KR100753183B1 - Electrolytic ionized water generating device and method - Google Patents

Abstract

The present invention relates to an electrolytic ion water generating device and a method thereof, comprising a loess tube forming an ion exchange membrane having a predetermined thickness, a pair of anode electrodes of the same length disposed on an outer circumferential surface of the ocher tube, and disposed inside the loess tube After supplying the seaweed water and tap water made by processing the seaweed to the electrolytic cell in which the cathode electrode rod 2.5 times larger than the length of the anode electrode is installed, it is electrolyzed to generate acidic ionized water and alkaline ionized water.

According to the present invention, the conventional electrolytic ionized water generating device can not only solve the disadvantage of not producing strong acidic ionized water of pH-1 and strong alkaline ionized water of pH-14, but also completely sterilized to be clearer and cleaner than humans. It is possible to utilize high quality ionized water that is rapidly absorbed as drinking water, and may use the present invention in medicine, agriculture, industry, fisheries, and the like.

Electrolytic ionized water generator, acidic ionized water, alkaline ionized water, seaweed, ocher

Description

Electrolytic ion water generator and method thereof

1 is a cross-sectional view of a conventional electrolytic ionized water generating device.

2 is a cross-sectional view of the electrolytic ionized water generating device according to the present invention.

3 is a cross-sectional view showing a state in which the ganban stone and mica are disposed in the electrolytic cell of the electrolytic ion water generating device according to the present invention.

4 is a plan sectional view of the electrolytic ionized water generating device according to the present invention.

5 is a process chart of the electrolytic ionized water generating method according to the first embodiment of the present invention.

6 is a process chart of the electrolytic ionized water generation method according to a second embodiment of the present invention.

7 is a process chart of the electrolytic ionized water generation method according to a third embodiment of the present invention.

<Explanation of symbols for main parts of the drawings>

10: electrolytic cell 11,12: plate type electrode

11a: anode chamber 12a: cathode chamber

13: ion exchange membrane 20: electrolyzer

21: ocher tube 22: anode electrode

23: cathode electrode 24: ionized water tank

24a: ionized water outlet 25: power supply

The present invention relates to an electrolytic ionized water generating apparatus and a method thereof, and more particularly, an electrolytic ionized water generating apparatus for generating acidic ionized water and alkaline ionized water by electrolyzing a seaweed water and tap water made by processing SALICORNIA HERBACEA L. It is about a method.

Conventional home or business electrolytic ionized water generating device is to produce alkaline ionized water and acidic ionized water by electrolyzing tap water, and as shown in Figure 1, a pair of flat plate type to form a positive electrode (+) and a negative electrode (-) The electrodes 11 and 12 are arranged at regular intervals, and the ion exchange membranes between the electrodes 11 and 12 are formed to isolate the electrodes 11 and 12 to form the anode chamber 11a and the cathode chamber 12a. 13) having an electrolyzer 10, and connecting the electrolyzer 10 to a faucet through a specific pipe (not shown) to supply tap water therein, and then to the electrolyzer 10 The electrolysis of the electrolyte in the water moves water from the + electrode to the-electrode, taking water containing alkali ions (+ ions) from the cathode chamber 12a, and water containing acidic ions (− ions). Configured to take on (11a) .

In addition, in the conventional electrolytic ion water generating apparatus as described above, since a scale such as alkali hydroxide is attached to the cathode surface during electrolysis operation, the ionization efficiency is lowered. Reverse scale to reverse scale to remove scale.

However, in the conventional electrolytic ion water generator as described above, since the diaphragm pore size of the ion exchange membrane 13 is generally 0.4 to 1 μ, 100% microorganisms of 0.02 μ size in the tap water are not sterilized and filtered. There is a disadvantage.

Particularly, in the conventional electrolytic ion water generator as shown in FIG. 1, the pair of flat electrodes 11 and 12 forming the positive electrode (+) and the negative electrode (−) are parallel to the same length with each other in the electrolytic cell 10. Since it is immersed in the upper part, the electrolysis phenomenon is concentrated only in the upper part of the electrolytic cell 10, so that the pH of the ionized water is limited to approximately 3.5 to 10.5 range, and in particular, strong acidic ionized water of pH-1 and strong alkaline ionized water of pH-14 are produced. There is a drawback to not doing it.

In addition, the plate-shaped electrodes 11 and 12 are formed to be parallel to the same height on the top of the electrolytic cell 10, so that 10 ions are generated from the + electrode during the electrolysis process and move to the -electrode. It can also receive only 10 ions, which makes it impossible to produce better ionized water.

In addition, in order to make a strong acidic ionized water is conventionally made by adding a large amount of chemicals, the strong acidic water produced in the process has a bad effect on the human body due to problems such as microorganisms are not completely sterilized treatment effect is There is a problem that is not high.

The present invention is to solve the above-mentioned conventional problems, an object of the present invention is a pair of anode electrodes of the same length disposed on the outer circumferential surface of the ocher tube and the ocher tube forming an ion exchange membrane of a predetermined thickness, and the ocher Electrolyzed ionized water which is disposed inside the tube and is fed with a seaweed water and tap water made by processing seaweed into an electrolytic cell having a cathode electrode rod 2.5 times larger than the length of the anode electrode, and then electrolyzed to generate acidic and alkaline ionized water. The present invention provides an apparatus and a method thereof.

Another object of the present invention is that the seaweeds and tap water supplied to the electrolyzer collide with the ocher tube in the process of electrolysis, and the microorganisms of 0.02μ size are naturally extinguished, and the seaweeds and tap water penetrated into the ocher tube rapidly enter the human body. The present invention provides an electrolytic ion water generating device and a method for absorbing the same.

Still another object of the present invention is to provide an electrolytic ionized water generating device and method for obtaining strong acidic ionized water of pH-1 and strong alkaline ionized water of PH-14 using natural materials.

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

2 and 3, the electrolyzer 20 is connected to a water tank (not shown) and a faucet in which the seaweed water is stored through a specific pipe (not shown) and receives the water and the tap water.

The electrolyzer 20 includes a certain amount of ganban rock and mica that is attached to the bottom surface when the seaweed water is connected to the stored water tank through a specific pipeline (not shown).

For example, after putting 1 kg of seaweed into 10 liters of water to produce a seaweed water for 5 hours, and then supplying the seaweed water to the electrolytic cell 20, the ganban stone and mica is 3g and 2g respectively by the electrolyzer 20 Is laid on the bottom surface.

For reference, the seaweed used in the present invention to generate acidic ionized water (SALICORNIA HERBACEA L.) is a plant called 'Tung-bark' in Korean, including salt dissolved in seawater, calcium, magnesium, potassium, iron, phosphorus and the like. It grows while absorbing the same kinds of minerals, and grows in groups in the west coast, south coast of Korea, the coast of the island province, and around the sea pearls and salt fields. In particular, the seaweed contains seven times more calcium than milk, 40 times more iron than seaweed or kelp, and three times more potassium than oysters. In addition, it contains more than 90 minerals in seawater. In addition, it is well known that seaweed has excellent effects on indigestion, gastrointestinal disease, hepatitis, nephritis, various cancers, sinusitis, arthritis, hypertension, hypotension, low back pain, obesity, hemorrhoids, diabetes, thyroid, asthma, bronchitis.

Also, as already known, elvan has the effect of adsorbing / decomposing contaminants, heavy metals, etc., and eluting more than 40 kinds of minerals that give vitality to the human body. However, strong alkaline water is adjusted to weak alkaline (pH7.2 ~ 7.4) and the water quality is activated to purify the water. Especially, when immersed in water, COD (chemical oxygen demand) and BOD (biological oxygen demand) are lowered. Gives vitality to the living body.

In addition, mica is widely used as an insulating material and a fireproof material.

The ocher tube 21 is fixedly installed at the center of the electrolytic cell 20, forms an ion exchange membrane of a predetermined thickness (for example, 2 cm), and retains the sterilization characteristics of the loess.

The pair of positive electrode electrodes 22 have the same length and are fixedly disposed on the outer circumferential surface of the ocher tube 21.

The cathode electrode 23 is fixedly disposed at the center portion of the inside of the ocher tube 21, and its length is 2.5 times longer than the length of the anode electrode.

When electrolysis occurs through the anode electrode 22 symmetrically formed on the outer circumference of the ocher tube 21, the sea water or tap water moving from the + electrode to the-electrode is negative electrode rod 23 if the first 10 ions are generated from the + electrode. As it moves to), 25 ions are generated like the ratio of 2.5: 1, so the body's absorption is quick and high reducing power is generated.

The ionized water tank 24 is ionically coupled to the upper circumferential surface of the top of the ocher tube 21 in a state where the ionized water discharge pipe 24a is formed on one side, and the ionized water generated by electrolyzing the seaweed water and the tap water supplied to the electrolytic cell 20. Is ejected through the top of the ocher tube 21 is collected.

The power supply device 25 is a 50 to 100V DC power source for generating acidic ionized water and alkaline ionized water by electrolyzing the water containing water and the tap water contained in the electrolytic cell 20 in the anode electrode 22 and the cathode electrode 23. To supply.

The pH of the acidic ionized water and the alkaline ionized water produced by electrolyzing the grass and the tap water is determined by the supply time and supply voltage of the DC power supply of the power supply device 25.

The electrolytic ionized water generating device according to the present invention configured as described above operates as follows to generate acidic ionized water and alkaline ionized water.

Referring to FIG. 5, a method of generating acidic ionized water with the electrolytic ionized water generating device according to the present invention will be described in detail.

Firstly, 1 kg of seaweed is added to 10 l of water and soaked for 5 hours to produce a seaweed water (S10), and then the seaweed water is supplied to the electrolytic cell 20 in which 3 g of ganganite and 2 g of mica are laid on the bottom surface. (S12).

Next, a pair of anode electrodes 22 having the same length fixedly disposed on an outer circumferential surface of the ocher tube 21 fixedly installed at the central portion of the electrolytic cell 20 and a fixed portion disposed at the center of the ocher tube 21 are fixed to the anode. 50 to 100 V of DC power is supplied to the cathode electrode rod 2.5 times longer than the length of the electrode 22 for about 15 to 20 minutes to cause the electrolytic action of the anode electrode 22 and the cathode electrode 23.

Accordingly, the seaweed ions of the electrolytic cell 20 are penetrated into the ocher tube 21 to form an ion exchange membrane having a thickness of 2 cm, and sterilized while fine bacteria having a size of 0.02 μ collide with the anti-tubule 21. Acidic ionized water in a range of ≤ pH <7 is generated (S14).

Finally, when the acidic ionized water generated inside the ocher tube 21 is ejected through the upper part of the ocher tube 21, the extracted acidic ionized water is collected in the ionized water tank 24 (S16), the ionized water tank It is discharged to the outside through the ionized water discharge pipe (24a) formed on one side of (24).

Strong acidic ionized water (pH-1) made by the above method is used as a disinfectant for medical field or various skin disease treatments, and because it is made of natural materials, unlike strong acidic ionized water made with chemicals, many features There is this.

Looking at the features,

First, it is harmless to human body.

Second, microscopic bacteria of 0.02μ size collide with the ocher tube and naturally disappear as it penetrates into the ocher tube and can be completely sterilized.

Third, the water penetrating into the ocher tube is quickly absorbed by the human body due to the fine particles of water, and it is possible to treat quickly by suffocating the bacteria breeding in the human body.

Fourth, the strong acidic ionized water can be used in medicine, agriculture, industrial, fisheries, and the like. In particular, it can be used as a cement diluent because the strength can be increased when applied to cement, etc., to reduce the oxygen content.

Referring to FIG. 6, a method of generating drinkable alkaline ionized water with the electrolytic ionized water generating device according to the present invention will be described in detail.

First, a suitable amount of tap water is supplied to the electrolytic cell 20 (S20), and then a pair of positive electrode rods 22 having the same length fixedly disposed on the outer circumferential surface of the ocher tube 21 fixedly installed at the center of the electrolytic cell 20. And a 50 to 100 V DC power supply for about 15 to 20 minutes to a cathode electrode rod fixed to a central portion inside the ocher tube 21 and 2.5 times longer than the length of the anode electrode 22. 22) and the cathode electrode 23 causes electrolysis.

Accordingly, while the tap water ions of the electrolytic cell 20 penetrate into the ocher tube 21 forming an ion exchange membrane having a thickness of 2 cm, fine bacteria having a size of 0.02 μ collide with the anti-tubule 21 to be sterilized. Alkaline ionized water of pH ≤ 14 is produced (S22). In particular, tap water ions submerged in the ocher tube 21 have a large amount of antioxidant oxygen dissolved oxygen in the form of fine particles (fog) in the cathode electrode rod 23, which is rapidly absorbed in the body. Produced from small water molecules.

Finally, when the alkaline ionized water generated inside the ocher tube 21 is ejected through the upper part of the ocher tube 21, the ejected alkaline ionized water is collected in the ionized water tank 24 (S24), and the ionized water tank It is discharged to the outside through the ionized water discharge pipe (24a) formed on one side of (24).

Referring to FIG. 7, a method of generating drinkable alkaline ionized water with the electrolytic ionized water generating device according to the present invention will be described in detail.

First, 5 liters of water was added to 1 kg of agitated soil, followed by stirring, to produce a clear jijisu, which was settled after 5 hours (S30), and then 1kg of seaweed was added to 10 liters of jijisu, which was then inhaled for 30 minutes to produce a seaweed water (S32). It supplies to 20 (S34).

A pair of positive electrode rods 22 having the same length fixedly disposed on an outer circumferential surface of the ocher tube 21 fixedly installed at the central portion of the electrolytic cell 20 and fixed to a central portion inside the ocher tube 21 are fixed to the anode electrode 22. 50 to 100 volts of DC power is supplied to the cathode electrode rod 2.5 times longer than the length of the N-pole, and the electrolytic action of the anode electrode 22 and the cathode electrode 23 is caused.

Accordingly, while the tap water ions of the electrolytic cell 20 penetrate into the ocher tube 21 forming an ion exchange membrane having a thickness of 2 cm, fine bacteria having a size of 0.02 μ collide with the anti-tubule 21 to be sterilized. Alkaline ionized water of pH ≤ 14 is generated (S36). In particular, tap water ions submerged in the ocher tube 21 have a large amount of antioxidant oxygen dissolved oxygen in the form of fine particles (fog) in the cathode electrode rod 23, which is rapidly absorbed in the body. Produced from small water molecules.

Finally, when the alkaline ionized water generated in the ocher tube 21 is ejected through the upper part of the ocher tube 21, the ejected alkaline ionized water is collected in the ionized water tank 24 (S38), and the ionized water tank It is discharged to the outside through the ionized water discharge pipe (24a) formed on one side of (24).

Alkaline ionized water made by the process as described above can make better alkaline ionized water than made using tap water, is easy to absorb the human body, it is effective in the treatment of diseases caused by structural modification of cells.

Electrolytic ionized water generating apparatus to which the electrolytic ionized water generating method according to the present invention is applied as described above, a pair of anode electrodes of the same length disposed on the outer peripheral surface of the ocher tube and the ocher tube forming an ion exchange membrane of a predetermined thickness, and the ocher After supplying the seaweed material made by processing the seaweed to the electrolytic cell disposed inside the tube and having a cathode electrode rod 2.5 times larger than the length of the anode electrode, the seaweed water was electrolyzed by a DC power source of 50 to 100V. The acidic water contained in the electrolyzer was permeated into the ocher tube forming a 2 cm thick ion exchange membrane to produce sterilized acidic ionized water in the range of 1 ≤ pH <7, and the tap water was supplied to the electrolyzer after supplying tap water. Electrolysis with a DC power supply of ˜100 V causes the tap water ions of the electrolytic cell to penetrate into the ocher tube, forming an ion exchange membrane having a thickness of 2 cm While generating sterilized alkaline ionized water in the range of 7 <pH ≤ 14, the conventional electrolytic ionized water generator can not only solve the disadvantage of not generating strong acidic ionized water of pH-1 and strong alkaline ionized water of pH-14, Fully sterilized, clear and clean than distilled water can be used as drinking water of high quality ionic water quickly absorbed by the human body, the present invention can be used in medicine, agriculture, industry, fisheries, and the like.

For example, the acidic ionized water according to the present invention can be used as a disinfectant for medical treatment or various skin diseases, and can be used as a cement diluent to increase cement strength by reducing the oxygen content of the industrial field.

What has been described above is just one embodiment for carrying out the electrolytic ion water generating apparatus and method thereof according to the present invention, and the present invention is not limited to the above-described embodiment, but the present invention as claimed in the following claims Without departing from the gist of the present invention, one of ordinary skill in the art will have the technical spirit of the present invention to the extent that various modifications can be made.

Claims (6)

An electrolytic cell connected to a water tank (not shown) and a faucet in which the seaweed water is stored through a specific pipe line (not shown) and supplied with the water and the tap water; An ocher tube fixed to a central portion of the electrolytic cell and forming an ion exchange membrane having a thickness of 2 cm; A pair of anode electrodes of the same length fixedly disposed on an outer circumferential surface of the ocher tube; A cathode electrode rod fixed to a central portion inside the ocher tube and having a length 2.5 times longer than a length of the anode electrode; An ionized water tank sealedly coupled to the upper outer circumferential surface of the ocher tube in a state where an ionized water discharge tube is formed at one side, and ionized water generated by electrolyzing the seaweeds and tap water supplied to the electrolytic cell is collected through the upper part of the ocher tube; A power supply device for supplying a DC power supply of 50 ~ 100V for generating acidic ionized water and alkaline ionized water by electrolyzing the containing water and tap water contained in the electrolytic cell to the positive electrode and the negative electrode Electrolytic ionized water generating device, characterized in that consisting of. delete delete Putting 1 kg of seaweed into 10 liters of water and stirring for 5 hours to produce a seaweed water; Supplying the seaweed water to an electrolytic cell on which 3g of ganbanite and 2g of mica are laid on the bottom surface; A pair of positive electrode rods having the same length fixedly disposed on the outer circumferential surface of the ocher tube fixed to the center of the electrolytic cell and a cathode electrode rod fixed to the central portion of the inside of the ocher tube and 2.5 times larger than the length of the anode electrode have a 50 to 100 V A DC power supply was applied to cause the electrolytic action of the positive electrode and the negative electrode, so that the water containing ions of the electrolytic cell penetrated into the ocher tube forming an ion exchange membrane having a thickness of 2 cm, and sterilized in an acid range of 1 ≤ pH <7 Generating ionic water; Collecting the acidic ionized water ejected through the upper portion of the ocher tube in the ionized water tank Electrolytic ionized water generation method characterized in that consisting of. Supplying tap water to the electrolytic cell; A pair of positive electrode rods having the same length fixedly disposed on the outer circumferential surface of the ocher tube fixedly installed at the center of the electrolytic cell and 50 to 100 V on the negative electrode electrode fixedly disposed at the central portion inside the ocher tube and 2.5 times larger than the length of the anode electrode. Supplying a DC power supply to cause the electrolytic action of the positive electrode and the negative electrode electrode so that the tap water ions of the electrolytic cell is permeated into the ocher tube forming an ion exchange membrane of 2 cm thickness, sterilized alkali <7 <pH ≤ 14 Generating ionic water; And Collecting alkaline ionized water ejected through the upper part of the ocher tube in an ionized water tank Electrolytic ionized water generation method characterized in that consisting of. Jijisu generating step of producing clear water, which was settled after 5 hours after stirring and adding 5kg of soil 1kg; Putting 1 kg of seaweed into 10 liters of Jijangsu and boiling it for 30 minutes to produce a seaweed water; Supplying the seaweed water to the electrolytic cell; A pair of positive electrode rods having the same length fixedly disposed on the outer circumferential surface of the ocher tube fixed to the center of the electrolytic cell and a cathode electrode rod fixed to the central portion of the inside of the ocher tube and 2.5 times larger than the length of the anode electrode have a 50 to 100 V Alkaline ionized water in the range of 7 <pH ≤ 14 that was sterilized while supplying a DC power to cause electrolysis of the positive electrode and the negative electrode, while the tap water ions of the electrolytic cell penetrated into the ocher tube forming an ion exchange membrane having a thickness of 2 cm Generating a; And Collecting alkaline ionized water ejected through the upper part of the ocher tube in an ionized water tank Electrolytic ionized water generation method characterized in that consisting of.

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