KR100603211B1 - Method of producing salt radiating far-infrared rays, and the salt radiating far-infrared rays produced by the method - Google Patents

Abstract

The present invention relates to a method for preparing far-infrared radiation salts absorbing far-infrared radiation energy of jade, and to a far-infrared radiation salt prepared by the method, and more particularly, adding a sun salt to a heat-resistant container containing elvan and wood quail; Loading the container into which the sun salt is added to a kiln having an outer wall of three or more layers of refractory bricks and having a coating layer formed on the innermost two layers of the refractory bricks with the same components as the heat resistant container; Heating the heat resistant container by raising the temperature in the kiln to 850˜1050 ° C. and maintaining it for 6 to 8 hours; And relates to a method for producing far-infrared radiation salt absorbed far-infrared radiation of jade comprising the step of cooling the temperature in the kiln to room temperature and the far-infrared radiation salt prepared by the production method. According to the jade far-infrared radiation salt manufacturing method of the present invention, since a ceramic container and a kiln that emit far-infrared rays are used, it is possible to manufacture the far-infrared radiation salt of jade at high temperature, and the useful minerals in the body exist in oxidized form and are harmful to the body Far-infrared radiation salt of jade that has been absorbed or vaporized in the silver vessel can be prepared.

Jade, salt, wooden door

Description

Method for producing far-infrared radiation salt, and the far-infrared rays produced by the method {@Method of producing Salt radiating far-infrared rays, and the Salt radiating far-infrared rays produced by the method}

1 is an exploded perspective view of a heat-resistant container used in the method for producing far-infrared radiation salts absorbing far-infrared radiation energy of jade of the present invention,

FIG. 2 is a cross-sectional view of a loading form and kiln of a container of a sun salt-loaded container used in the method for producing far-infrared radiation salts absorbing the far-infrared radiation energy of jade according to the present invention.

<Description of the symbols for the main parts of the drawings>

10: heat resistant container, 11: body

12: air outlet, 13: lid

20: kiln, 21: firebrick

22: coated refractory brick, 23: coated refractory brick

24: heat source supply port, 25: blocking plate

26 gas outlet,

The present invention relates to a method for producing a far-infrared radiation salt and a far-infrared radiation salt, and more particularly, a method for producing a far-infrared radiation salt that can absorb far-infrared radiation energy of jade through the heating process of sun salt, and to emit far-infrared radiation. It relates to far-infrared radiation salt prepared by.

Humans contain about 0.09% of body weight of salt, but sodium in salt maintains the proper amount of fluid in the body, including blood, balances acid and base, and the cells ingest nutrients. It plays an important role in helping nerves transmit signals or muscle contractions. The minimum amount of sodium needed by the human body is 10-20 mEq per day, which is 0.5 to 1 g of salt. Therefore, most people eat about 3 grams of salt a day is enough. Insufficient sodium in the body causes serious symptoms, especially if the sodium deficiency progresses in a short time, brain cells swell, causing loss of appetite, nausea, vomiting, difficulty concentrating, confusion, lethargy, excitement, headache, and convulsions. Occurs.

As Korea has progressed to an industrial society in which the industry has developed rapidly for almost 100 years, not only industrial waste is generated from various industrial sites, but also household waste, domestic sewage, factory wastewater, livestock waste water, pesticides, chemical fertilizers, chemicals, and exhausts. Almost all living environments have been contaminated with gas, soot and heavy metals. In particular, the water pollution caused by various wastewater and heavy metals is very serious, and the pollution levels of various river waters in Korea tend to increase every year. Such pollution of river water causes pollution of seawater, and in particular, pollution of coastal seawater is very serious. Therefore, the natural salt produced in the salt field is not only the purity of the salt is reduced by mixing impurities such as heavy metals, pesticides, oil, etc., the salt may cause a problem when ingesting the salt in humans.

One method of removing the contaminants is to remove the contaminants by heating a salt. Specifically, when the salt is heated to a high temperature of 1,000 ° C or more, various harmful heavy metals and impurities are vaporized and removed, thereby making the alkaline salt beneficial to the human body in which only the mineral component beneficial to the human body exists. Examples of such a method include Patent Application No. 1997-71990 'Method for producing alkaline salt'.

On the other hand, jade generally emits far-infrared radiation energy similar to that of an ideal black body, and its effects are found in various ways, such as utilizing it for health. Table 1 below shows the results of far-infrared measurements compared to black bodies of wood gate stones using FT-IR spectrometer at 40 ° C. by Korea Institute of Construction Materials (KICM).

Measurement result of black body of black stone jadeite using FT-IR spectrometer at 40 ℃ Emissivity (5 ~ 20 ㎛) 0.93 Radiation energy (W / ㎡ · ㎛, 40 ℃) 3.74 × 10 ²

Therefore, as described above, the effect of jade is excellent and greatly contributes to the health, and the salt that absorbs a large amount of far-infrared radiation energy of jade despite increasing use and its use of refined salt (since this salt radiates far infrared rays, Rarely reported is an easy process for the preparation of far-infrared radiation salts.

Therefore, the inventors of the present invention, while devising a method for producing far-infrared radiation salt of jade with superior efficacy, used a heat-resistant container containing ganban stone and wood door jade and a kiln coated with the inner wall side with the components of the container, so that the far-infrared radiation energy of jade was sun salt. The present invention has been completed by finding that far-infrared radiation salt is obtained in which not only is absorbed in large amounts, but also other harmful heavy metals are removed.

An object of the present invention is to provide a method for producing far-infrared radiation salt in which jade absorbs far-infrared radiation energy to emit far-infrared rays, and minerals useful to the body are present in an oxidized form while heavy metals harmful to the body are removed.

In order to achieve the above object, the present invention comprises the steps of adding a sun salt in a heat-resistant container containing bar stone and wood quarry; Loading the container into which the sun salt is added to a kiln having an outer wall of three or more layers of refractory bricks and having a coating layer formed on the innermost two layers of the refractory bricks with the same components as the heat resistant container; Heating the heat resistant container by raising the temperature in the kiln to 850˜1050 ° C. and maintaining it for 6 to 8 hours; And it provides a method for producing a far-infrared radiation salt of jade, comprising the step of cooling the temperature in the kiln to room temperature.

In addition, the present invention provides a far-infrared radiation salt prepared by the above production method.

Hereinafter, the method for preparing the far-infrared radiation salt of the present invention will be described in detail by dividing step by step with reference to the accompanying drawings.

The present invention comprises the steps of: iii) injecting a sun salt into a heat-resistant container containing elvan and wood; Ii) loading the container into which the sun salt is added to a kiln having an outer wall of three or more layers of refractory bricks and having a coating layer formed on the innermost two layers of the refractory brick with the same components as the heat resistant container; Iii) heating the heat resistant container by raising the temperature in the kiln to 850-1050 ° C. and maintaining it for 6-8 hours; And iii) cooling the temperature in the kiln to room temperature.

At this time, the component of the heat-resistant container and the coating layer component of the refractory brick of the kiln preferably further contain bentonite, and more preferably further contain two or more components selected from the group consisting of feldspar, silica quartz and talc. . This is necessary for the stability and heat resistance of the container itself, but it also serves to supplement the scar minerals. In addition, the components of the heat-resistant container and the coating layer of the refractory bricks of the kiln more preferably contain all of ganbanite, wood door jade, bentonite, feldspar, silica, kaoring and talc, the content of which is 15 to 40% by weight of gannetite, More preferably, it contains 15 to 40% by weight of wood quarry, 1 to 4% by weight of bentonite, 7 to 15% by weight of feldspar, 5 to 12% by weight of quartz, 6 to 13% by weight of kaoring and 2 to 5% by weight of talc, 20 to 32% by weight of ganbanite, 15 to 32% by weight of wood, bentonite 2 to 3% by weight, feldspar 9 to 10% by weight, quartzite 7 to 8% by weight, kaoring 7 to 9% by weight and talc 3 to 4% by weight Most preferably.

Moreover, you may additionally contain 2 to 6 weight% of limestone as a binder for container manufacture as needed.

First step: adding natural salt to heat resistant container

Solar salt is added to a heat-resistant container containing elvan and wood.

The heat resistant container is made of a ceramic material containing elvan and wood. When the heat-resistant container is made of only jade for far-infrared emission of jade, the container is very weak and easily broken, and the manufacturing of the container is difficult and the manufacturing cost is very expensive. Accordingly, the present inventors have produced a heat-resistant container having the heat-resistant container as the main components of elvan and wood. The vessel has heat resistance that does not melt even at the melting temperature of the salt (about 800 ° C.), and an air distribution port may be installed in the upper portion of the vessel to allow gas in the salt to be discharged by gasification.

Since the heat-resistant container of the present invention contains a wooden door, it emits far-infrared rays in the following heating step, and is also made of a special ceramic container such as elvan, maintaining heat resistance even at a high temperature of 1,000 ° C. or higher. Mokokok has a higher content of beneficial minerals such as germanium, selenium, and cobalt than ordinary jade. Especially, the germanium content is 38ppm per gram, which is more than 12 times that of ordinary germanium hot spring water, and these are known to have anticancer effects. In addition, elvan is composed of 3 to 150,000 holes per cm 3 and has strong adsorption, contains about 25,000 kinds of inorganic salts, and is excellent for removing harmful metals because it acts to exchange ions with heavy metals. It emits far infrared rays along with wood gate.

In addition, the amount of natural salt added may not be sufficiently absorbed by the natural salt when the far-infrared energy of Mokmunok is added to the natural salt, and may not sufficiently remove other harmful heavy metals. Therefore, it is preferable to administer the sun salt of 20 to 80% by volume of the heat-resistant container.

Figure 1 is an exploded perspective view of the heat-resistant container 10 used in the present invention, the container is composed of a body 11 and the lid 13, the upper end of the body so that the inside and outside of the container communicating with the air outlet 13 ) Is installed. Hazardous heavy metals contained in the sun salt may be vaporized and removed through the distribution port 13, and heavy metals may be removed through ion exchange with harmful metals due to the composition of the container.

Second step: loading the container with sun salt into the kiln

In the first step, the heat-resisting container into which the sun salt is added is covered with a lid, and then loaded in a kiln and the kiln door is closed.

At this time, the kiln is made of three or more refractory bricks. In addition, a coating layer is formed on the inner surface of the innermost two layers of the refractory brick of the kiln by coating a material of the same component as the heat-resistant container. That is, it is coated with a ceramic composition containing elvan and wood. Such a coding composition must not enclose the heat resistant container, so that the gas composition in the kiln can provide an environment similar to the components of the heat resistant container. In addition, since the kiln is composed of three or more layers of refractory bricks, the inside and outside of the kiln are completely blocked to prevent heat conduction, thereby keeping the temperature in the kiln at a high temperature for a long time. The reason why this environment is important is that the vaporized heavy metals do not contaminate the salt and obtain pure jade far-infrared radiation salt. The multiple refractory walls prevent acceleration of temperature change, preventing vaporized impurities from liquefying and coating the ceramic composition on the refractory bricks to reliably block heavy metal contamination.

The kiln may be composed of various kinds of kilns to prevent secondary contamination of the salt, and may be composed of gas or electric kilns. 2 shows a schematic temporary example of a kiln for producing far-infrared radiation salt of jade used in the present invention. As shown, the kiln 20 is composed of three layers of refractory bricks 21, 22, and 23, and a heat source supply port 24 capable of supplying heat from the heat source into the kiln 20 of the kiln 20. A plurality of floors are installed on the bottom surface, and a plurality of gas outlets 26 are installed at the upper third point of the kiln, and in the kiln of the gas outlet 26, a blocking plate 25 which prevents heat from being directly released to the outside. Install it.

Step 3: heating the container into which the natural salt is added

After gradually heating the temperature in the kiln for 2 to 3 hours through the heat source supply port to be 850 to 1050 ° C., the temperature in the kiln is again kept isothermal for 6 to 8 hours at the above temperature.

As the kiln is heated in the process, the sun salt gradually melts, and the water, oil and impurities contained in the sun salt vaporize and are discharged into the outer kiln of the vessel through the air outlet 13 of the heat resistant container, and finally As the convection in the kiln is discharged into the atmosphere through the gas outlet 26 located at the top of the kiln. In addition, due to the physical properties of the heat-resistant container itself, it is possible to more reliably remove harmful impurities, and also to have an effect of containing more beneficial minerals in salt. At the same time, far infrared rays are emitted from the vessel into the vessel, and the infrared rays of the emitted jade are absorbed by the salt.

Fourth step: cooling the container in which oxo salt is prepared

Open the kiln door to cool the temperature in the kiln. Finally, various impurities contained in the sun salt are removed and the far-infrared absorbed oxo gold is produced. If necessary, the oxalum prepared by the above method is ground to a suitable size and packaged to complete the product.

In addition, the present invention provides a far-infrared radiation salt absorbing far-infrared radiation energy of jade produced by the above production method.

The chemical constituents of the far-infrared radiation salt prepared by the above method are approximately 95 to 98% by weight of NaCl, 0.06 to 0.08% by weight of Na ₂ O, 0.02 to 0.04% by weight of MgO, 0.01 to 0.03% by weight of K ₂ O, and SiO ₂ 0.02. ~ 0.03% by weight, Al ₂ 0 ₃ 0.01 ~ 0.02% by weight, Fe ₂ O ₃ 0.01 ~ 0.02% by weight, CaO 0.002 ~ 0.003% by weight, and other rare trace elements 0.01 ~ 0.02% by weight.

As a result, the constituents of the far-infrared radiation salt have a much higher content of essential minerals that play an important role in the human body than sun salt, while the components such as lead and arsenic, which are harmful to the human body, are below the detection limit. Natural salts contain various minerals such as calcium, magnesium, iron, manganese, phosphorus, and sulfur, and if they are converted to jade's far-infrared radiation salts, the contents of these minerals will not only change significantly, but sodium, potassium, chlorine, calcium, magnesium, iron, and manganese. The content of phosphorus, silicon, sulfur and zinc is greatly increased. Therefore, the far-infrared radiation salt of jade can prevent various diseases such as nervousness, rickets, undergrowth, anemia, decreased sexual function and sexual organs undergrowth, muscle atrophy, skin disease, bone growth disorder, and decreased resistance when the body lacks minerals. Can provide abundant minerals. In addition, jade's far-infrared radiation salt did not detect impurities contained in natural salts in large quantities, and liver water, lead, copper, arsenic, and mercury.

The far-infrared radiation salt has detoxification neutralizing function of antibacterial, antiviral heavy metals and toxic substances, and also contains natural minerals of essential trace elements. It is a salt that maximizes the reinforcement of natural minerals of essential elements.

The far-infrared radiation salt has a function that can not be compared with the existing salt that can be utilized in a variety of food cooking, manufacturing, processing and high quality, refractory, rare adult disease healing natural therapy. Specifically, doenjang, red pepper paste, soy sauce, salted fish, kimchi production, cooking of food, drinking, fern, eye wash, trauma disinfection, skin cleansing agent, antidote, salt natural therapy, flavor, bad breath, gum disease, Stomatitis, trauma disinfection, eye disease, corn, warts, skin disease, athlete's foot, allergies, insect bites, burns, frostbite, ringworm, stubbornness, white lead, epithelial cancer, white hair, hypertension, heart disease, gastrointestinal disease, diabetes, kidney bladder urinary system disease, Waste toxins detoxification, malignant tumors (cancer), parasites, bacteria, staphylococcus, viruses, etc. There is a natural healing effect.

Hereinafter, the present invention will be described in detail by production examples and examples.

However, the following Preparation Examples and Examples are merely to illustrate the present invention, and the content of the present invention is not limited to the following Examples.

<Production example>

After drying the high-quality sun salt from the west coast in the sun, 4 kg of the sun salt is added to 32% by weight of ganbanite, 32% by weight of jadeite, 2% by weight of bentonite, 10% by weight of feldspar, 8% by weight of quartzite and 4% by weight of limestone. A heat-resistant container (width 25 × length 25 × height 20 cm) consisting of 9% by weight and 3% by weight of talc was finely charged and then covered with a lid. Subsequently, 288 containers in which the natural salt was added were loaded in the kiln with a space between the containers so that air could be distributed, and the kiln door was closed. Thereafter, the temperature in the kiln was gradually heated to 1050 ° C for 2 hours through the heat source supply port of the kiln, and maintained at that temperature for 6 hours. Thereafter, the door of the kiln was opened, and the temperature in the kiln was cooled to room temperature. Through this process, 850 kg of far-infrared radiation salt of jade purified from 1000 kg of sun salt was obtained. At this time, NaCl concentration of sun salt was 88% by weight, and NaCl concentration in far-infrared radiation salt absorbed far-infrared radiation of jade was 97% by weight. It was.

<Example>

The chemical constituents of the far-infrared radiation salt absorbing the far-infrared radiation energy of jade prepared by the above method are 97 wt% NaCl, 0.072 wt% Na ₂ O, 0.0342 wt% MgO, 0.0254 wt% K ₂ O, 0.0247 wt% SiO ₂ It contains 0.0157% by weight of Al ₂ 0 ₃ , 0.009% by weight of Fe ₂ O ₃ , 0.0022% by weight of CaO, and 0.0166% by weight of other rare trace elements.

As such, the far-infrared radiation salt contains hardly any heavy metals such as arsenic, lead, cadmium, and mercury, which are firstly arsenic and lead having a specific gravity greater than that of the salt to the lower end of the heat resistant container due to the difference in specific gravity. Precipitated and mostly absorbed in the container, and the remaining traces of the heavy metal are vaporized into the air at a high temperature of 1,000 ° C. or higher because the boiling point is lower than salt. On the other hand, cadmium, mercury, and the like, which have a much lower boiling point than salt, are mostly vaporized and removed at the beginning of the heating step.

In addition, as can be seen from the chemical composition of the far-infrared radiation salt described above, the liver water (MgCl ₂ .6H ₂ O) is oxidized to MgO and is present. In addition, CaCl ₂ is present as CaO, KCl is oxidized to K ₂ O. Other mineral components were also found to be oxidized. As such, it was confirmed that K, Ca, Fe, Na, etc., which are useful minerals in the body, are present in higher concentrations than sun salt.

In addition, the far-infrared emissivity of the far-infrared radiation salt prepared by the above method was measured using an FT-IR spectrometer at 40 ° C. in comparison with a black body (requested by the Korea Institute of Construction Materials).

Measurement result of far-infrared emissivity of salt absorbing jade's far-infrared radiation energy compared to black body

Emissivity (5 ~ 20 ㎛) 0.90 Radiation energy (W / ㎡ · ㎛, 40 ℃) 3.62 × 10 ²

As shown in the table, it was found that the far-infrared radiation salt prepared by the production method of the present invention exhibited an emissivity almost similar to that of the black body.

As described above, according to the method for producing far-infrared radiation salt of the present invention, since a special ceramic container and a specially coated kiln are used, not only the far-infrared radiation salt of jade absorbing the far-infrared radiation energy of jade can be produced at high temperature. In addition, minerals that are useful to the body are in oxidized form and heavy metals that are harmful to the body are absorbed or vaporized in the container and removed. Therefore, the far-infrared radiation salt prepared by the above method can be used to benefit human health.

Claims (6)

Iii) introducing sun salt into a heat-resistant container containing elvan and wood; Ii) loading the container into which the sun salt is added to a kiln having an outer wall of three or more layers of refractory bricks and having a coating layer formed on the innermost two layers of the refractory brick with the same components as the heat resistant container; Iii) heating the heat resistant container by raising the temperature in the kiln to 850-1050 ° C. and maintaining it for 6-8 hours; And Iii) cooling the temperature in the kiln to room temperature. 2. The far-infrared radiation salt according to claim 1, wherein the components of the heat resistant container and the components of the refractory brick coating layer of the kiln further contain at least two or more components selected from the group consisting of bentonite, feldspar, silica, kaoring and talc. Manufacturing method. 3. The method of claim 2, wherein the components of the heat resistant container and the components of the refractory brick coating layer of the kiln contain bentonite, feldspar, silica, kaoring and talc. According to claim 3, wherein the heat-resistant container component and the special coating component of the refractory brick of the kiln is 15 to 40% by weight of ganbanite, 15 to 40% by weight of the quarry, 1 to 4% by weight of bentonite, 7 to 15% by weight of feldspar 5 to 12% by weight, 6 to 13% by weight of kaoring and 2 to 5% by weight of talc. According to claim 4, wherein the components of the heat-resistant container and the components of the refractory brick coating layer of the kiln is 20 to 32% by weight of ganbanite, 15 to 32% by weight of the quarry, 2 to 3% by weight of bentonite, 9 to 10% by weight of feldspar, A method for producing far-infrared radiation salt comprising 7 to 8% by weight of silica, 7 to 9% by weight of kaoring and 3 to 4% by weight of talc. Far-infrared radiation salt prepared by the method of any one of claims 1 to 5.

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