KR20030037063A - A water parifier using electrolysis - Google Patents

Abstract

PURPOSE: An electrolytic water purifier is provided, which can steadily produce three kinds of electrolytic water of various activations regardless of influent water quality, and of these activated hydrogen rich weak alkali water used as drinking water can remove activated oxygen that is the causative agent of all disease of human efficiently. CONSTITUTION: In the usual electrolytic water purifier including electrolytic part and water purifying part, the electrolytic water purifier comprises a primary electrolysis part(10) constituted by two electrode chambers(11,12) of positive electrode plate(11) and negative electrode plate(12) by an ion separation membrane for separating the influent water into alkali water and acidic water; a secondary electrolysis part(20) constituted by three electrode chambers(21,22,23) of one positive electrode(21) and two negative electrodes(22,23) by two membranes(24,25) for separating the influent alkali water produced at the primary electrolysis part(10) into strong alkali water, weak alkali water and acidic water.

Description

A water parifier using electrolysis

The present invention is to provide a weak alkaline water rich in "active hydrogen" which removes "active oxygen" which is a source of all diseases in the human body by electrolysis of water twice, so that it can be stably provided regardless of the quality of the influent. It relates to one electrolytic water purifier.

"Active oxygen," the source of all diseases, means active oxygen, that is, oxygen that is particularly strong in oxidation, and by this particularly strong oxidation, the body's cells or genes are oxidized to cause various diseases.

However, while these "active oxygen" are oxidized by oxygen to produce the substances and energy necessary to sustain life, oxygen is reduced by food to become "active oxygen", so it is continuously generated in the human body. Will be.

Therefore, in order to remove the "active oxygen" that is continuously generated in the human body, it is necessary to provide the human body with sufficient "reactive hydrogen" with excellent reducing effect. Such "active hydrogen" can be obtained from alkaline water obtained by electrolysis of water.

Therefore, a water purifier was introduced to provide a weak alkaline water of pH 7.4 to 8.5 for drinking water by electrolyzing water. The conventional structure of the water purifier includes a water purifying part and an electrolytic part. One anode electrode plate 1 and two cathode electrode plates 2 and 3 are provided between the three diaphragms 4 and 5 to allow only the movement of ions contained in the water. As a result, strong alkali water (pH 9-10) and weak alkali water (pH 7.4-8.5) are generated from the two cathode electrode chambers, and electrolytic ion water of acidic water (pH 4-5) is produced from the anode electrode chamber. Among them, the drinkable weak alkaline water is to be used as drinking water.

In the reaction of water, anions such as chlorine, sulfuric acid, and sulfur move to the positive electrode plate 1 and are discharged together with the positive electrode electrolytic water, and at the same time, hydroxyl ions OH ^_ Since the oxidation reaction takes place and becomes the oxygen molecule (O ₂ ), the anode electrolyzed water discharged at this time becomes hydrogen acid and becomes acidic.

On the other hand, cations, minerals such as calcium, magnesium, and potassium contained in the water, are transferred to the cathode electrode plates (2) and (3), discharged, and then dissolved again in water to be discharged together with the cathode electrolyzed water and at the same time, hydrogen (H ⁺ ) Electrons (e-) are generated at the cathode to generate "active hydrogen," so that the discharged cathode electrolytic water has a lower hydrogen ion (H ⁺ ) concentration than normal water and becomes alkaline and a redox potential.

However, the conventional water purifier having such a structure electrolyzes the water only once in generating three kinds of electrolytic ion water (strong alkaline water, weak alkali water and acidic water), so that the concentration of hydrogen ions near the cathode depends on the nature of the water introduced therein. There was a problem that, without standing, the cation was not sufficiently removed and the redox potential was difficult to be lowered, so that weak alkaline water rich in "active hydrogen" could not be obtained stably.

Therefore, the water purifier of the present invention is devised to solve the above-mentioned conventional problems, and an object of the present invention is to stably obtain a weak alkaline water rich in "active hydrogen" regardless of the quality of the influent.

To this end, two electrolytic units, each of which is different from each other, are separated into alkaline water and acidic water in the two electrode chambers in the first electrolytic unit, and the electrolyzed alkaline water generated in the primary electrolytic unit is once again electrolyzed in the secondary electrolytic unit. It is intended to provide weak alkaline water, which is more enriched with hydrogen, as drinking water, and to provide strongly alkaline water for washing and acidic water for washing.

1 is a cross-sectional view showing the structure of the present invention water purifier.

2 is a partial cross-sectional view showing a primary electrolytic part of the water purifier of the present invention.

Figure 3 is a partial cross-sectional view showing a secondary electrolytic portion of the water purifier of the present invention.

Figure 4 is a sectional view showing another structure of the present invention water purifier.

5 is a flow chart showing the electrolytic ion water generation process of the water purifier of the present invention.

6 is a cross-sectional view showing the structure of a conventional water purifier.

Explanation of symbols on the main parts of the drawing

10: Primary dissection

11: (+) electrode plate 12: (-) electrode plate

13, 14: diaphragm 16: primary electrolyte inlet

17: acidic water outlet 18: secondary electrolyte inlet

20: Secondary dissection

21: (+) electrode plate 22, 23: (-) electrode plate

24, 25: diaphragm 27: face-water outlet

28: washing water outlet 29: drinking water outlet

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

1 is a cross-sectional view of an embodiment of the present invention, which is composed of an electrolytic part for generating electrolytic ionized water by electrolyzing water and a purified part for removing foreign substances or organic matter, rust, chlorine, odor, etc. in water. In the electrolytic water purifier, the first electrolytic part 10 and the alkaline water generated in the first electrolytic part 10 for generating alkaline water and acidic water are electrolyzed once again to form strong alkaline water, weak alkaline water, and acidic water. Secondary electrolytic section 20 is provided to generate.

At this time, the primary electrolytic unit 10 of the electrolytic unit is provided with one (+) electrode plate 11 and (-) electrode plate 12, respectively, the ion separation that can pass only ions contained in the water therebetween The diaphragm 14 is installed to provide two electrode chambers, and the secondary electrolytic unit 20 is provided with one (+) electrode plate 21 and two (-) electrode plates 22 and 23. Two diaphragms 24, 25 are respectively provided between the electrode plates 21, 22, 23, and three electrode chambers are provided.

In addition, the water purification unit is equipped with various filters 30 used to remove foreign substances or organic matter, rust, chlorine, odors, etc. of the inflow water, and is installed in front of the electrolytic unit 1 before the electrolysis of water The purified water is to be formed, or it can be installed at the rear stage, or can be installed at the front and rear stages as necessary.

Therefore, the production process of the electrolytic ion water obtained from the electrolytic water purifier of the present invention can be described as follows.

First, when the water purified by the purified water unit 2 flows into the primary electrolytic unit 10 through the inlet 16 of the primary electrolytic unit 10, the positive electrode plate 11 and the negative electrode plate 12 Power is supplied to the first electrode chamber between the positive electrode plate 11 and the diaphragm 14, and acidic water is generated and discharged to the acidic water outlet 17, and the diaphragm 14 and the negative electrode plate. Alkaline water is generated in the second electrode chamber between the 12 and discharged to the inlet 18 of the secondary electrolytic unit 20.

Thereafter, alkaline water introduced into the inlet 18 of the secondary electrolytic unit 20 is supplied with power to the (+) electrode plate 21 and the (-) electrode plate 22 and 23 to supply the (+) electrode plate 21. ) Between the diaphragm and the diaphragm 24, acidic water is generated, joined with the acidic water generated in the primary electrolytic unit 10, and discharged to the face-wash water discharge port 27, and the diaphragm 24 and the (-) electrode plate 22. Strong alkaline water is generated between the electrode plate 22 and the diaphragm 25 and discharged to the washing water outlet 28, and the weak alkali water is supplied to the third electrode chamber between the diaphragm 25 and the negative electrode plate 23. It is generated and discharged to the drinking water outlet (29).

At this time, the three electrolytic ionized water (strong alkaline water, weak alkaline water, acidic water) have different effects as follows.

First, in the first electrode chamber including the (+) electrode plate 11 of the primary electrolytic unit 10, anions such as chlorine, sulfuric acid, and sulfur existing in the water are collected, and hydroxyl ions (OH-) are ( +) (11) deprives electrons and oxidizes them into oxygen molecules (O ₂ ), so the hydrogen ion concentration becomes high and the water becomes acidic. This acidic water is used for cleansing as it has sterilizing and skin-converging effect. Will be done.

In addition, in the second electrode chamber including the negative electrode 12 of the primary electrolytic unit 10, cations which are mineral components such as calcium, magnesium, and potassium present in water are collected, and hydrogen ions (H ⁺ ) are ( Electrons (e-) are generated in-) (12) to produce "active hydrogen", the concentration of hydrogen ions (H ⁺ ) is lowered into alkaline water, the redox potential (ORP) is lowered, and the water is sterilized. It is to act.

At this time, the alkaline water generated in the second electrode chamber and containing the "active hydrogen" is sent to the secondary electrolytic unit 20, so that in the third electrode chamber including the (-) 23 which is far from the (+) 21, The cations which are mineral components such as calcium, magnesium, potassium, etc. present in the water are collected, and hydrogen ions (H ⁺ ) are obtained by electrons (e-) in the ?? electrode plate 23 to generate "active hydrogen" again. A higher amount of "active hydrogen" can be obtained than in the second electrode chamber, as well as a lower redox potential (ORP), and hydrogen ion (H ⁺ ) concentration of pH 7.4-8.5 It will be used as drinking water.

In addition, in the fourth electrode chamber including the negative (-) (22) close to the distance (+) (21), cations which are mineral components such as calcium, magnesium, and potassium present in the water are collected, and hydrogen ions (H ⁺ ) By generating electrons (e ??) from this (-) (22), "active hydrogen" is also generated, resulting in more "active hydrogen" than the second electrode chamber, lower redox potential (ORP), and sterilization. It is effective, and the hydrogen ion (H ⁺ ) concentration becomes a strong alkaline water of pH 9-10 grade to be used for washing.

In addition, since the acidic water is generated in the fifth electrode chamber including the positive electrode plate 21 by the same reaction as the first electrode chamber, the acidic water generated in the first electrode chamber is used for washing. will be.

Therefore, the water purifier according to the present invention can firstly electrolyze alkaline water containing "active hydrogen" once more to obtain alkaline water richer in "active hydrogen". The weak alkaline water is to be provided as drinking water, the strong alkaline water can be used for washing, and the acidic water is to be used for washing according to different effects.

In addition, by electrolysis twice, the water purification effect of the two sterilization action is also excellent.

On the other hand, Figure 4 shows another structure of the present invention, between the (+) electrode plate 11 and the (-) electrode plate 12 by additionally installing a diaphragm 13 in the primary electrolytic portion (10) Two diaphragms 13 and 14 are positioned in the air, and the neutral water flowing out between the diaphragms 13 and 14 is introduced into the inlet 18 of the secondary electrolytic unit 20 to perform secondary electrolysis. It is to be applied in the region where the high hardness water should be used as the inflow water of the present invention, the (+) electrode plate 11 and the (-) electrode plate 12 has to change the polarity at regular intervals. Of course.

For this reason, when the inflow water is hard water, a large amount of ionic material contained in the water is adhered to the (+) electrode plate 11 and the (-) electrode plate so that the electrolytic action due to overcurrent is stopped. This is because the operation of the invention water purifier is inhibited.

At this time, instead of installing the diaphragm 14, even if the ion exchange part filled with ion exchange resin in the inlet 16 of the water purifier can be obtained the same effect that can be used as hard water.

The water purifier of the present invention can generate electrolytic ionized water of three different functions regardless of the quality of the influent, and among these, weak alkaline water used as drinking water is particularly rich in "active hydrogen", which causes all diseases in the human body. Removal of the substance "active oxygen" is an excellent effect.

Claims (5)

In a conventional electrolytic water purifier composed of an electrolytic part and a water purifying part, an electrode chamber provided with one (+) electrode plate and a (-) electrode plate is installed so that water flowing into the inlet of the electrolytic part is separated into alkaline water and acidic water. One positive electrode plate formed of two electrode chambers by a separation diaphragm and only alkaline water generated in the primary electrolytic part and separated into three electrolytic ionized waters, strong alkaline water, weak alkaline water and acidic water. And a secondary electrolytic part in which an electrode chamber in which two (-) electrode plates are installed is formed of three electrode chambers by two ion separation membranes. The method according to claim 1, wherein an additional diaphragm is provided in the primary electrolytic plate so that two diaphragms are positioned between the (+) electrode plate and the (-) electrode plate, and the neutral water flowing out between the two diaphragms is secondary. Electrolytic water purifier configured to enter the inlet of the electrolytic unit. The electrolytic water purifier of claim 1 or 2, wherein the weak alkaline water generated in the secondary electrolyte is discharged to a drinking water outlet. The electrolytic water purifier according to claim 1 or 2, wherein the acidic water generated in the primary electrolytic unit is combined with the acidic water discharged from the secondary electrolytic unit and discharged to the face-wash water outlet. The electrolytic water purifier according to claim 1 or 2, wherein the strong alkaline water generated in the secondary electrolytic unit is discharged to the washing water outlet.