JP2001334271A - Method for making acidic water and alkaline water - Google Patents

Abstract

PROBLEM TO BE SOLVED: To solve the point at issue such that hypochlorous acid and chlorine gas are generated in a conventional method for making acidic water and alkaline water to exert a bad influence upon environment. SOLUTION: An electrolytic cell 2 filled with tap water 40 is demarcated into an acidic water forming region 5 and an alkaline water forming region 6 by an ion exchange membrane 3 and a predetermined amount of a nonmetal mineral is charged in the acidic water forming region 5 while a predetermined amount of a silicate mineral 60 is charged in the alkaline water forming region 6 and the anode rod 24 of a DC voltage applying device 20 is arranged in the acidic water forming region 5 and the cathode rod 26 of the DC voltage applying device 20 is arranged in the alkaline water forming region 6 and voltage is applied across the anode and cathode rods 24, 26 not only to modify tap water 40 to acidic water in the acidic water forming region 5 but also to modify tap water 40 to alkaline water in the alkaline water forming region 6.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a natural mineral which is produced by modifying water such as tap water into strongly acidic water and alkaline water using a naturally occurring mineral without performing chemical treatment, electrolysis and the like. The present invention relates to a method for producing strongly acidic water and alkaline water.

[0002]

2. Description of the Related Art To obtain acidic water, refer to Japanese Patent Application No. 63-517.
As proposed in Japanese Patent Application No. 65 and Japanese Patent Application No. 63-49861, the inside of the electrolytic layer is divided into two chambers by a diaphragm, electrodes are provided in both chambers, and these electrodes are connected to a DC power supply to form an anode chamber. And a cathode chamber are formed, and tap water containing salt (sodium chloride) or the like as an electrolytic agent is supplied to the anode chamber and the cathode chamber, and the tap water is electrolyzed to generate acidic water from the anode chamber. It was done by letting. In addition, alkaline water is generated from the cathode chamber.

[0003]

However, in the above-mentioned conventional method for producing acidic water and alkaline water, toxic substances such as hypochlorous acid and chlorine gas are generated due to the electrolytic treatment, and the environmentally friendly water is produced. Adversely affect
In order to remove toxic substances such as hypochlorous acid and chlorine gas, there is a problem that a removing device is required and the production cost is relatively high.

The present invention has been made in view of the above problems, and an object of the present invention is to produce a large amount of strongly acidic water and alkaline water by generating hypochlorous acid and chlorine gas. It is an object of the present invention to provide a method for producing acidic water and alkaline water, which can be produced without causing any adverse effects on the environment and at a low production cost.

[0005]

Means for Solving the Problems To achieve the above object, a method for producing acidic water and alkaline water according to the present invention comprises disposing an anode in an acidic water producing region and a cathode in an alkaline water producing region. A voltage is applied to the electrolytic solution filled in the acidic water generating region and the alkaline water generating region, and the acidic water is generated in the acidic water generating region by ion exchange and the alkaline water is generated in the alkaline water generating region. A method for producing water and alkaline water, wherein an electrolytic solution elutes an ionic substance from a nonmetallic mineral and a silicate mineral into raw water by introducing a nonmetallic mineral and a silicate mineral into the raw water as an electrolytic agent. It is generated.

[0006] Therefore, to reform raw water such as tap water by using naturally occurring non-metallic minerals and silicate minerals in strongly acidic water and alkaline water without generating hypochlorous acid and chlorine gas. Therefore, a large amount of strongly acidic water can be produced at low cost without adversely affecting the environment, and the production cost can be reduced without adversely affecting the environment.

In order to achieve the above object, the method for producing acidic water and alkaline water according to the present invention is characterized in that a tank filled with tap water is sandwiched between an acidic water producing zone and an alkaline water by an ion exchange means. And an anode of the voltage application means in the acidic water generation area, and a cathode of the voltage application means in the alkaline water generation area, and a predetermined amount of nonmetallic mineral is charged into the acid water generation area. , A predetermined amount of silicate mineral is introduced into the alkaline water generation area, ionic substances are eluted into tap water, tap water is reformed into an electrolytic solution, a voltage is applied to the anode and the cathode, and ions are ion-exchanged by ion exchange means. Exchange is performed to increase the hydrogen ion concentration in the acidic water generation region, so that acidic water is generated in the acidic water generation region and alkaline water is generated in the alkaline water generation region.

Preferably, the nonmetallic mineral is a fossil earth, and the silicate mineral is a tuff.

Therefore, when a voltage is applied to the anode and the cathode by driving the voltage applying means and an electric current is passed through the tap water as the electrolytic solution, the ionic substances eluted from the silicate mineral in the alkaline water producing region are negatively affected. The ionic substances move to the acidic water generation area by the ion exchange means to increase the hydrogen ion concentration, and the cation substances among the ionic substances eluted from the nonmetallic mineral in the acidic water generation area are converted to the alkaline water generation area by the ion exchange means. Then, the tap water in the acidic water generation area is reformed into strongly acidic water, and the tap water in the alkaline water generation area is reformed into alkaline water.

[0010] As described above, tap water is produced from naturally occurring nonmetallic minerals (fossil earths) and silicate minerals (tuff) to generate hypochlorous acid and chlorine gas in strongly acidic water and alkaline water. Since the reforming can be performed without causing any adverse effects on the environment, a large amount of strongly acidic water can be produced at low cost.

[0011]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a perspective view of a production facility used in the method for producing acidic water and alkaline water according to the present invention.

[0013] The production equipment 1 shown in FIG. 1 is used in the method for producing strongly acidic water and alkaline water using natural minerals. The manufacturing equipment 1 includes an electrolytic cell (layer) 2 composed of a glass container, a water supply device 10, and a DC voltage application device 2 serving as a voltage application means.
0.

The inside of the electrolytic cell 2 is divided into an acidic water generation area 5 and an alkaline water generation area 6 by a partition wall 4 having an ion exchange membrane 3 as an ion exchange means. The ion exchange means is not limited to the ion exchange membrane 3, but may be a plate-like porous ceramic or the like.

The water supply device 10 has a supply pipe 11 for tap water. The supply pipe 11 has one and the other branch pipes 12 and 13, each of which is branched. The opening part faces the area 5 above, and the other branch pipe 13 faces the opening part above the alkaline water generation area 6.

The electrolytic cell 2 is provided with a take-out pipe 14 for taking out acidic water from the acidic water generation area 5 and a take-out pipe 15 for taking out alkaline water from the alkaline water generation area 6.

The DC voltage applying device 20 includes a DC voltage generating device (battery) 21 and the DC voltage generating device 2.
1, a positive electrode rod (anode) 24 connected to the positive electrode side by a lead wire 23; a negative electrode rod (cathode) 26 connected to the negative electrode side of the DC voltage generator 21 by a lead wire 25; 23. The positive electrode rod 24 is inserted in the acidic water generation area 5, and the negative electrode rod 26 is inserted in the alkaline water generation area 6.

Tap water 40, which is raw water, is supplied from the water supply device 10 into the acidic water generating region 5 and the alkaline water generating region 6, respectively. Earth) 50 and a silicate mineral (tuff) 60 in the alkaline water generation region 6 each having a water content of about 10%.

The tap water 40 has a conductivity of 100 μS / cm or more, a cation of a mineral component of 20 mg / · or more, a chloride ion of 30 mg / · or more, and a hardness of 50 or more.

The nonmetallic minerals (fossil earths) 50 are solidified diatom fossil soils and solidified cyanobacterial fossil soils.

Diatomaceous earth is a sedimentary soil of diatom shells.
It is a kind of algae floating in the sea and lakes. It is a single-celled plant that absorbs nutrients from water and absorbs silica to form a cell membrane. The fossil of this cell membrane is diatom shell. This diatom shell fossil forms microscopic independent cells of 0.1 micron to 10 microns, and its surface is covered with countless fine pores.
The diatomaceous earth is a silica-based nonmetallic mineral (fossil earth) containing substances containing hydrogen ions, sulfides, chlorides, and the like due to volcanic activity, crustal deformation, and the like when underground.

Cyanobacteria exist in a wide variety of species, such as urea and noctuid algae, are unicellular bodies that do not move on their own, live in free, massive, or filamentous colonies, and have no nucleus and no body. They propagate only by division. The cyanobacteria are fossilized and, when in the ground, are non-metallic minerals (fossil earths) containing hydrogen ions due to volcanic activity, crustal deformation, etc., and sulfides and chlorides.

These non-metallic minerals (fossil earths) 50 are
There are dozens of natural types, of which reddish brown and grayish black are used. The nonmetallic mineral (fossil earth) 50 has many sedimentary layers, and this nonmetallic mineral (fossil earth)
When 50 is left in water, water will enter through numerous fine holes on the surface, and the voids between the deposition layers will expand, and water will enter at that moment.

The composition of the nonmetallic mineral (fossil earth) 50 is as follows: silicon (silicic acid) 78% aluminum (aluminum oxide) 10% iron (iron oxide) 4.0% potassium (potassium oxide) 4.0% calcium (oxide Calcium) 2.0% Sulfur (sulfate) 1.0% Others contain trace amounts of copper, titanium, nickel, strontium, and rubinium.

The composition of the silicate mineral (tuff) 60 is about 78% of silicic acid, aluminum oxide 10%, sodium oxide 4%, potassium oxide 4%, iron oxide 1%, magnesium oxide 1%, calcium oxide 1%, a small amount of sulfur, titanium, Contains manganese, barium, zirconium, palladium and strontium.

As described above, the non-metallic mineral 50 and the silicate mineral 60 are added to the tap water 40 by adding the non-metallic mineral 50 and the silicate mineral 60 to the tap water 40 as an electrolytic agent.
The ionic substance elutes from 0, and the tap water 40 becomes an electrolyte solution (electrolyte solution).

Then, the DC voltage applying device 20 is driven to apply a voltage to the positive electrode rod 24 in the acidic water generating region 5 and the negative electrode rod 26 in the alkaline water generating region 6, so that tap water as an electrolyte solution is supplied. When an electric current is passed through 40, anionic substances eluted from the silicate mineral 60 in the alkaline water generation area 6 move to the acidic water generation area 5 by selective permeation of the ion exchange membrane 3, and increase the hydrogen ion concentration. In addition, the cations among the ionic substances eluted from the nonmetallic mineral 50 in the acidic water generation region 5 move to the alkaline water generation region side 6 by selective permeation of the ion exchange membrane 3, and The tap water 40 is reformed into strongly acidic water, and the tap water 40 in the alkaline water generation area 6 is reformed into alkaline water.

As described above, the tap water 40 is made up of the naturally occurring nonmetallic minerals (fossil earths) 50 and the silicate minerals (tuff) 6
0 can be used to reform strongly acidic water and alkaline water without generating hypochlorous acid and chlorine gas. Can be generated.

In this case, the relationship between the amount of tap water 40 and the DC voltage by the DC voltage applying device 20 is 0.5 m with respect to 10 liters (l) of tap water 40.
A 5 mA per 100 liters (l) of tap water 40 5 m per 1 kiloliter (Kl) of tap water 40
A: 0.5 A for 10 kiloliters (Kl) of tap water 40 5 A for 100 kiloliters (Kl) of tap water 40

The generation time of acidic water and alkaline water is as follows: acidic water, alkaline water, pH 6.0, pH 7.5, 6 hours, pH 4.5, pH 8.0, 12 hours, pH 3.5, pH 8.5, 18 hours. pH 2.6 pH 9.4 for 24 hours.

As described above, a large amount of strongly acidic water and alkaline water can be produced with a small DC voltage without generating hypochlorous acid and chlorine gas.

The results of analysis of acidic water and alkaline water obtained by modifying the tap water 40 as described above are shown below. The analysis of the acidic water and the alkaline water is an excerpt from a test result report commissioned to the Tokyo Food Association and the Tokyo Food Research Institute.

The content of the acidic water test inspection and results pH value ···················· 2.6 Electrical conductivity _(- μS / cm) ····· ··· 1100 Redox potential (ORP) · · · 450 Dissolved oxygen (DO) · · · · · · 19 Nitrate nitrogen and 1.6 Chloride ion (mg / l) ... 31 Sulfate ion (mg / l) ... 140 hardness (mg / l) 39 organic substances (potassium permanganate consumption mg / l 5.9 phosphorus) (Mg / l) 0.2 Copper (mg / l) 0 .14 zinc (mg / l) ... 0.10 Iron (mg / l) ... 5.6 Manganese (mg / l) ... 0.25 Calcium (mg / l) 10 Magnesium (mg / l) 3.6 Sodium (mg / l) 13 Chloroform (mg / l) 0.005 Dibromo Chloromethane (mg / l): less than 0.001 Bromodichloromethane (mg / l): 0.002 Bromoform (mg / l):・ ・ ・ ・ ・ ・ ・ ・ 0.017 Total trihalomethane (mg / l) ・ ・ ・ 0.024

The contents of alkaline water test inspection and results pH value ···················· 9.4 Electrical conductivity _(- μS / cm) ····· 550 Redox potential (ORP) 150 Dissolved oxygen (DO) 7.9 Nitrate nitrogen and chlorite nitrogen (mg / l) ... 1.7 Chloride ion (mg / l) ... 26 Sulfate ion (mg / l) 81 Hardness (mg / l) 19 Organic matter (potassium permanganate consumption mg / l ...)・ 7.6 Phosphorus (mg / l) ・ ・ ・ ・ ・ ・ less than 0.1 Copper (mg / l) ・ ・ ・ ・ ・ ・ ・..... 0.03 zinc (mg / l) 0.038 Iron (mg / l) 0.86 Manganese (mg / 70) 0.070 Calcium (mg / l) 6 Magnesium (mg / l) 1.8 Sodium (mg / l) 93 Chloroform (mg / l) ... 0.001 Dibromochloromethane (mg / l) ... <0.001 Bromodichloromethane (mg / l) ... <0.001 Bromoform (mg) / L) 0.002 Total trihalomethane (mg / l) 0.003

Next, a method of using (utilizing) acidic water (strongly acidic water) and alkaline water (strongly alkaline water) will be described.

The acidic water having a pH value of 4.0 or less is unemployed and odorless and suppresses the generation of plant and zooplankton.
In addition, it exerts an astringent effect. In addition, acidic water having a pH value of 2.7 or less kills most microorganisms and fungi and has a bactericidal effect. For example, E. coli and general bacteria are annihilated by about 10% of strongly acidic water. In addition, it can be used as washing and sterilizing water for raw vegetables and the like. In addition, it can be used as acidic hot spring water and sulfate ion hot spring, can be used as sterilizing water for neutral simple hot springs (artificial hot springs), and can be used as sterilizing water for swimming pools.

Further, acidic water having a pH value of 4.0 or less can suppress the generation of parasites, maggots, and the like in sewage water, and can be used in restaurants, hotels, restaurants, restaurants, napkins, dining tables, tables, It can be used for disinfection of tableware. In addition, users such as public facilities, public places, buses, and trains can use the paper napkins containing acidic water for sanitation, cleanliness, and sterilization.

Acidic water having a pH value of 4.0 or less can be used for disinfection of public and public toilets, disinfectant hairway for golf courses, insect repellents for greens, etc., and sterilization of various bacteria in sandboxes such as parks. Can be used as an agent.

Alkaline water having a pH value of 9.4 (alkali
Sodium water) can be used as an alkaline / sodium hot spring, and if iron and manganese are removed, it can be used as alkaline mineral water. In addition, for cooking rice, cooking, removing air,
It can be used as a vegetable boiler or as a soil improver that tends to be acidic in plant cultivation.

In the above-described embodiment, as the fossil soils, those obtained by solidifying diatom fossil sedimentary soils and those obtained by solidifying blue-green algae fossilized soils are used. It is sufficient if the fossil sedimentary soil is solidified.

[0041]

As described above, according to the method for producing acidic water and alkaline water according to the present invention, the voltage application means is driven to apply a voltage to the anode and the cathode, and the tap water as the electrolytic solution is used. When an electric current is passed through the anion, the ionic substances eluted from the silicate mineral in the alkaline water generation area move to the acidic water generation area by the ion exchange means to increase the hydrogen ion concentration, and in the acid water generation area, Among the ionic substances eluted from the non-metallic mineral, the cation substances move to the alkaline water generation area side by the ion exchange means, the tap water in the acidic water generation area becomes strongly acidic water, and the tap water in the alkaline water generation area becomes alkaline. Each is reformed into water.

As described above, tap water is produced from non-metallic minerals (fossil earths) and silicate minerals (tuff) which are naturally produced to generate hypochlorous acid and chlorine gas in strongly acidic water and alkaline water. Since the reforming can be performed without causing any adverse effects on the environment, a large amount of strongly acidic water can be produced at low cost.

[Brief description of the drawings]

FIG. 1 is a perspective view of a production facility used for a method for producing acidic water and alkaline water according to the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Manufacturing equipment 2 Electrolysis tank (tank) 3 Ion exchange membrane (ion exchange means) 4 Partition wall 5 Acidic water generation area 6 Alkaline water generation area 10 Water supply device 11 Supply pipe 12 One branch pipe 13 The other branch pipe 15 Take out Tube 20 DC voltage applying device (voltage applying means) 23 Lead wire 24 Positive electrode rod (anode) 25 Lead wire 26 Negative electrode rod (cathode) 50 Nonmetallic mineral (fossil earth) 60 Silicate mineral (tuff)

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[Procedure amendment]

[Submission date] November 17, 2000 (200.11.
17)

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Full text

[Correction method] Change

[Correction contents]

[Document Name] Statement

Patent application title: Method for producing acidic water and alkaline water

[Claims]

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a natural mineral which is produced by modifying water such as tap water into strongly acidic water and alkaline water using a naturally occurring mineral without performing chemical treatment, electrolysis and the like. The present invention relates to a method for producing strongly acidic water and alkaline water.

[0002]

2. Description of the Related Art To obtain acidic water, refer to Japanese Patent Application No. 63-517.
As proposed in Japanese Patent Application No. 65 and Japanese Patent Application No. 63-49861, the inside of the electrolytic layer is divided into two chambers by a diaphragm, electrodes are provided in both chambers, and these electrodes are connected to a DC power supply to form an anode chamber. And a cathode chamber are formed, and tap water containing salt (sodium chloride) or the like as an electrolytic agent is supplied to the anode chamber and the cathode chamber, and the tap water is electrolyzed to generate acidic water from the anode chamber. It was done by letting. In addition, alkaline water is generated from the cathode chamber.

[0003]

However, in the above-mentioned conventional method for producing acidic water and alkaline water, toxic substances such as hypochlorous acid and chlorine gas are generated due to the electrolytic treatment, and the environmentally friendly water is produced. Adversely affect
In order to remove toxic substances such as hypochlorous acid and chlorine gas, there is a problem that a removing device is required and the production cost is relatively high.

The present invention has been made in view of the above problems, and an object of the present invention is to produce a large amount of strongly acidic water and alkaline water by generating hypochlorous acid and chlorine gas. It is an object of the present invention to provide a method for producing acidic water and alkaline water, which can be produced without causing any adverse effects on the environment and at a low production cost.

[0005]

Means for Solving the Problems To achieve the above object, a method for producing acidic water and alkaline water according to the present invention comprises disposing an anode in an acidic water producing region and a cathode in an alkaline water producing region. A voltage is applied to the electrolytic solution filled in the acidic water generating region and the alkaline water generating region, and the acidic water is generated in the acidic water generating region by ion exchange and the alkaline water is generated in the alkaline water generating region. A method for producing water and alkaline water, wherein an electrolytic solution elutes an ionic substance from a nonmetallic mineral and a silicate mineral into raw water by introducing a nonmetallic mineral and a silicate mineral into the raw water as an electrolytic agent. It is generated.

[0006] Therefore, to reform raw water such as tap water by using naturally occurring non-metallic minerals and silicate minerals in strongly acidic water and alkaline water without generating hypochlorous acid and chlorine gas. Therefore, a large amount of strongly acidic water can be produced at low cost without adversely affecting the environment, and the production cost can be reduced without adversely affecting the environment.

In order to achieve the above object, the method for producing acidic water and alkaline water according to the present invention is characterized in that a tank filled with tap water is sandwiched between an acidic water producing zone and an alkaline water by an ion exchange means. And an anode of the voltage application means in the acidic water generation area, and a cathode of the voltage application means in the alkaline water generation area, and a predetermined amount of nonmetallic mineral is charged into the acid water generation area. , A predetermined amount of silicate mineral is introduced into the alkaline water generation area, ionic substances are eluted into tap water, tap water is reformed into an electrolytic solution, a voltage is applied to the anode and the cathode, and ions are ion-exchanged by ion exchange means. Exchange is performed to increase the hydrogen ion concentration in the acidic water generation region, so that acidic water is generated in the acidic water generation region and alkaline water is generated in the alkaline water generation region.

Preferably, the nonmetallic mineral is a fossil earth, and the silicate mineral is a tuff.

Therefore, when a voltage is applied to the anode and the cathode by driving the voltage applying means and an electric current is passed through the tap water as the electrolytic solution, the ionic substances eluted from the silicate mineral in the alkaline water producing region are negatively affected. The ionic substances move to the acidic water generation area by the ion exchange means to increase the hydrogen ion concentration, and the cation substances among the ionic substances eluted from the nonmetallic mineral in the acidic water generation area are converted to the alkaline water generation area by the ion exchange means. Then, the tap water in the acidic water generation area is reformed into strongly acidic water, and the tap water in the alkaline water generation area is reformed into alkaline water.

[0010] As described above, tap water is produced from naturally occurring nonmetallic minerals (fossil earths) and silicate minerals (tuff) to generate hypochlorous acid and chlorine gas in strongly acidic water and alkaline water. Since the reforming can be performed without causing any adverse effects on the environment, a large amount of strongly acidic water can be produced at low cost.

[0011]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a perspective view of a production facility used in the method for producing acidic water and alkaline water according to the present invention.

[0013] The production equipment 1 shown in FIG. 1 is used in the method for producing strongly acidic water and alkaline water using natural minerals. The manufacturing equipment 1 includes an electrolytic cell (layer) 2 composed of a glass container, a water supply device 10, and a DC voltage application device 2 serving as a voltage application means.
0.

The inside of the electrolytic cell 2 is divided into an acidic water generation area 5 and an alkaline water generation area 6 by a partition wall 4 having an ion exchange membrane 3 as an ion exchange means. The ion exchange means is not limited to the ion exchange membrane 3, but may be a plate-like porous ceramic or the like.

The water supply device 10 has a supply pipe 11 for tap water. The supply pipe 11 has one and the other branch pipes 12 and 13, each of which is branched. The opening part faces the area 5 above, and the other branch pipe 13 faces the opening part above the alkaline water generation area 6.

The electrolytic cell 2 is provided with a take-out pipe 14 for taking out acidic water from the acidic water generation area 5 and a take-out pipe 15 for taking out alkaline water from the alkaline water generation area 6.

The DC voltage applying device 20 includes a DC voltage generating device (battery) 21 and the DC voltage generating device 2.
1, a positive electrode rod (anode) 24 connected to the positive electrode side by a lead wire 23; a negative electrode rod (cathode) 26 connected to the negative electrode side of the DC voltage generator 21 by a lead wire 25; 23. The positive electrode rod 24 is inserted in the acidic water generation area 5, and the negative electrode rod 26 is inserted in the alkaline water generation area 6.

Tap water 40, which is raw water, is supplied from the water supply device 10 into the acidic water generating region 5 and the alkaline water generating region 6, respectively. Earth) 50 and a silicate mineral (tuff) 60 in the alkaline water generation region 6 each having a water content of about 10%.

The tap water 40 has a conductivity of 100 μS / cm or more, a cation of a mineral component of 20 mg / · or more, a chloride ion of 30 mg / · or more, and a hardness of 50 or more.

The nonmetallic minerals (fossil earths) 50 are solidified diatom fossil soils and solidified cyanobacterial fossil soils.

Diatomaceous earth is a sedimentary soil of diatom shells.
It is a kind of algae floating in the sea and lakes. It is a single-celled plant that absorbs nutrients from water and absorbs silica to form a cell membrane. The fossil of this cell membrane is diatom shell. This diatom shell fossil forms microscopic independent cells of 0.1 micron to 10 microns, and its surface is covered with countless fine pores.
The diatomaceous earth is a silica-based nonmetallic mineral (fossil earth) containing substances containing hydrogen ions, sulfides, chlorides, and the like due to volcanic activity, crustal deformation, and the like when underground.

Cyanobacteria exist in a wide variety of species, such as urea and noctuid algae, are unicellular bodies that do not move on their own, live in free, massive, or filamentous colonies, and have no nucleus and no body. They propagate only by division. This cyanobacterium fossilizes, and when in the ground, substances containing hydrogen ions, sulfides due to volcanic activity, crustal deformation, etc.
及 beauty is Circa quality non-metallic minerals, including chloride (fossil earth).

These non-metallic minerals (fossil earths) 50 are
There are dozens of natural types, of which reddish brown and grayish black are used. The nonmetallic mineral (fossil earth) 50 has many sedimentary layers, and this nonmetallic mineral (fossil earth)
When 50 is left in water, water will enter through numerous fine holes on the surface, and the voids between the deposition layers will expand, and water will enter at that moment.

The composition of the nonmetallic mineral (fossil earth) 50 is as follows: silicon (silicic acid) 78% aluminum (aluminum oxide) 10% iron (iron oxide) 4.0% potassium (potassium oxide) 4.0% calcium (oxide Calcium) 2.0% Sulfur (sulfate) 1.0% Others contain trace amounts of copper, titanium, nickel, strontium, and rubinium.

The composition of the silicate mineral (tuff) 60 is about 78% of silicic acid, aluminum oxide 10%, sodium oxide 4%, potassium oxide 4%, iron oxide 1%, magnesium oxide 1%, calcium oxide 1%, a small amount of sulfur, titanium, Contains manganese, barium, zirconium, palladium and strontium.

As described above, the non-metallic mineral 50 and the silicate mineral 60 are added to the tap water 40 by adding the non-metallic mineral 50 and the silicate mineral 60 to the tap water 40 as an electrolytic agent.
The ionic substance elutes from 0, and the tap water 40 becomes an electrolyte solution (electrolyte solution).

Then, the DC voltage applying device 20 is driven to apply a voltage to the positive electrode rod 24 in the acidic water generating region 5 and the negative electrode rod 26 in the alkaline water generating region 6, so that tap water as an electrolyte solution is supplied. When an electric current is passed through 40, anionic substances eluted from the silicate mineral 60 in the alkaline water generation area 6 move to the acidic water generation area 5 by selective permeation of the ion exchange membrane 3, and increase the hydrogen ion concentration. In addition, the cations among the ionic substances eluted from the nonmetallic mineral 50 in the acidic water generation region 5 move to the alkaline water generation region side 6 by selective permeation of the ion exchange membrane 3, and The tap water 40 is reformed into strongly acidic water, and the tap water 40 in the alkaline water generation area 6 is reformed into alkaline water.

As described above, the tap water 40 is made up of the naturally occurring nonmetallic minerals (fossil earths) 50 and the silicate minerals (tuff) 6
0 can be used to reform strongly acidic water and alkaline water without generating hypochlorous acid and chlorine gas. Can be generated.

In this case, the relationship between the amount of tap water 40 and the DC voltage by the DC voltage applying device 20 is 0.5 m with respect to 10 liters (l) of tap water 40.
A 5 mA per 100 liters (l) of tap water 40 50 per 1 kiloliter (Kl) of tap water 40
0.5 A for a water volume of 10 kiloliters (Kl) of the mA tap water 40 is 5 A for a water volume of 100 kiloliters (Kl) of the tap water 40.

The generation time of acidic water and alkaline water is as follows: acidic water, alkaline water, pH 6.0, pH 7.5, 6 hours, pH 4.5, pH 8.0, 12 hours, pH 3.5, pH 8.5, 18 hours. pH 2.6 pH 9.4 for 24 hours.

As described above, a large amount of strongly acidic water and alkaline water can be produced with a small DC voltage without generating hypochlorous acid and chlorine gas.

The results of analysis of acidic water and alkaline water obtained by modifying the tap water 40 as described above are shown below. The analysis of the acidic water and the alkaline water is an excerpt from a test result report commissioned to the Tokyo Food Association and the Tokyo Food Research Institute.

Acidic water Content and results of test and inspection pH value 2.6 Electrical conductivity (-μS / cm) ··· 1100 Redox potential (ORP) · · · 450 Dissolved oxygen (DO) · · · · · · 19 Nitrate nitrogen and 1.6 Chloride ion (mg / l) ... 31 Sulfate ion (mg / l) ... 140 hardness (mg / l) 39 organic substances (potassium permanganate consumption mg / l 5.9 phosphorus) (Mg / l) 0.2 Copper (mg / l) 0 .14 zinc (mg / l) 0.10 Iron (mg / l) 5.6 Manganese (mg / l) ... 0.25 Calcium (mg / l) ... 10 Magnesium (mg / l) ... ... 3.6 Sodium (mg / l) ... 13 Chloroform (mg / l) ... 0.005 Dibromochloro Methane (mg / l) ... less than 0.001 Bromodichloromethane (mg / l) ... 0.002 Bromoform (mg / l) ... ········· 0.017 Total trihalomethane (mg / l) ··· 0.024

Alkaline water Contents and results of test and inspection pH value 9.4 Electric conductivity (-μS / cm) 550 Redox potential (ORP) 150 Dissolved oxygen (DO) 7.9 Nitrate nitrogen and chlorite nitrogen (mg / l) ... 1.7 Chloride ion (mg / l) ... 26 Sulfate ion (mg / l) 81 Hardness (mg / l) 19 Organic matter (potassium permanganate consumption mg / l ...)・ 7.6 Phosphorus (mg / l) ・ ・ ・ ・ ・ ・ less than 0.1 Copper (mg / l) ・ ・ ・ ・ ・ ・ ・..... 0.03 zinc (mg / l) 0.038 Iron (mg / l) 0.86 Manganese (mg / l) l) 0.070 Calcium (mg / l) 6 Magnesium (mg / l) 1.8 sodium (mg / l) 93 chloroform (mg / l) 0.001 Dibromochloromethane (mg / l): less than 0.001 Bromodichloromethane (mg / l): less than 0.001 Bromoform (mg / l) l) 0.002 Total trihalomethane (mg / l) 0.003

Next, a method of using (utilizing) acidic water (strongly acidic water) and alkaline water (strongly alkaline water) will be described.

Acidic water having a pH value of 3.0 or less is colorless and odorless, and suppresses the generation of plant and zooplankton.
In addition, it exerts an astringent effect. In addition, acidic water having a pH value of 2.7 or less kills most microorganisms and fungi and has a bactericidal effect. For example, E. coli and general bacteria are annihilated by about 10% of strongly acidic water. In addition, it can be used as washing and sterilizing water for raw vegetables and the like. In addition, it can be used as acidic hot spring water and sulfate ion hot spring, can be used as sterilizing water for neutral simple hot springs (artificial hot springs), and can be used as sterilizing water for swimming pools.

Further, acidic water having a pH value of 3.0 or less can suppress generation of parasites, maggots, and the like in sewage, and can be used in restaurants, hotels, restaurants, restaurants, napkins, dining tables, tables, It can be used for disinfection of tableware. In addition, users such as public facilities, public places, buses, and trains can use the paper napkins containing acidic water for sanitation, cleanliness, and sterilization. Also yellow bud
Streptococci can be killed in about 60 minutes.

Acidic water having a pH value of 3.0 or less can be used for disinfection and disinfection of public and public toilets, deodorants Hair repellents for golf courses, insect repellents for greens and the like, and disinfection of various bacteria in sandboxes such as parks. Can be used as an agent.

Alkaline water having a pH value of 9.4 (alkali
Sodium water) can be used as an alkaline / sodium hot spring, and if iron and manganese are removed, it can be used as alkaline mineral water. In addition, for cooking rice, cooking, removing air,
It can be used as a vegetable boiler or as a soil improver that tends to be acidic in plant cultivation.

In the above-described embodiment, as the fossil soils, those obtained by solidifying diatom fossil sedimentary soils and those obtained by solidifying blue-green algae fossilized soils are used. It is sufficient if the fossil sedimentary soil is solidified.

[0041]

As described above, according to the method for producing acidic water and alkaline water according to the present invention, the voltage application means is driven to apply a voltage to the anode and the cathode, and the tap water as the electrolytic solution is used. When an electric current is passed through the anion, the ionic substances eluted from the silicate mineral in the alkaline water generation area move to the acidic water generation area by the ion exchange means to increase the hydrogen ion concentration, and in the acid water generation area, Among the ionic substances eluted from the non-metallic mineral, the cation substances move to the alkaline water generation area side by the ion exchange means, the tap water in the acidic water generation area becomes strongly acidic water, and the tap water in the alkaline water generation area becomes alkaline. Each is reformed into water.

As described above, tap water is produced from non-metallic minerals (fossil earths) and silicate minerals (tuff) which are naturally produced to generate hypochlorous acid and chlorine gas in strongly acidic water and alkaline water. Since the reforming can be performed without causing any adverse effects on the environment, a large amount of strongly acidic water can be produced at low cost.

[Brief description of the drawings]

FIG. 1 is a perspective view of a production facility used for a method for producing acidic water and alkaline water according to the present invention.

[Description of Signs] 1 Manufacturing equipment 2 Electrolyzer (tank) 3 Ion exchange membrane (Ion exchange means) 4 Partition wall 5 Acidic water generation area 6 Alkaline water generation area 10 Water supply device 11 Supply pipe 12 One branch pipe 13 The other Branch tube 15 extraction tube 20 DC voltage applying device (voltage applying means) 23 lead wire 24 positive electrode rod (anode) 25 lead wire 26 negative electrode rod (cathode) 50 nonmetallic mineral (fossil earth) 60 silicate mineral ( Tuff)

Claims (3)

[Claims] 1. An anode is disposed in an acidic water generating region, and a cathode is disposed in an alkaline water generating region. A voltage is applied to an electrolyte filled in the acidic water generating region and the alkaline water generating region, and ion exchange is performed. A method for producing acidic water and alkaline water in the acidic water producing region, and producing alkaline water in the alkaline water producing region, respectively, comprising: A method for producing acidic water and alkaline water, characterized in that an ionic substance is eluted from the nonmetallic mineral and the silicate mineral into the raw water by charging a metal mineral and a silicate mineral. 2. A tank filled with tap water is divided into an acidic water generation area and an alkaline water generation area with an ion exchange means interposed therebetween, and an anode of a voltage applying means is connected to the acid water generation area with the alkali water. Disposing a predetermined amount of nonmetallic minerals in the acidic water generating region and charging a predetermined amount of silicate minerals in the alkaline water generating region, The tap water is reformed into an electrolytic solution by eluting an ionic substance into water, and a voltage is applied to the anode and the cathode to perform ion exchange by the ion exchange means. Wherein acidic water is generated in the acidic water generating region and alkaline water is generated in the alkaline water generating region, respectively. 3. The method for producing acidic water and alkaline water according to claim 1, wherein the non-metallic mineral is a fossil earth, and the silicate mineral is a tuff.