 700 to 800 ° C .; And glazing the germanium ore into 300 to 400 mesh in a poison prepared by applying glaze to the first roasted poison and baking at a temperature of 1050 to 1100 ° C., and then forming a ball shape having a radius of 10 to 30 mm to 1050. Germanium-containing mineral water, characterized in that it comprises 0.4-0.6 kg of germanium balls produced by primary firing at -1100 ° C and secondary firing at 600-800 ° C. The mineral water poison according to claim 1, wherein the germanium gemstone contains germanium of crystalline form of Cu ₃ (GeFe) S ₄ .