JPH01111483A - Formation device for electrolysis water containing many electrons - Google Patents

Abstract

PURPOSE:To form ion water of different nature by installing a flow rate ratio regulating device for regulating the discharge in a corresponding flow channel of at least one of an alkali ion water discharge channel and an acid ion water discharge channel or a joint discharge pipe section for both. CONSTITUTION:A non-insulated side output terminal 10a of a high voltage generating device 10 is connected with one electrode 6a in an electrolysis tank 5, and a given voltage not to generate a short circuit of a couple of heteropolar electrodes 6a and 6b in the electrolysis tank 5 is applied to modify the water in the electrolysis tank 5 to the water containing electrons. The mixing ratio of alkali ion water containing electrons thus formed and acid ion water is regulated by a flow ratio regulating device 14 installed in discharge channels 4a and 4b to prepare ion water of different nature (pH value and the like). Also, as said electrolysis water contains electrons, the continuity of ion activity can be enhanced and the ion water can be availed for the remedy of diseases and health promotion.

Description

[Detailed Description of the Invention] [Field of Application of the Invention] The present invention induces electrons into water in an electrolytic cell to generate electrolytic ionized water containing many electrons, and also to improve the flow rate ratio or mixing ratio of alkaline water and acidic water. The present invention relates to an electrolyzed ionized water generating device that can variably adjust and supply the components of electrolyzed water by adjusting the components of the electrolyzed water.

[Problem that the invention seeks to solve]

The present inventor previously demonstrated that by electrolyzing water to produce alkaline water and acidic water, adjusting the mixing ratio and discharging the water, ionized water with various properties biased toward alkaline or acidic can be obtained.
In addition, it was discovered that when a phosphate-based or silicate-based rust preventive agent was added to the electrolyzed water, the reaction of the rust preventive agent was activated.
A patent application was filed as No. 4.

As a result of further research, the inventor found that by inducing electrons into the water in the electrolyzer, electrolyzed water containing many electrons is produced, which is more beneficial to health and can increase the sustainability of the ionic activity of electrolyzed water. At the same time, by adjusting the flow rate (mixing) ratio of alkaline water and acidic water in electrolyzed water with electrons induced in this way, water with various properties can be obtained, and water for hot spring bathing and solutions for hydroponic cultivation can be produced. The present invention has been made based on the discovery that the method is advantageous for the following reasons.

Therefore, the first object of the present invention is to provide a device that can supply electrolyzed water rich in electrons by adjusting its composition and properties, which is good for health, maintains ionic activity, and does not cause rust. It is difficult to obtain water.

Another object of the present invention is to generate the above-mentioned water as magnetized water by applying a magnetic force to the water during electrolysis.

[Means to solve the problem]

The first object of the present invention is to provide an alkaline ionized water discharge channel and an acidic ionized water discharge channel in which a negative electrode and a positive electrode for applying an electrolytic voltage are disposed facing each other, and the two electrodes are communicated with an electrolytic chamber separately. A high voltage generator for electron induction of direct current or alternating current, with one output terminal insulated and the other output terminal electrically connected to one of the electrodes inside the electrolytic cell of the electrolyzer. a flow rate ratio adjustment device that is installed in one or both of the alkaline ionized water discharge channel and the acidic ionized water discharge channel or in their combined drain pipe section and adjusts the discharge amount of the channel; This can be achieved by an electrolyzed water generator.

The second object of the present invention can be achieved by providing a magnetic field generating means for generating a magnetic field in one electrode chamber of the electrolyzer, either outside or inside the electrolytic cell of the electrolytic device. Can be done.

[Action of the invention]

The present invention provides a high voltage generator for direct current or alternating current electron induction with one output terminal insulated, separately from the electrolytic voltage applying device of the electrolysis device, and the non-insulated side output terminal of this high voltage generator (in the case of direct current When the positive electrode) is connected to one electrode in the electrolytic cell and a predetermined voltage is applied that does not short-circuit the pair of opposite polarity electrodes in the electrolytic cell, the water in the electrolytic cell becomes water containing a large amount of electron e-. modified.

Since this water contains a large amount of electron e-, it is good for health in itself, and the action of electron C maintains the ionic activity in the electrolyzed water and has the effect of suppressing the formation of rust.

Furthermore, if the flow rate (mixing ratio) of the electron-containing alkaline water and acidic water generated in this way is adjusted and discharged, water containing many electrons will be supplied with its properties (PH value, etc.) adjusted in various ways. Ru.

Furthermore, when the electrolyzer is equipped with a magnetism generating device, the water is easily magnetized because of the magnetic force acting on the water being electrolyzed, and electrolyzed water that is physiologically activated by the magnetism can be obtained.

[Embodiments of the invention]

Embodiments of the present invention will be described below based on the drawings.

As illustrated in FIG. 1, the electrolysis device 2 provided in the piping system 1 has a water supply part 3 connected to the water supply side 1a of the piping system 1 on one side, and a drain pipe of the piping system 1 on the other side. A pair of electrolyzed water discharge channels 4a, 4 for alkaline ionized water and acidic water communicating with 1b.
The electrolytic cell 5 is equipped with an electrolytic cell 5 having a

The electrolytic cell 5 includes a pair of electrodes 6a having mutually different polarities.

6b (a negative electrode and a positive electrode) are arranged to face each other, and the electrodes 6a and 6b are connected to the pair of electrolyzed water discharge channels 4a and 4b, respectively, by an electrolytic diaphragm 7 (ion exchange membrane). It is partitioned into a pair of electrode chambers 8a and 8b that communicate with each other.

In this way, the DC voltage of the electrolytic voltage circuit 9 is applied to both electrodes 5a, 5b to electrolyze the supplied water in the electrolytic cell, and alkaline ionized water and acidic ionized water are separately discharged from the pair of discharge channels 4a, 4b. It is supposed to be done. Although FIG. 1 illustrates a cylindrical electrolysis unit in which both electrodes 6a and 6b are arranged concentrically and facing each other as a unit of the electrolyzer 2,
The electrolytic unit used in the present invention is not limited to this configuration, and may be a flat plate type electrolytic unit in which both flat electrodes are partitioned via an electrolytic diaphragm, and in short, between two electrodes of different polarity 6a that are substantially opposed to each other. , 6b is partitioned into a pair of electrode chambers 8a, 8b by a diaphragm 7 for electrolysis, and on one side of this electrolytic cell, a water supply part 3 communicating with the electrode chambers 8a, 8b is provided.
Any other configuration may be used as long as a pair of discharge passages 4a + 4b are provided on the other side to respectively communicate with the pair of electrode chambers 8a + 8b.

IO is a high voltage generator for electron induction provided separately from the electrolytic voltage circuit 9, and this high voltage device 10 insulates one output terminal 10b and electrolytically connects the other non-insulated output terminal 10a. It is connected to an electrode inside the electrolytic cell 5 via a voltage circuit 11, thereby inducing electrons e- into the water within the electrolytic cell 5.

The high voltage generator 10 can use either direct current or alternating current, but when using direct current by providing a rectifier 13 on the secondary side of the transformer 12 as shown in the figure, connect the - (minus) terminal 10b on the output side. Insulate and connect the + (plus) terminal to the electrolytic tank 5.
Connect to internal electrode.

In the case of alternating current, one of the secondary output terminals is insulated and the other is connected to the electrolytic electrode. As shown in FIG. 1, when the casing of the electrolytic cell 5 is used as one electrode 6b (for example, a negative electrode) and the other electrode 6a (for example, a positive electrode) is provided inside the casing, the electron induction voltage generator 10 is The non-insulated side terminal 10a is connected to the inner electrode 6a.

On the other hand, when the negative and positive electrodes 6a and 5b are arranged facing each other inside the casing of the electrolytic cell 5 as shown in FIG. In this case, it is preferable to connect the voltage circuit 11 to the positive electrode 6a and the negative electrode 6b via a changeover switch 11'.

As already mentioned, the high voltage generator 10 insulates one output terminal and applies the high voltage of the other output terminal to only one electrode in the electrolytic cell 5, thereby causing water in the electrolytic cell 5 to The purpose is to induce electrons e-, and therefore the voltage applied from the high voltage generator 10 is approximately 300V to 10V.
,000V is used. However, the applied voltage for electron induction is not uniform depending on the distance between the electrodes 6a and 6b of the electrolysis device 1. That is, both electrodes 6a+6
If the applied voltage is too high for the electrode gap b, a short circuit will occur between the electrodes, and the purpose will not be achieved. Therefore, the high voltage generator 10
The voltage is set to an appropriate voltage depending on the distance between the electrodes 6a and 6b so that short circuit does not occur and electron e- is more effectively induced.

When the electrode 6a of the electrolysis device 2 is used as an anode and the electrode 6b is used as a cathode, one electrolyzed water discharge path 4a becomes an alkaline ion water discharge path, and the other electrolyzed water discharge path 4b becomes an acidic ion water discharge path. Become.

As shown in FIG. Q, a flow rate ratio adjustment device 14 with a drain is provided at one or both of these electrolyzed water discharge paths 4a and 4b, or at the confluence thereof, to adjust the flow rate ratio of the two discharge paths.

The flow rate ratio adjusting device 14 basically has a rotary valve body 15b fitted in a casing 15a, as shown in FIG.
It forms a notch passage 15C that can communicate with the valve body 15b, and a drain 15d that extends transversely from the circumference near the end of the notch passage 15C and communicates with the outside through the axial direction. By rotating the passage 15c along the casing 15a, the passage 15c opens and closes, and the passage 15
c is closed, a part of the water in the drainage channel 4a (4b) is drained to the outside through the drain 15d.
The flow rate flowing from a (4b) to the drain pipe 1b is controlled.

FIG. 1 shows an example of a case where a flow ratio adjustment device 14 is provided in both of a pair of electrolyzed water discharge channels 4a, 4b, and two rotary valve bodies 15b, 1 corresponding to a pair of discharge channels 4a, 4b are provided.
5b are formed coaxially and integrally at different angles with respect to the direction of each discharge passage, as shown in Fig. 4, and when one valve body operates in the direction to close the corresponding discharge passage by rotation, the other valve body responds. It is designed to operate in the direction of opening the discharge path.

Although not shown in the drawings, if the flow ratio adjusting device 14 is provided in both of the pair of discharge passages 4a and 4b, for example, two rotary valve bodies with gears provided on the outer periphery of the wheel of the rotary valve bodies as shown in Fig. 3 may be used. may be rotatably fitted in each discharge passage, and may be interlocked by engaging the gears of each valve body.

In addition, when the flow ratio adjustment device 14 is provided at the confluence of the pair of drain passages 4a and 4b, two drain branch passages 15 (j, 1
5d may be rotatably fitted into the merging portion.

Although the valve body 15b may of course be operated manually, it is preferably operated by electric drive means such as the motor 16.

In addition, 17 in the figure is a throttle valve provided in the drain pipe of the drain 15d, which controls the amount of drained drain depending on the difference in water pressure from the water supply section.

In addition, 18 is a rust preventive agent supply unit that supplies a phosphate-based or silicate-based rust preventive agent to the water passing through the piping system 1, and in the embodiment shown in the figure, a pair of electrolyzed water discharge channels are merged. Although it is installed in the drain pipe 1b, it is not limited thereto and may be installed anywhere in the piping system.

The water supply section 3 of the electrolyzer 2 is preferably connected to an electrolytic cell 5 as shown in the figure.
A pair of water supply ports 3a, 3b which communicate with each of the pair of electrode chambers 3a, 8b are provided independently, so that raw water supplied from the water supply pipe 1a can be separately introduced from these water supply ports 3a, 3b. In this way, the chemical solution from the chemical solution supply device 19 can be supplied from the water supply port together with the raw water.

This chemical solution supply device can select and use various chemical solutions depending on the purpose, such as a chemical solution for producing alkali ions such as minerals, various hot spring components, and nutrients for hydroponic cultivation.

Furthermore, the opposing electrodes (3a and 6b) of the electrolyzer are made of a material that can withstand use as a positive electrode during water electrolysis.
That is, using a material resistant to anodic electrolysis, both electrodes 5a,
It is desirable to switch the polarity of the voltage applied to 6b to enable normal electrolytic operation. The anodic electrolysis resistant material defined here means an electrode material that can withstand use not only as a cathode but also as an anode during water electrolysis, such as ferrite, magnetite, ceramics, etc. Ceramics that can be used as positive electrodes, such as ceramics that have been surface-treated with gold or platinum or mixed with other conductive materials; titanium; titanium alloys; titanium plated with precious metals; and other alloys that can be used as positive electrodes. Examples include alloy materials that prevent anode collapse on the electrode surface through the action of the electric charge of the alloy's ions.

When such an electrolyzer is used, the electric circuit 9 for applying the electrolytic voltage is usually provided with a polarity switch 9' for changing the polarity of the electrodes 5a, 5b.

Furthermore, when such an electrolytic device is used, the polarity of the pair of electrode chambers 8a, 8b is reversed by switching the polarity, so it is also necessary to switch the flow rate ratio adjustment device 14 and the chemical solution supply device 19.

For this reason, in the embodiment shown in FIG.
4 and the polarity changeover switch 9' of the electrolytic electric circuit 9 are electrically interlocked, and the chemical solution supply device 19 is provided with a flow path changeover valve device 19b operated by the motor 19a. may be electrically interlocked.

In addition, 19c in the figure is the motor 19a of the chemical liquid flow path switching valve 19b.
It is a position detector such as a limit switch provided to control the

FIG. 6 shows another embodiment of the device of the present invention, in which the electrolytic cell 5
is equipped with a magnetic supply device 20 to apply magnetic force to the water in the electrolytic cell.

The magnetic supply device 20 of the embodiment shown in FIG. 6 is designed to generate a magnetic field by applying a voltage from the power supply circuit 21 to a coil unit 20a disposed around the outer periphery of the electrolytic cell 5. However, the structure is not limited to this, and a structure in which a permanent magnet is disposed outside the electrolytic cell 5 as shown in FIG. 7a may also be used.
The positive electrode 10b of the electrolytic cell may be made of a permanent magnet as shown in the figure, or it may be a hollow positive electrode fitted with a permanent magnet as shown in Fig. 7c. Any structure may be used as long as a magnetic field is formed in one electrode chamber and magnetism is applied to the water being electrolyzed.

Next, the present invention will be explained in detail.

Water added with the necessary chemical solution is introduced into the electrolytic tank from the water supply port 3 of the electrolyzer, and voltage from the electrolysis electric circuit 9 is applied, and high voltage from the high voltage generator IO for electron induction is applied to the electrolytic tank 5. When the voltage is applied to only one electrode of the electrolytic cell 5, electrons e- are accumulated in the water in the electrolytic cell 5. Therefore, electrolyzed ionized water containing many electrons is produced from the electrolyzer.

By changing the flow rate ratio of the alkaline water drainage channel and the acidic water drainage channel using a flow rate ratio adjustment device provided in the discharge channel of the electrolyzer, water of various quality with different pH values is selectively produced.

If the generated water is biased toward alkalinity, an increase in mineral ions such as calcium and magnesium eluted into the water will accelerate the reaction of phosphate-based and silicate-based rust inhibitors, causing damage to the metal surface of water pipes. The film-forming action becomes active.

When the electrolytic cell is provided with the magnetic supply device 20, magnetism acts on the water being electrolyzed to generate magnetized ionized water.

〔Effect of the invention〕

As described above, the device of the present invention can adjust the flow rate ratio of electrolytically generated alkaline ionized water and acidic water to generate ionized water with different properties. The sustainability of the drug is improved, and it is useful for treating diseases and promoting health.

In particular, it is possible to produce solutions for hot spring bathing and hydroponic cultivation with various properties by adjusting the flow rate ratio of alkaline water and acidic water of electrolyzed water to which various chemical solutions have been added.

Also, by magnetizing the water during electrolysis, rust and water scale are less likely to occur.

Furthermore, since the desired chemical solution can be supplied together with the raw water from the two water supply ports that communicate with the pair of electrode chambers separately, the concentration of the chemical solution can be averaged, and there is no need to provide a special chemical solution supply path.

If a material resistant to anodic electrolysis is used for both electrodes, normal electrolysis operation can be performed by switching the polarity of the electrodes.

In this case, calcium carbonate, etc. that have adhered to the electrolytic cell are dissolved in the water during electrolytic operation after switching the electrodes, eliminating the need for cleaning, which was a bottleneck for this type of electrolyzer, eliminating the cost of cleaning equipment, and reducing cleaning loss time. Effects such as reduction can be obtained.

[Brief explanation of the drawing]

FIG. 1 is a block diagram schematically showing the present invention, FIG. 2 is a partial cross-sectional view showing one embodiment of the device of the present invention, and FIGS. 3 and 5 are cross-sections of a flow ratio adjusting device according to another embodiment. 4 is a sectional view taken along line rV-IV in FIG. 2, FIG. 6 is a view corresponding to FIG. 2 showing another embodiment of the present invention, and FIGS. 7a to 70 are magnetic FIG. 7 is a partial cross-sectional view showing another embodiment of the generator. 2... Electrolyzer, 3... Water supply section, 4a, 4b.
... Electrolyzed water discharge channel, 5... Electrolytic cell, 6a, 5b.
... Electrode, 9 ... Electrolytic electric circuit, 10 ... High voltage supply device for electron induction, 14 ... Flow ratio adjustment device, 15b ... Rotary valve body, 15C ... Notch passage, 15d. ...Drain, 18.. Rust preventive agent supply unit, 20.. Magnetic supply device, 20a.. Coil unit, 20b.. Permanent magnet. Patent Applicant Tatsuo Okazaki Agent Patent Attorney Nao Sato Prosthetic Hand 2Moss ■] December 27, 1982 2 Title of Invention Device for generating electrolyzed water containing a large amount of electrons 3 Person making the amendment Relationship to the case Patent applicant address: 2-7-18 Nishi, Kamifukuoka-shi, Saitama Name: Tatsuo Okazaki 4 Agent address: Saeki Building, 2-4-1 Kajicho, Chiyoda-ku, Tokyo Telephone: 03 ( 252) 25515, Date of amendment order Voluntary 6, Number of inventions increased by amendment 07, Subject of amendment "Detailed description of the invention" in the specification (1) "One electrolyte" on page 10, line 7 of the specification Correct the water discharge channel 4aJ to [one electrolyzed water discharge channel 4bJ. (3) In the drawings, Figure 2 will be corrected as shown in the attached sheet.

Claims (4)

[Claims] (1) A raw water supply port for electrolysis is provided in an electrolytic cell in which a cathode and an anode for applying an electrolytic voltage are arranged facing each other, and an electrolytic diaphragm is used to partition the space between the two electrodes into a cathode chamber and an anode chamber. A water electrolysis device is provided with an alkaline ionized water discharge path and an acidic ionized water discharge path that communicate with the anode chamber separately, one output terminal is insulated, and the other output terminal is connected to either one inside the electrolytic cell of the electrolysis device. A high voltage generator for direct current or alternating current electron induction electrically connected to one of the electrodes, and installed in one or both of the alkaline ionized water discharge channel and the acidic ionized water discharge channel or their combined drain pipe, 1. A device for generating electrolyzed water containing a large amount of electrons, comprising: a flow rate ratio adjustment device for adjusting the amount of discharge from a channel; (2) The electrolysis device according to claim 1, characterized in that the electrolytic device is equipped with a magnetism generating means for forming a magnetic field in at least one electrode chamber in the electrolytic cell, outside or inside the electrolytic cell. Water generator. (3) The electrolyzed water according to claim 1 or 2, characterized in that the water supply part of the electrolyzer is provided with two water supply ports that communicate with the internal cathode chamber and anode chamber, respectively. generator. (4) The cathode and anode of the electrolyzer are made of anodic electrolysis-resistant material that can withstand use as an anode when producing electrolyzed water, and the polarity of the voltage applied to both electrodes can be switched. The electrolyzed water generating device according to any one of claims 1 to 3, further characterized in that: