KR101959081B1 - A Electrolyzer - Google Patents

Abstract

The present invention relates to a hydrogen-containing electrolytic cell for electrolyzing water to generate hydrogen water, and more specifically, to a hydrogen-containing electrolytic cell in which water molecules passing through a second flow path, And the hydrogen gas is caused to collide with the hydrogen water by the speed change of the accelerating / decelerating speed so that the remaining hydrogen gas is melted into the hydrogen con- centration, thereby securing an enhanced concentration of hydrogen peroxide .

Description

[0001] The present invention relates to a hydrogen-

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a hydrogen generator for securing hydrogen water by electrolysis of water. More specifically, the present invention relates to an electrolyzer of a hydrogen generator which improves the concentration of hydrogen peroxide and the concentration of hydrogen .

Generally, a water purifier is a device for generating potable drinking water by removing contaminants contained in raw water. The water purifier can be configured variously according to a filtering method, and recently, a water purifier capable of drinking drinking water has emerged.

It is known that Oxygen Free Radical (Oxygen Free Radical) generated in the metabolic process of living organisms is very strong oxidizing ability and oxidizes genes or cells constituting the living body to cause disease. However, Hydrogen Water reacts with active oxygen in the body and reduces it as pure water. Therefore, it not only prevents oxidation of cells by active oxygen, but also can help various intractable diseases and prevention and treatment of aging.

An electrolytic cell is installed inside the water purifier to secure such a small amount of water.

Typically, the electrolytic cell is provided with a separating membrane (not shown) through which hydrogen gas passes but water does not pass through an enclosure formed with an inlet port and an outlet port, and each positive electrode plate Electrode) and negative electrode (negative electrode) are installed to secure the water of the electrolysis.

However, there is a problem that it is difficult to maintain the concentration of 0.1 ppm or more in the case of producing hydrogen water by the conventional electrolytic bath. That is, as shown in FIG. 1, the hydrogen gas 101 generated during electrolysis sticks to the surface of the cathode electrode plate 100 and can not easily be dissolved in water.

Further, as shown in FIG. 2, a plurality of hydrogen gasses sticking to the surface of the cathode electrode plate 100 are clumped to stick to the cathode electrode plate 100 in a state where hydrogen bubbles 103 having a predetermined area or more are formed Since the electrode plate is maintained in a stabilized state, the electrolysis is not performed or the efficiency is lowered in the region until the hydrogen bubble 103 is dropped, so that the concentration of the hydrogen peroxide is low due to the fact that the hydrogen bubble 103 does not generate hydrogen peroxide .

KR 20-0478290 Y1 KR 10-1427989 B1 KR 10-2016-0062674 A KR 20-2010-0003641 U

Accordingly, the object of the present invention is to provide an electrolytic cell in which hydrogen gas adhering to a cathode electrode plate is directly separated during electrolysis, and the separated hydrogen gas is melted in purified water and has a more improved concentration and a dissolved amount of hydrogenated water.

According to an aspect of the present invention, there is provided an air conditioner comprising: a housing having an inlet and an outlet formed on an outer side thereof and a pair of electrode plates and a separator on the inner side;

A plurality of elongate channels connecting the inlet and the outlet are formed so that the purified water passing through the channels flows at a high speed so that the hydrogen gas attached to the cathode plate is separated so that the cathode plate can continuously generate hydrogen Thereby improving the concentration and the dissolved amount of the hydrogenated water.

In addition, the present invention can improve the concentration and the dissolved amount of hydrogen peroxide by colliding the constants passing through the plurality of flow paths and allowing the hydrogen gas contained in each hydrogen peroxide to melt.

In the present invention, the constants for moving the plurality of flow paths at a high speed directly separate the hydrogen gas adhered to the cathode electrode plate, and the electrode plate can continuously generate hydrogenated water, . In addition, according to the present invention, the hydrogen gas containing the separated hydrogen gas is collided with each other to melt the hydrogen gas, so that it is possible to secure an even higher concentration of hydrogen peroxide.

1 is a partial perspective view showing a state where a hydrogen gas is adhered to a conventional electrolytic bath;
Figure 2 is a cross-
3 is a perspective view of an electrolytic cell according to an embodiment of the present invention.
4 is an exploded perspective view of an electrolytic cell according to an embodiment of the present invention.
5 is an operational state diagram of an electrolyzer according to an embodiment of the present invention.
6 is a partially enlarged cross-sectional view of an electrolytic cell according to an embodiment of the present invention.
7 is a partially enlarged cross-sectional view of an electrolytic cell according to an embodiment of the present invention.
8 is an operational state view of an electrolytic cell according to another embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

FIG. 3 is a perspective view showing an entire electrolytic cell according to an embodiment of the present invention, and FIG. 4 is an exploded perspective view showing an internal configuration of an electrolytic cell according to an embodiment of the present invention. FIG. 5 is an operational state diagram showing how a purified water passing through an elongated second channel of an electrolytic cell sweeps hydrogen gas attached to a cathode electrode plate according to an embodiment of the present invention.

The electrolytic bath of the present invention has inlet ports 11 and 21 and outlet ports 12 and 22 on the outer side and an inner inlet port 11 and outlet port 12 connected to the inlet ports 11 and 21 and the outlet ports 12 and 22, In a state of having a pair of the first housing 10 and the second housing 20 forming the first and second housings 13 and 23,

The inner housing 13 of the first housing 10 and the inner housing 23 of the second housing 20 are positioned opposite to each other and then the first housing 10 and the second housing 20 are brought into close contact with each other Thereby forming an enclosure having an inner space inside.

At this time, the cathode electrode plate 40 is disposed in the inner portion 13 of the one first housing 10 and the second electrode housing 40 is disposed on the other side of the separation membrane 30, 20 are provided with an anode electrode plate 50 in the inner portion 23 and each of the connecting pipes 41 and 51 for supplying a current to the cathode electrode plate 40 and the anode electrode plate 50 The first housing 10 and the second housing 20 protrude outward from the through holes 14 and 24, respectively.

At this time, the inlet ports 11 and 21 and the outlet ports 12 and 22 are positioned diagonally,

The first flow path (15, 25) is formed in the inlet (11, 21) located at one side of the upper part of the inner part (13, 23)

The third flow passages 17 and 27 are formed in the outflow ports 12 and 22 located on the other side of the inner portions 13 and 23 so as to discharge the hydrogen out of the outlets 12 and 22, Lt; / RTI >

The cross section of the first and second flow paths 15 and 25 and the third flow paths 17 and 27 has a lower height or area than the first flow paths 15 and 25 and the third flow paths 17 and 27 And a plurality of elongated second flow paths (16, 26)

A plurality of second flow paths 16 having a lower height or area than the first flow path 15 flow through the first flow path 15 through the inlet 11 at a high speed, The hydrogen gas (2) adhered to the hydrogen gas (40) is immediately separated.

At this time, the first flow paths 15 and 25 are connected to the inlet ports 11 and 21 formed at one side of the upper part, and the cross section thereof is relatively larger than the second flow paths 16 and 26, To flow into the second flow path (16, 26) after filling the first flow path (15, 25).

The second flow paths 16 and 26 are for separating the hydrogen gas 2 adhered to the cathode electrode plate 40. The second flow paths 16 and 26 are formed of a plurality of channels, So that the purified water passes through the second flow paths 16 and 26 at a high speed by the principle of baunus.

In addition, the third flow paths 17 and 27 are connected to the outflow ports 12 and 22 formed on the other side of the lower portion, and the cross section thereof is relatively larger than the second flow path to pass through the plurality of second flow paths 16 and 26 So that the hydrogen gas is dissolved in the hydrogen water while the hydrogen molecules are collided with each other as the hydrogen molecules are collected in the third flow paths 17 and 27.

Although the first and second flow paths 15 and 25 and the third flow paths 17 and 27 may be formed in different areas in the present invention, So that the distances from the inlet ports 11 and 21 to the outlet ports 12 and 22 are equal to each other so as to have a similar moving speed.

The cathode electrode plate 40 and the anode electrode plate 40 are formed by plating a titanium perforated plate with platinum so that conductivity and corrosiveness are taken into account. .

6 is a view showing a state where hydrogen water containing hydrogen gas is discharged outside an outlet according to an embodiment of the present invention,

With reference to this, upwardly curved entry tangs 18 and 28 are formed at the edges of the outflow ports 12 and 22 formed in the inner portions 13 and 23 of the present invention,

The molten water passing through the plurality of second flow paths 16.26 is collected into the third flow paths 17 and 27. At this time, the molten water collected in the third flow paths 17 and 27 flows upwardly, To move toward the outflow ports (12, 22) after colliding with each other,

Hydrogen gas (2) contained in hydrogen water is melted at the time of collision, so that hydrogen water of a higher concentration can be generated.

Figure 7 also shows the appearance of an outlet forming a chamber in accordance with an embodiment of the present invention.

The outlets 12 and 22 of the present invention are integrally formed with chambers 19 and 29 having diameters relatively larger than the areas of the outlets 12 and 22,

As the hydrogen gas that has been discharged at a high rate is introduced into the chambers 19 and 29 and dispersed, the hydrogen gas 2 is allowed to flow into the hydrogen process, So that a sufficient number of water can be secured.

FIG. 8 is an operational state diagram illustrating a process for securing hydrogenated water by another method using an electrolytic bath according to an embodiment of the present invention.

When the purified water is injected into the inlet 21 of the second enclosure 20,

The gas is introduced into the first flow path 25 of the second housing 20 and is moved to the second flow path 26. At this time, the electrolysis is performed by the anode electrode plate 50, And the number is generated. And the oxygen water is discharged through the third flow path 27 out of the outlet.

At this time, the hydrogen gas 2 generated by the electrolysis of the purified water of the second flow path 26 is moved to the second flow path 16 of the first enclosure 10 through the separation membrane 30, The hydrogen gas 2 present in the second flow path 16 of the second flow path 16 may be discharged outside the outlet 12 and stored in the hydrogen tank or may be mixed with purified water to generate hydrogen peroxide.

Accordingly, the present invention is characterized in that the first flow paths 15 and 25, the second flow paths 16 and 26, and the third flow paths 17 and 27 are formed inside the inner portion 13.23, And the hydrogen gas 2 adhered to the cathode electrode plate 40 is directly separated from the cathode electrode plate 40. The cathode electrode plate 40 is continuously electrolyzed to generate hydrogen peroxide. At this time, the separated hydrogenated water is added to or subtracted from the speed change by the intake taps 18 and 28 and the chambers 19 and 29, thereby causing the hydrogenated water to collide with each other to melt the remaining hydrogen gas, It is possible to generate a prime number.

1: electrolytic cell 2: hydrogen gas
10: first housing 10a: fastening hole
11: Inlet
12: Outlet 13: Inner part
14: through hole 15: first flow path
16: second flow path 17: third flow path
18: entry chin 19: chamber
20: second housing 20a: fastening hole
21: Inlet
22: Outlet 23: Inner part
24: through hole 25: first flow path
26: second flow path 27: third flow path
28: entry chin 29: chamber
30: separator 40: cathode electrode plate
41: Connector 50: Anode electrode plate
51: Connector

Claims (6)

The first housing and the second housing each having an inlet and an outlet formed on the outer side and an inner portion connected to the inlet and the outlet, respectively,
The inner housing of the first housing and the inner housing of the second housing face each other and then the first housing and the second housing are closely contacted to each other to form an inner space,
A cathode electrode plate is disposed in an inner portion of the first enclosure and a cathode electrode plate is provided in an inner portion of the second enclosure,
The first enclosure is formed with a first flow path in a horizontal direction and a third flow path in a horizontal direction while being connected to an outflow port at a lower portion thereof. In a state in which a plurality of second flow paths are elongated in the longitudinal direction between the flow paths,
Wherein an upwardly curved entry step is formed at an edge of an outlet formed in an inner portion of the first housing and when the hydrogenated water passing through the plurality of second flow paths is collected into the third flow path, By colliding with each other by the upwardly curved entry jaws and then moving toward the outlet,
Wherein hydrogen gas contained in the hydrogen water in the collision is melted during the collision to secure an enhanced concentration of hydrogen in the hydrogen. The method according to claim 1,
Wherein the second flow path has an elongated shape with an area smaller than that of the first flow path or the third flow path,
The purified water in the first flow path is directly passed through the second flow path at a speed faster than the first flow path by the principle of the basin and the hydrogen gas attached to the cathode electrode plate is immediately separated through the inlet, Of the hydrogen-containing electrolytic bath. 3. The method of claim 2,
Wherein the first flow path and the third flow path are formed in the same area. 3. The method according to claim 1 or 2,
Wherein the outlet has a relatively larger diameter chamber than the outlet so that the hydrogen gas collides with each other while varying the speed of the hydrogen discharge so that the hydrogen gas is dissolved in the hydrogen flow, The electrolytic bath containing hydrogen. The method according to claim 1,
And the second flow path of the second housing is connected to the second flow path of the second housing and the second flow path of the second housing is connected to the anode electrode plate And oxygen water containing oxygen ions is generated in the purified water while the oxygen water is discharged out of the outlet through the third flow path of the second housing,
The hydrogen gas generated in the second flow path of the second enclosure is electrolyzed and the hydrogen gas generated in the second flow path of the first enclosure is transferred to the second flow path of the first enclosure through the separation membrane, Wherein the hydrogen storage tank is moved out of the outlet of the housing and stored in the hydrogen tank or dissolved in the purified water to generate hydrogenated water. delete

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