KR100964560B1 - Filter for generation of alkaline reduced water using mineral mixtures and method of manufacturing the filter - Google Patents

Abstract

PURPOSE: A manufacturing method of a filter and a production filter of alkaline reduced water using a mineral mixture are provided to sterilize bacteria with an anion and far infrared rays emitted, and to eliminate all kinds of harmful materials or heavy metals etc to a human body. CONSTITUTION: A production filter(1) of alkaline reduced water comprises mineral mixtures consisting of 20 weight parts of silica, 30 weight parts of carbon, 30 weight parts of germanium, 20 weight part of potash feldspar, 10 weight parts of diatomite, 10 weight parts of pegmatite, 20 weight parts of nickel, 30 weight parts of beryl, 30 weight parts of sodium carbonate, 30 weight parts of calcium carbonate, 30 weight parts of tantalum, 50 weight parts of lepidolite, 30 weight parts of manganese, 50 weight parts of the magnesium powder, 30 weight parts of mica, 50 weight parts of zeolite, 80 weight parts of magnesium oxide, 40 weight parts of calcium oxide, 50 weight parts of selenium, 30 weight parts of copper oxide, 30 weight parts of oxidized steel powder, 20 weight parts of the sodium, 30 weight parts of cerium, 30 weight parts of charcoal dust, 20 weight parts of zinc, 50 weight parts of illite, 30 weight parts of monazite, 30 weight parts of the niobium and etc.

Description

Filter for generation of alkaline reduced water using mineral mixtures and method of manufacturing the filter}

The present invention relates to an alkaline reduced water generating filter using a mineral mixture and a method for manufacturing the filter, and more particularly, used in place of the filter used in the existing water purifier, sterilizing bacteria by anion and far infrared rays emitted from itself and harmful to human body. The present invention relates to an alkali reduced water generating filter using a mineral mixture capable of removing various harmful substances, heavy metals, and the like, and a method of manufacturing the filter.

Generally, various types of water purifiers are used to purify tap water again in order to obtain clean drinking water due to pollution of water supply and tap water. Also widely used.

 In particular, the most important filter in the water purifier has a structure in which a sediment filter, a pretreated carbon filter, a post carbon filter, and a UF hollow fiber membrane filter are sequentially connected, and the raw water passes through these filters, The process removes heavy metals and other harmful substances from raw water.

However, if the purified water stored in the storage tank is immediately discharged, there is no problem, but as the stored state elapses for a long time, the purified water is secondaryly infected and decayed, and the user can drink the decayed water and metabolize the body. There was a problem causing illness by degrading function.

In addition, the water purified in the general water purifier, besides the suspended sediment, removes the beneficial components (e.g. minerals) that are beneficial to the human body in the water, causing changes in the properties of the water, which can also cause side effects of the human body when taken for a long time. There was this.

The present invention has been made to solve the above problems, as well as sterilizing the bacteria by anion and far infrared rays emitted from the filter prepared by mixing 43 kinds of mineral mixtures, as well as removing various harmful substances or heavy metals harmful to the human body. It is an object of the present invention to provide an alkaline reduced water generation filter and a method for producing the filter using a mineral mixture that promotes immune function, promotes blood circulation, and miniaturizes water molecules to increase absorption in the body.

The present invention, 20 parts by weight of silica stone (powder), 30 parts by weight of carbon, 30 parts by weight of germanium, 30 parts by weight of potassium feldspar, 10 parts by weight of diatomite , 10 parts by weight of pegmatite, 20 parts by weight of nickel, 30 parts by weight of beryl, 30 parts by weight of sodium carbonate, 30 parts by weight of calcium carbonate, tantalum 30 parts by weight, 50 parts by weight of lepidolite, 30 parts by weight of manganese, 50 parts by weight of magnesium powder, 30 parts by weight of mica, 50 parts by weight of zeolite, magnesium oxide (magnesium oxide) 80 parts by weight, calcium oxide 40 parts by weight, selenium 20 parts by weight, copper oxide 30 parts by weight, iron oxide powder 30 parts by weight, sodium 20 parts by weight, cerium 30 parts by weight, charcoal powder 30 parts by weight, zinc 20 parts by weight, illite 50 in Part, 30 parts by weight of monazite, 30 parts by weight of niobium, 20 parts by weight of arsenic, 30 parts by weight of jade, 30 parts by weight of phosphorus, sulfur 10 Parts by weight, 20 parts by weight of aluminum, 30 parts by weight of talc, 20 parts by weight of graphite, 50 parts by weight of sepolite, 30 parts by weight of tin, 20 parts by weight of tungsten , Mineral mixture consisting of 40 parts by weight of tourmaline, 50 parts by weight of zirconium, 20 parts by weight of titanium dioxide, 20 parts by weight of magnet powder, 20 parts by weight of silver nano and powder 15 parts by weight of kaolin in form, 25 parts by weight of pottery stone, 10 parts by weight of agalmatolite, 10 parts by weight of feldspar, 30 parts by weight of clay, 10 parts by weight of sericite Mixing the mineral mixture formed in a weight ratio of 70:30; Powdering the mixed mineral mixture into 400-600 mesh using a high speed jet mill; Stirring the powdered mineral mixture in a stirrer for 5-6 hours; The stirred mineral mixture is poured into a mold and then injection molded, characterized in that it comprises the step of firing at 500-700 ℃.

Alkaline reduced water generation filter using the mineral mixture according to the present invention and a filter manufacturing method, the various harmful substances or heavy metals contained in the water is removed and reduced to alkaline reduced water due to the anion and far-infrared radiation efficacy as the water passes through the filter Drinking is effective in strengthening immune function, improving blood circulation and regenerating tissue.

In addition, by using the water passing through the filter for agriculture as well as drinking water, it not only increases the growth rate of crops and prevents pests, but also serves as a breeding water for livestock farmers, which is resistant to infectious diseases and reduces mortality. .

Alkaline reduced water generation filter using the mineral mixture according to the present invention, 20 parts by weight of silica powder (silica stone), 30 parts by weight of carbon, 30 parts by weight of germanium (germanium), carry (potash feldspar) 20 Parts by weight, 10 parts by weight of diatomite, 10 parts by weight of pegmatite, 20 parts by weight of nickel, 30 parts by weight of beryl, 30 parts by weight of sodium carbonate, calcium carbonate ) 30 parts by weight, tantalum 30 parts by weight, 50 parts by weight of lepidolite, 30 parts by weight of manganese, 50 parts by weight of magnesium powder, 30 parts by weight of mica, 50 parts by weight of zeolite, 80 parts by weight of magnesium oxide, 40 parts by weight of calcium oxide, 20 parts by weight of selenium, 30 parts by weight of copper oxide, iron oxide powder powder 30 parts by weight, sodium 20 parts by weight, cerium 30 parts by weight, charcoal powder ) 30 parts by weight, 20 parts by weight of zinc, 50 parts by weight of illite, 30 parts by weight of monazite, 30 parts by weight of niobium, 20 parts by weight of arsenic, jade 30 parts by weight of jade, 30 parts by weight of phosphorus, 10 parts by weight of sulfur, 20 parts by weight of aluminum, 30 parts by weight of talc, 20 parts by weight of graphite, sepiolite ) 50 parts by weight, tin 30 parts by weight, tungsten 20 parts by weight, tourmaline 40 parts by weight, zirconium 50 parts by weight, titanium dioxide 20 parts by weight, magnet powder powder 20 parts by weight, mineral mixture consisting of 20 parts by weight of silver nano, 15 parts by weight of kaolin in powder form, 25 parts by weight of pottery stone, 10 parts by weight of agalmatolite, feldspar ) Injection molded by mixing a mineral mixture consisting of 10 parts by weight, 30 parts by weight of clay and 10 parts by weight of sericite in a weight ratio of 70:30. .

In addition, the filter is formed in a cylindrical shape, the flow path is formed so that the water passes therein, characterized in that the groove portion is formed so that the permanent magnet is embedded between the flow path.

In addition, the filter is formed in the form of a container with an open top, characterized in that the bottom is provided with a plurality of metal pieces so that the cold water outlet and hot water outlet are formed and the permanent magnet is attached.

In addition, the protective case is further provided to prevent damage to the device outside the filter.

In addition, the method for producing alkaline reduced water using the mineral mixture is 20 parts by weight of silica stone (powder), 30 parts by weight of carbon, 30 parts by weight of germanium, 20 parts by weight of potassium feldspar. Parts, 10 parts by weight of diatomite, 10 parts by weight of pegmatite, 20 parts by weight of nickel, 30 parts by weight of beryl, 30 parts by weight of sodium carbonate, calcium carbonate 30 parts by weight, 30 parts by weight of tantalum, 50 parts by weight of lepidolite, 30 parts by weight of manganese, 50 parts by weight of magnesium powder, 30 parts by weight of mica, fluorite 50 parts by weight of zeolite, 80 parts by weight of magnesium oxide, 40 parts by weight of calcium oxide, 20 parts by weight of selenium, 30 parts by weight of copper oxide, iron oxide powder ) 30 parts by weight, sodium 20 parts by weight, cerium 30 parts by weight, charcoal powder 30 parts by weight, 20 parts by weight of zinc, 50 parts by weight of illite, 30 parts by weight of monazite, 30 parts by weight of niobium, 20 parts by weight of arsenic, jade ( 30 parts by weight of jade, 30 parts by weight of phosphorus, 10 parts by weight of sulfur, 20 parts by weight of aluminum, 30 parts by weight of talc, 20 parts by weight of graphite, sepiolite 50 parts by weight, tin 30 parts by weight, tungsten 20 parts by weight, tourmaline 40 parts by weight, zirconium 50 parts by weight, titanium dioxide 20 parts by weight, magnet powder ) 20 parts by weight, mineral mixture consisting of 20 parts by weight of silver nano and 15 parts by weight of kaolin in powder form, 25 parts by weight of pottery stone, 10 parts by weight of agalmatolite, feldspar Mixing the mineral mixture consisting of 10 parts by weight, 30 parts by weight of clay and 10 parts by weight of sericite in a weight ratio of 70:30; Powdering the mixed mineral mixture into 400-600 mesh using a high speed jet mill; Stirring the powdered mineral mixture in a stirrer for 5-6 hours; The stirred mineral mixture is poured into a mold and then injection molded, characterized in that it comprises the step of firing at 500-700 ℃.

In addition, after the injection molding it is characterized in that it further comprises applying a glaze on the surface of the fired filter and refired at 1000-1300 ℃ again.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a perspective view showing an alkali reduced water generating filter using a mineral mixture according to the present invention, Figure 2 is a cross-sectional view showing an alkali reduced water generating filter using a mineral mixture according to the present invention, Figure 3 is a mineral mixture according to the present invention FIG. 4 is a cross-sectional view of an alkaline reduced water generating filter using the mineral mixture according to FIG. 3, and FIG. 5 is an alkali reduced water generating filter manufacturing method using the mineral mixture according to the present invention. 6 is an anion measurement test report of an alkali reduced water generation filter using the mineral mixture according to the present invention, and FIG. 7 is an emissivity and radiation energy measurement test report of an alkali reduced water generation filter using the mineral mixture according to the present invention. 8 is an alkali using the mineral mixture according to the present invention. The infrared measurement test results of the raw water produced filter, Figure 9 is a photograph showing the infrared filter of the alkaline water produced by the mineral mixture according to the invention.

1 and 2, the alkali reduced water generation filter (hereinafter referred to as 'filter' for convenience) using the mineral mixture according to the present invention is 20 parts by weight of silica powder (silica stone), carbon ( 30 parts by weight of carbon, 30 parts by weight of germanium, 20 parts by weight of potash feldspar, 10 parts by weight of diatomite, 10 parts by weight of pegmatite, 20 parts by weight of nickel, green tin ( beryl 30 parts by weight, sodium carbonate 30 parts by weight, calcium carbonate 30 parts by weight, tantalum 30 parts by weight, lepidolite 50 parts by weight, manganese 30 parts by weight Parts, 50 parts by weight of magnesium powder, 30 parts by weight of mica, 50 parts by weight of zeolite, 80 parts by weight of magnesium oxide, 40 parts by weight of calcium oxide, selenium ( selenium 20 parts by weight, copper oxide 30 parts by weight, iron oxide powder 30 parts by weight, small (sodium) 20 parts by weight, cerium 30 parts by weight, charcoal powder 30 parts by weight, zinc 20 parts by weight, illite 50 parts by weight, monazite 30 parts by weight , 30 parts by weight of niobium, 20 parts by weight of arsenic, 30 parts by weight of jade, 30 parts by weight of phosphorus, 10 parts by weight of sulfur, 20 parts of aluminum. Parts, 30 parts by weight of talc, 20 parts by weight of graphite, 50 parts by weight of sepolite, 30 parts by weight of tin, 20 parts by weight of tungsten, 40 parts by weight of tourmaline, Mineral mixture consisting of 50 parts by weight of zirconium, 20 parts by weight of titanium dioxide, 20 parts by weight of magnet powder, 20 parts by weight of silver nano and 15 parts by weight of kaolin in powder form , 25 parts by weight of pottery stone, 10 parts by weight of agalmatolite, 10 parts by weight of feldspar, 30 parts by weight of clay, and 10 parts by weight of sericite A mixture of water mixture in a weight ratio of 70: 30 is injection molded.

The filter 1 may be used for general household, agricultural, industrial, commercial, etc., and may be used instead of the filter used in the existing water purifier. In addition to the water purifier, it can also be used by connecting to a general faucet.

The filter 1 has a cylindrical shape, and a flow path 11 is formed to allow water to pass through therein. That is, the general tap water not only removes various harmful substances or heavy metals contained in the water due to anion release and far-infrared radiation effect while passing through the flow passage 11, and changes to alkaline reduced water.

On the other hand, the groove portion 12 is formed between the passage 11 so that the permanent magnet 2 of 1000-3000 gauss is built therein, so that the water passing through the passage 11 passes through the permanent magnet 2 again. In addition, the magnetization treatment capacity is increased, so that the water molecules are miniaturized to be quickly absorbed into the body.

The filter 1 may be used to form only the flow path (11), it is also possible to further install a permanent magnet (2) between the flow path (11).

As shown in Figure 3 and 4, the filter 1 of another example is formed in the shape of a container with an open top, the cold water outlet 13 and the hot water outlet 14 is formed at the bottom and the permanent magnet ( A plurality of metal pieces 15 are provided to attach 2). An upper portion of the filter 1 may be installed to open and close a cover (not shown) having an inlet to allow water to flow therein.

Meanwhile, as shown in FIGS. 1 to 4, a protective case 3 may be further installed outside the filter 1 to prevent damage to the device.

The cylindrical filter 1 is preferably made of PVC and the container-type filter 1 is preferably made of stainless steel.

Hereinafter, a method for preparing an alkali reduced water generation filter using a mineral mixture according to the present invention will be described.

As shown in FIG. 5, the method for producing alkaline reduced water using the mineral mixture includes mixing the mineral mixture (100), powdering the mixed mineral mixture (200), and powdering the mineral mixture. Stirring step 300, and injection molding the stirred mineral mixture and then calcining (400).

First, in the step of mixing the mineral mixture (100), 20 parts by weight of silica powder (silica stone), 30 parts by weight of carbon, 30 parts by weight of germanium (germanium), 20 (potash feldspar) 20 Parts by weight, 10 parts by weight of diatomite, 10 parts by weight of pegmatite, 20 parts by weight of nickel, 30 parts by weight of beryl, 30 parts by weight of sodium carbonate, calcium carbonate ) 30 parts by weight, tantalum 30 parts by weight, 50 parts by weight of lepidolite, 30 parts by weight of manganese, 50 parts by weight of magnesium powder, 30 parts by weight of mica, 50 parts by weight of zeolite, 80 parts by weight of magnesium oxide, 40 parts by weight of calcium oxide, 20 parts by weight of selenium, 30 parts by weight of copper oxide, iron oxide powder powder 30 parts by weight, sodium 20 parts by weight, cerium 30 parts by weight, charcoal powder 30 parts by weight, 20 parts by weight of zinc, 50 parts by weight of illite, 30 parts by weight of monazite, 30 parts by weight of niobium, 20 parts by weight of arsenic, 30 parts by weight of jade Parts, 30 parts by weight of phosphorus, 10 parts by weight of sulfur, 20 parts by weight of aluminum, 30 parts by weight of talc, 20 parts by weight of graphite, 50 parts by weight of sepolite, 30 parts by weight of tin, 20 parts by weight of tungsten, 40 parts by weight of tourmaline, 50 parts by weight of zirconium, 20 parts by weight of titanium dioxide, 20 parts by weight of magnet powder , Mineral mixture consisting of 20 parts by weight of silver nano and 15 parts by weight of kaolin in powder form, 25 parts by weight of pottery stone, 10 parts by weight of agalmatolite, 10 parts by weight of feldspar, The mineral mixture consisting of 30 parts by weight of clay and 10 parts by weight of sericite is mixed in a weight ratio of 70:30.

In the step (200) of powdering the mixed mineral mixture, the mixed mineral mixture is powdered into a 400-600 mesh with a high speed jet mill, and the high speed jet mill is a device for pulverizing and crushing using compressed air. It is a device that grinds by high pressure and high speed air while high-speed track movement is performed by the injection nozzle inside by high-speed injection of the sample with the compressed air through the ejector through the ejector at high speed.

In the step 300 of stirring the powdered mineral mixture, the powdered mineral mixture may be stirred in the stirrer for 5-6 hours, thereby effectively stirring the finely ground mineral mixture by the high speed jet mill.

In the step 400 of injection molding and then firing the stirred mineral mixture, the stirred mineral mixture is poured into a mold and injection molded and then fired at 500-700 ° C. Therefore, the manufacture of the filter (1) capable of sterilizing bacteria by the negative ions and far infrared rays emitted from itself and removing various harmful substances or heavy metals harmful to the human body is completed.

Meanwhile, the method may further include applying a glaze to the surface of the fired filter 1 after injection molding and refires at 1000-1300 ° C. Therefore, in addition to glossing the surface of the filter 1 to beautify the appearance, it is possible to increase the strength and to make the surface semi-finished to prevent the dirt, and to remove the absorbency to increase the resistance to water or chemicals. have.

Hereinafter, the content of the present invention will be described in more detail by examples. However, these examples are only presented to more easily understand the contents of the present invention, the scope of the present invention is not limited by these examples.

≪ Example 1 >

20 parts by weight of silica powder in powder form, 30 parts by weight of carbon, 30 parts by weight of germanium, 20 parts by weight of potash feldspar, 10 parts by weight of diatomite, macrocrystalline ( 10 parts by weight of pegmatite, 20 parts by weight of nickel, 30 parts by weight of green tin, 30 parts by weight of sodium carbonate, 30 parts by weight of calcium carbonate, 30 parts by weight of tantalum, 50 parts by weight of lepidolite, 30 parts by weight of manganese, 50 parts by weight of magnesium powder, 30 parts by weight of mica, 50 parts by weight of zeolite, magnesium oxide 80 parts by weight, 40 parts by weight of calcium oxide, 20 parts by weight of selenium, 30 parts by weight of copper oxide, 30 parts by weight of iron oxide powder, 20 parts by weight of sodium, 30 parts by weight of cerium, 30 parts by weight of charcoal powder, 20 parts by weight of zinc, 50 parts by weight of illite, Monaza 30 parts by weight of monazite, 30 parts by weight of niobium, 20 parts by weight of arsenic, 30 parts by weight of jade, 30 parts by weight of phosphorus, 10 parts by weight of sulfur 20 parts by weight of aluminum, 30 parts by weight of talc, 20 parts by weight of graphite, 50 parts by weight of sepolite, 30 parts by weight of tin, 20 parts by weight of tungsten, tourmaline (tourmaline) 40 parts by weight, zirconium (50 parts by weight), titanium dioxide (20 parts by weight), 20 parts by weight of magnet powder, 20 parts by weight of silver nano (silver nano) and a mineral mixture consisting of powder Minerals consisting of 15 parts by weight of kaolin, 25 parts by weight of pottery stone, 10 parts by weight of agalmatolite, 10 parts by weight of feldspar, 30 parts by weight of clay, and 10 parts by weight of sericite The mixture was mixed at a weight ratio of 70:30, powdered into 500 mesh using a high speed jet mill, and stirred for 6 hours in a stirrer, followed by stirring The mineral mixture was poured into a mold and molded, and then fired at 600 ° C. to prepare a filter.

<Example 2>

The filter prepared according to Example 1 was tested at room temperature 24 ° C., humidity 36%, and anion water 104 / cc in order to measure the amount of negative ions released using a charge particle measuring apparatus.

As shown in Figure 6, the amount of negative ions released from the filter was measured at 15,440 (ION / cc).

<Example 3>

The filter prepared in Example 1 was tested for emissivity and amount of radiation energy using an FT-IR spectrometer.

As shown in FIG. 7, the emissivity was measured at 0.918 (μm) and the emission energy was measured at 3.54 × 10 ² .

<Example 4>

The filter prepared according to Example 1 was tested for infrared radiation using an infrared thermal imager.

As shown in FIG. 8 and FIG. 9, the test was performed at a room temperature of 26 ° C. and a humidity of 29%, and is a measurement result of processing infrared radiation energy emitted from a filter into images and temperature data.

As such, as can be seen through the various embodiments of the present invention, the filter of the present invention maximizes the amount of anion and far-infrared radiation at room temperature to remove various harmful substances or heavy metals contained in water and reduce them to alkaline reduced water. It has the effect of strengthening and improving blood circulation and tissue regeneration.

Although the present invention has been described with reference to the accompanying drawings, it will be apparent to those skilled in the art that many various obvious modifications are possible without departing from the scope of the invention from this description. Therefore, the scope of the invention should be construed by the claims described to include examples of many such variations.

1 is a perspective view showing an alkali reduced water generating filter using a mineral mixture according to the present invention.

Figure 2 is a cross-sectional view showing an alkaline reduced water generation filter using a mineral mixture according to the present invention.

Figure 3 is an exploded perspective view showing another example of the alkaline reduced water generation filter using the mineral mixture according to the present invention.

4 is a cross-sectional view of the alkaline reduced water generation filter using the mineral mixture according to FIG.

Figure 5 is a process chart showing a method for producing alkaline reduced water filter using the mineral mixture according to the present invention.

6 is an anion measurement test report of the alkaline reduced water generation filter using the mineral mixture according to the present invention.

7 is an emissivity and radiation energy measurement test results of the alkaline reduced water generation filter using the mineral mixture according to the present invention.

8 is an infrared thermography test report of the alkali reduced water generation filter using the mineral mixture according to the present invention.

Figure 9 is a photograph showing the infrared thermal image of the alkaline reduced water generating filter using the mineral mixture according to the present invention.

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

1: filter

    11: euro

    12: groove

    13: cold water outlet

    14: hot water outlet

    15: metal piece

2: permanent magnet

3: Protective case

Claims (6)

20 parts by weight of silica powder in powder form, 30 parts by weight of carbon, 30 parts by weight of germanium, 20 parts by weight of potash feldspar, 10 parts by weight of diatomite, macrocrystalline ( 10 parts by weight of pegmatite, 20 parts by weight of nickel, 30 parts by weight of green tin, 30 parts by weight of sodium carbonate, 30 parts by weight of calcium carbonate, 30 parts by weight of tantalum, 50 parts by weight of lepidolite, 30 parts by weight of manganese, 50 parts by weight of magnesium powder, 30 parts by weight of mica, 50 parts by weight of zeolite, magnesium oxide 80 parts by weight, 40 parts by weight of calcium oxide, 20 parts by weight of selenium, 30 parts by weight of copper oxide, 30 parts by weight of iron oxide powder, 20 parts by weight of sodium, 30 parts by weight of cerium, 30 parts by weight of charcoal powder, 20 parts by weight of zinc, 50 parts by weight of illite, Monaza 30 parts by weight of monazite, 30 parts by weight of niobium, 20 parts by weight of arsenic, 30 parts by weight of jade, 30 parts by weight of phosphorus, 10 parts by weight of sulfur 20 parts by weight of aluminum, 30 parts by weight of talc, 20 parts by weight of graphite, 50 parts by weight of sepolite, 30 parts by weight of tin, 20 parts by weight of tungsten, tourmaline (tourmaline) 40 parts by weight, zirconium (50 parts by weight), titanium dioxide (20 parts by weight), 20 parts by weight of magnet powder, 20 parts by weight of silver nano (silver nano) and a mineral mixture consisting of powder Minerals consisting of 15 parts by weight of kaolin, 25 parts by weight of pottery stone, 10 parts by weight of agalmatolite, 10 parts by weight of feldspar, 30 parts by weight of clay, and 10 parts by weight of sericite Alkali reduced water production filter using a mineral mixture, characterized in that the injection molding by mixing the mixture in a weight ratio of 70:30. The method of claim 1, wherein the filter is formed in a cylindrical shape, the channel is formed so that the water passes therein, the alkaline reduced water generation using the mineral mixture, characterized in that the groove is formed so that the permanent magnet is embedded between the passage. filter. According to claim 1, wherein the filter is formed in the form of an open top of the container, the cold water outlet and hot water outlet is formed alkali and using a mineral mixture, characterized in that a plurality of metal pieces are provided so that the permanent magnet is attached to each other Reduced water generation filter. According to any one of claims 1 to 3, Alkali reduced water generation filter using a mineral mixture, characterized in that the protective case is further provided to prevent damage to the device outside the filter. 20 parts by weight of silica powder in powder form, 30 parts by weight of carbon, 30 parts by weight of germanium, 20 parts by weight of potash feldspar, 10 parts by weight of diatomite, macrocrystalline ( 10 parts by weight of pegmatite, 20 parts by weight of nickel, 30 parts by weight of green tin, 30 parts by weight of sodium carbonate, 30 parts by weight of calcium carbonate, 30 parts by weight of tantalum, 50 parts by weight of lepidolite, 30 parts by weight of manganese, 50 parts by weight of magnesium powder, 30 parts by weight of mica, 50 parts by weight of zeolite, magnesium oxide 80 parts by weight, 40 parts by weight of calcium oxide, 20 parts by weight of selenium, 30 parts by weight of copper oxide, 30 parts by weight of iron oxide powder, 20 parts by weight of sodium, 30 parts by weight of cerium, 30 parts by weight of charcoal powder, 20 parts by weight of zinc, 50 parts by weight of illite, Monaza 30 parts by weight of monazite, 30 parts by weight of niobium, 20 parts by weight of arsenic, 30 parts by weight of jade, 30 parts by weight of phosphorus, 10 parts by weight of sulfur 20 parts by weight of aluminum, 30 parts by weight of talc, 20 parts by weight of graphite, 50 parts by weight of sepolite, 30 parts by weight of tin, 20 parts by weight of tungsten, tourmaline (tourmaline) 40 parts by weight, zirconium (50 parts by weight), titanium dioxide (20 parts by weight), 20 parts by weight of magnet powder, 20 parts by weight of silver nano (silver nano) and a mineral mixture consisting of powder Minerals consisting of 15 parts by weight of kaolin, 25 parts by weight of pottery stone, 10 parts by weight of agalmatolite, 10 parts by weight of feldspar, 30 parts by weight of clay, and 10 parts by weight of sericite Mixing the mixture in a weight ratio of 70:30; Finely powdering the mixed mineral mixture into 400-600 mesh using a high speed jet mill; Stirring the finely powdered mineral mixture in a stirrer for 5-6 hours; Pour the stirred mineral mixture in a mold and injection molding, and then calcining at 500-700 ° C. Alkali reduced water production filter production method using a mineral mixture, characterized in that it comprises. The method of claim 5, further comprising applying a glaze to the surface of the calcined filter after injection molding and refires at 1000-1300 ° C.

Images