KR970000719Y1 - Hexagon water manufacturing apparatus - Google Patents

Abstract

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Description

Hexagon Water Manufacturing Equipment

1 is a longitudinal sectional view of a conventional hexagonal water production apparatus.

2 is a longitudinal sectional view of the hexagonal water production apparatus according to the present invention.

Figure 3 is a graph of the pH change according to the electrolysis time of the present invention and the conventional hexagonal water production apparatus.

＊ Explanation of symbols on main parts of drawing

1: outer case 2: electrolytic cell

3: circulating pump 4a, 4b: hose

5: cathode 6: anode

7, 8: diaphragm

The present invention relates to a water hexagonal water production apparatus for producing hexagonal water by electrolysis, in particular to improve the electrolytic capacity by removing the bubbles generated during the electrolysis process, and to give the vibration energy to the water to improve the water structuring performance It relates to a hexagonal water production apparatus.

In the conventional hexagonal water production apparatus, as shown in FIG. 1, an electrolytic cell 2 is inserted and fixed inside the outer case 1, and the positive electrode 5 and the negative electrode 6 are coupled to the electrolytic cell 2. In the interior, a diaphragm (7) (8) is coupled between the anode (5) and the cathode (6) to move ions in water, and the power source is applied to the anode (5) and the cathode (6). Electrode terminals 9a and 9b are coupled.

In addition, a hinge 11 is formed at an upper side of the outer case 1, and a shaft 13 formed at the lid 12 is fitted to the hinge 11 to connect the lid 12 to open and close the pivot type. The inner lid 14 is fastened to the inside of the lid 12.

The inner lid 14 is formed with an annular protrusion 15, the O-ring 16b is fitted to the outer peripheral surface of the annular protrusion 15 to serve as a seal with the upper portion of the electrolytic cell (2).

The lid 12 has a deformed body 18 having an O-ring 16a fitted therein and is coupled to the compression spring 19 so as to be rotated by the handle 20, and the inner lid 14 and the deformed body ( 18, the distribution holes 17a and 17b are formed to correspond.

A locking device 21 for locking the lid 12 is coupled to one side of the lid 12, and a discharge port 22 is formed, and a control unit 23 is located at the lower side of the outer case 1. Is built in.

In the conventional hexagonal water production apparatus, when a DC voltage is applied between the positive electrode 5 and the negative electrode 6, water is electrolyzed, and a positive ion component moves to the positive electrode 5 on the positive electrode 6 side.

Therefore, on the cathode 6 side, ions that structure the water, that is, calcium, sodium, iron, and copper ions, are gathered together to form hexagonal water of hexagonal ring structure, and on the anode 5 side, that is, the ion that destroys the water structure, that is, chloride ion , Anions such as sulfate ions and carbonates are generated to generate water which destroys the hexagonal structure. Electrochemical electrolysis of the water produces a cationic component on the cathode 6 side and an anion component on the anode 5 side. The mechanism is as follows.

First, when water is electrolyzed by DC voltage, the salt of the metal dissolved in water is ionized into the metal ion component and the acid ion component, and chemical equilibrium occurs as follows.

MX M ^{+ +} X ^-

Where MX is the salt of the metal dissolved in water, M ⁺ is the metal ion component, and X ^- is the acid ion component.

In more detail, the hydrogen ions (H ⁺ ) are generated on the anode side, and the liquidity of the water becomes acidic, and the structure of the water is destroyed by gathering a lot of acid ions (X ⁺ ), chloride ions, sulfate ions, and carbonate ions.

X ⁺ + (+) → X (1)

2X + H ₂ O → 2HX + 1/20 ₂ (2)

+ X ^- (3)

On the cathode side, hydroxide ions (OH ⁻ ) are formed, and the liquidity is alkaline, and the H ₂ gas is bubbled.

M ⁺ + (-) → M (4)

M + H ₂ O → M (OH) + 1 / 2H ₂ (5)

M ⁺ + (OH) ^- (6)

In addition, as shown in Equation (6), metal ions (M ⁺ ), that is, a lot of positive ions structuring water such as calcium, sodium, copper, iron, etc. are collected to form hexagonal water.

Nuclear self-resonance (NMR) spectroscopy, which evaluates the molecular state of water in the hexagonal water generated in this way, showed that the water before electrolysis showed a wider NMR line width, whereas the water on the cathode side that had a large amount of cation by electrolysis Has narrower line width than water before electrolysis.

This means that the water on the cathode side, which has more cations than the water before electrolysis, has a faster movement of the water molecule group, and thus a higher probability of existence of a small water molecule group.

That is, it means that the number of hexagonal water that is easily absorbed by human cells and beneficial to the human body is high.

Conventional hexagonal water production apparatus to generate in the hexagonal water by this electrolytic theory, as shown in the formula (5) on the cathode side, as hydrogen gas is generated to form a bubble attached to the surface of the negative electrode, attached to the negative electrode surface There was a problem of impairing the electrolytic capacity by interrupting the current flowing through the positive electrode during electrolysis by the bubble.

The present invention solves the reduction of the electrolytic capacity by the bubble generation, which has been pointed out as a problem in the conventional hexagonal water production apparatus as described above, and installs a pipe inside the cathode side of the electrolytic cell so that the entire water on the cathode side can be changed to hexagonal water evenly. And, to provide a hexagonal water production apparatus provided with a water circulation pump on the bottom side of the cathode.

Water hexagonal water production apparatus according to the present invention in order to achieve this object is connected to the hose to the lower end of one negative electrode portion of the electrolytic cell in which the positive electrode and the negative electrode is coupled to the inside, the positive electrode portion and the negative electrode portion is formed into a diaphragm, the other negative electrode portion Fixing the pipe to the lower end is connected to the hose, it is configured to circulate the water inside the electrolytic cell by coupling the circulation pump to the connection portion of the both hoses.

Hereinafter, described in detail with an embodiment to the accompanying drawings of the present invention as follows.

Figure 2 is a longitudinal cross-sectional view of the hexagonal water production apparatus according to the present invention, as shown in this, the electrolytic cell 2 is inserted and fixed inside the outer case 1, the lower end of the electrolytic cell 2 with a circulation pump ( 3) is attached and the electrolytic cell 2 and the water channel are connected by the hose 4a.

In addition, a pipe 10 is inserted into the electrolytic cell 2 so that the water circulated by the circulation pump 3 rises up to the upper portion of the negative 6 side and flows uniformly as a whole, and the circulation pump 3 is a hose. 4b is connected to the lower end of the pipe 10.

In addition, an anode 5 and a cathode 6 are coupled to the electrolytic cell 2, and the inside is divided into diaphragms 7 and 8, and the power is applied to the anode 5 and the cathode 6. Electrode terminals 9a and 9b are coupled.

In addition, a hinge 11 is formed at an upper side of the outer case 1, and a shaft 13 formed at the lid 12 is fitted to the hinge 11 to connect the lid 12 to open and close the pivot type. The inner lid 14 is fastened to the inside of the lid 12.

The inner lid 14 is formed with an annular protrusion 15, the O-ring 16b is fitted to the outer peripheral surface of the annular protrusion 15 to serve as a seal with the upper portion of the electrolytic cell (2).

The lid 12 is fitted with a compression spring 19, the deformed body 18 is fitted with an O-ring (16a) is coupled to be rotated by the handle 20, the inner lid 14 and the deformed ( 18, the distribution holes 17a and 17b are formed to correspond.

A locking device 21 for locking the lid 12 is coupled to one side of the lid 12, and a discharge port 22 is formed, and a control unit 23 is located at the lower side of the outer case 1. Is built in.

The present invention as described above is a bubble of hydrogen generated in the electrolytic process by circulating the water by the circulation pump (3) does not adhere to the surface of the cathode (6) smoothly to the outside of the electrolytic cell (2) by the flow of water. As the electrolysis time accumulates due to bubbles on the surface of the cathode 6, the problem of poor electrolytic capability is solved, and the amount of change in the entire water into hexagonal water in the water circulation is increased.

In addition, by circulating the water, mechanical vibration energy was added to the water, and thus the structure of the water was further improved.

3 is a graph showing the change in pH of the liquid of water between the apparatus (△) of the present invention and the conventional apparatus (○) not circulated by the electrolytic time-process circulation system, and as shown therein, As the water becomes more alkaline, this shows that as the electrolysis ability is maintained by removing hydrogen bubbles, the pH is further increased with the passage of the electrolysis time.

The following table shows the measured values of the PH and NMR line widths of the device of the present invention and the conventional device not circulated by the circulation system after the completion of electrolysis. The PH was not changed, but the NMR line width was reduced. Could.

In addition, according to the results as shown in the above table, the mechanical energy of vibration is applied to the water by the circulation of the water to speed up the movement of the water molecule group, and thus, the existence of small water molecule groups increases.

As can be seen from the table and FIG. 3, the circulation of water is also necessary in the process of electrolysis, but even if the electrolysis is completed, it means that the circulation of water helps the structure of water molecules for a certain period of time. This improves the capacity and structure of the water molecules.

The present invention as described above improves the electrolytic capacity by removing the air bubbles generated during the electrolysis process by installing a circulation pump on the cathode side of the electrolytic cell and circulating for a certain time after completion of the electrolysis process, a certain time after the completion of electrolysis By giving a mechanical vibration energy to the water by circulating during it has the effect of further improving the structure of the water.

Claims (1)

A positive electrode and a negative electrode are combined therein, and a hose is connected to the lower end of one negative electrode part of the electrolytic cell in which the positive electrode part and the negative electrode part are formed into a diaphragm, and the hose is connected to the lower end by fixing a pipe to the other negative electrode. Hexagonal water production apparatus characterized by circulating the water in the electrolytic cell by combining the circulation pump to the connection portion of the.