KR101320463B1 - Apparatus for manufacturing hydrogen water - Google Patents

Abstract

Hydrogen water production apparatus is disclosed. Hydrogen water production apparatus according to an embodiment of the present invention, an apparatus for producing hydrogen water by electrolysis of water, the container is filled with water; First and second electrodes provided in the container; And a power supply unit supplying DC power to the first and second electrodes, wherein the first electrode comprises: a first base electrode; And a plurality of first branches, one end of which is connected to the first base electrode, respectively, sequentially disposed on both sides of the first base electrode along the length direction of the first base electrode, and each having the same center and a different sized radius. An electrode, wherein the second electrode comprises: a second base electrode; And a plurality of second branches, one end of which is connected to the second base electrode, respectively, sequentially disposed on both sides of the second base electrode along the length direction of the second base electrode, and each having the same center and a different sized radius. The first electrode and the second electrode are disposed such that the second branch electrodes are respectively positioned in the space between the first branch electrodes.

Description

Hydrogen water production device {APPARATUS FOR MANUFACTURING HYDROGEN WATER}

The present invention relates to an apparatus for producing hydrogen water, and more particularly, to an apparatus for producing hydrogen water by dissolving hydrogen generated by electrolysis in raw water.

In general, hydrogen water is produced by a method such as magnetization, sonication, ore treatment, mineral treatment, or electrolysis. Among these methods, an electrolysis method is mainly used, and the hydrogen water produced by electrolysis is called electrolytic hydrogen water.

Electrolytic hydrogen water is called alkaline ionized water or hydrogen rich water, and can be used for drinking water, beauty, industrial and agricultural use, and the like. Specifically, the electrolytic hydrogen water is effective in dermatitis such as atopic dermatitis, skin whitening, aging, lifestyle disease, etc., can be used in cosmetics as an anti-aging and moisturizing effect, and has superior cleaning power than ultrapure water in the technical field of semiconductors and displays, It has an effect of accelerating growth and preventing pests in agriculture (including hydroponic cultivation), and has an excellent effect on long-term preservation of foodstuffs.

By the way, the conventional hydrogen water production apparatus has the following problems.

The interior of the electrolytic container also serves as an electrolytic chamber using a metal electrode and an activated carbon porous body as an electrode, and a purification chamber made of an activated carbon porous body. In particular, by using the activated carbon porous body as an electrode, the voltage drop due to the resistance of raw water is reduced. It becomes large and this reduces electrolytic efficiency.

When the current density is increased to increase the electrolytic efficiency, the surface of the activated carbon porous body is modified to easily change electrical characteristics.

Since the direct current voltage is used as the electrolytic voltage, calcium carbonate is produced from the calcium dissolved in raw water, precipitates on the surface of the negative electrode, adversely affects the electrolytic efficiency, or adheres to the activated carbon porous body, thereby adversely affecting the filtration performance. For this reason, maintenance work which regularly washes an electrode and removes calcium carbonate using an acidic chemical agent (for example, citric acid etc.) is necessary.

Increasing the electrolytic current value tends to generate calcium carbonate, so it is necessary to proceed electrolysis over a long time with a weak current of 200 mA or less, and it is difficult to generate a large amount of hydrogen gas in a short time.

Embodiment of the present invention, to improve the electrolysis efficiency, to reduce the power consumption, to provide a hydrogen water production apparatus that can minimize the production cost.

According to an aspect of the present invention, there is provided an apparatus for producing hydrogen water by electrolyzing water, the container is filled with water; First and second electrodes provided in the container; And a power supply unit supplying DC power to the first and second electrodes, wherein the first electrode comprises: a first base electrode; And one end connected to each of the first base electrodes, and sequentially arranged on both sides of the first base electrode along a length direction of the first base electrode, and each having a same center and a different sized radius. A first branch electrode, wherein the second electrode comprises: a second base electrode; And one end connected to each of the second base electrodes, the second base electrodes being sequentially staggered on both sides of the second base electrode along the length direction of the second base electrode, and each having a same center and a different sized radius. A hydrogen water production apparatus may include a second branch electrode, wherein the first electrode and the second electrode are disposed such that the second branch electrodes are respectively positioned in a space between the first branch electrodes.

The apparatus for producing hydrogen water may include: a detector configured to measure an impedance of the water; And a controller configured to receive a detection signal for the impedance of the water from the detection unit, and to control the electrolysis process of the water based on the detection signal.

The control unit may control the power supply unit so that the voltage of the DC power supplied to the first and second electrodes is adjusted.

The detector may measure an impedance of the water by measuring a current flowing between the first electrode and the second electrode.

The apparatus for producing hydrogen water further includes a switching unit that turns on / off the supply of the DC power and alternates a positive (+) polarity and a negative (−) polarity of the DC power, and the control unit May control the on / off of the switching unit to adjust the electrolysis time of the water.

The hydrogen water production apparatus may further include a display unit configured to receive a control signal from the controller and display an elapsed time and an end of the electrolysis.

The apparatus for producing hydrogen water may further include a magnesium hydrogen generator, which is provided in the container and generates hydrogen by a dissolution reaction by contact with the water.

The apparatus for producing hydrogen water may further include a filter provided in the container and configured to adsorb and remove a gas including oxygen, carbon dioxide, chlorine, and a volatile substance.

The apparatus for producing hydrogen water may further include a magnetic body that applies a magnetic field to the water such that the water is magnetized water.

The apparatus for producing hydrogen water may further include a vibrator for applying vibration to the water so that the water becomes wave water.

The apparatus for producing hydrogen water includes: an electrode support member supporting the first and second electrodes and coupled to the bottom wall through a hole formed in the bottom wall of the container; First and second conducting members provided in a portion of the electrode supporting member penetrating the hole and electrically connected to the first and second electrodes, respectively; A base on which the container is placed; And first and second connectors provided on an upper surface of the base and electrically connecting the first and second conducting members and the power supply unit.

The apparatus for producing hydrogen water may further include a waterproof pad provided between an upper surface of the bottom wall and the electrode support member to prevent leakage of the water through the hole.

According to an exemplary embodiment of the present invention, a DC power is applied while alternating a positive (+) polarity and a negative (−) polarity to the electrode, thereby preventing impurities from adhering to the electrode.

And, according to an embodiment of the present invention, by measuring the impedance of the water to automatically adjust the electrolysis time, it is possible to increase the user convenience, and do not perform the electrolysis more than necessary to reduce the power consumption.

In addition, according to an embodiment of the present invention, by measuring the impedance of the water can adjust the voltage of the DC power applied to the electrode.

In addition, according to an embodiment of the present invention, the electrode can be arranged in a symmetrical structure to improve the electrolytic efficiency.

1 is a perspective view of a hydrogen water production apparatus according to an embodiment of the present invention.
2 is a cross-sectional view showing the internal configuration of the container and the base of FIG.
3 is an exploded perspective view of the hydrogen water production apparatus of FIG. 1.
4 is a plan view of the electrode of FIG. 3.
5 is a view showing a bonding state of the electrode.
6 is a block diagram showing a power system and a control system of the hydrogen water production apparatus according to an embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention is capable of various modifications and various embodiments, and specific embodiments are illustrated in the drawings and described in detail in the detailed description. It is to be understood, however, that the invention is not to be limited to the specific embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The terminology used herein is for the purpose of illustrating embodiments and is not intended to be limiting of the present invention. In the present specification, the singular form includes plural forms unless otherwise specified in the specification.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. Referring to the accompanying drawings, the same or corresponding components are denoted by the same reference numerals, do.

1 is a perspective view of a hydrogen water production apparatus 1 according to an embodiment of the present invention.

Referring to FIG. 1, the hydrogen water producing apparatus 1 is for producing hydrogen water by producing hydrogen by electrolysis of water and dissolving the generated hydrogen in water again, and the container 10 and the cover 20. ) And the base 30.

The vessel 10 may have a hollow cylindrical shape with an open top and accommodates water that is electrolyzed. The container 10 may be provided with a transparent material to visually confirm that hydrogen generated by electrolysis of water is dissolved in water.

The side wall of the container 10 may be coupled to the handle 12 for the user to grip the container 10, the discharge port 14 for discharging hydrogen water is formed at the upper end of the container (10).

The cover 20 opens and closes the open upper portion of the container 10.

The base 30 may include a holder 32 on which the container 10 is placed, and an input / output unit 36 on which the input unit 33 and the display unit 35 are installed. An electric power system and a control system are provided inside the holder 32, and the electric power system and the control system supply DC power for electrolysis of water to electrodes (not shown) in the container 10.

The input unit 33 may be provided in the form of a button, and the operation of the hydrogen water producing apparatus 1 is started by pressing the input unit 33. The display unit 35 may be provided as a plurality of light emitting diodes (LEDs), turned on with the start of operation of the hydrogen water production apparatus 1, and may be gradually turned off one by one as the operation of the hydrogen water production apparatus 1 progresses. have.

2 is a cross-sectional view showing the internal configuration of the container and the base of FIG. 3 is an exploded perspective view of the hydrogen water production apparatus of FIG. 1. 4 is a plan view of the electrode of FIG. 3. And, Figure 5 is a view showing the bonding state of the electrode.

2 to 5, first and second electrodes 100a and 100b are provided inside the container 10. The first and second electrodes 100a and 100b may be made of titanium plated with platinum.

For example, as shown in FIG. 4, the first electrode 100a may include a first base electrode 110a and a plurality of first branch electrodes 120a, 130a, 140a, and 150a. The first base electrode 110a may have a rod shape, and the first branch electrodes 120a, 130a, 140a, and 150a may be provided in a semicircle shape having the same center and different radii of different sizes. The first branch electrodes 120a, 130a, 140a, and 150a are alternately disposed on both sides of the first base electrode 110a in the longitudinal direction of the first base electrode 110a, and one end thereof is alternately disposed. May be connected to 110a.

The second electrode 100b may include a second base electrode 110b and a plurality of second branch electrodes 120b, 130b, 140b, and 150b. The second base electrode 110b may have a rod shape, and the second branch electrodes 120b, 130b, 140b, and 150b may be provided in a semicircle shape having the same center and different radii of different sizes. The second branch electrodes 120b, 130b, 140b, and 150b are alternately disposed on both sides of the second base electrode 110b in the longitudinal direction of the second base electrode 110b, and one end thereof is alternately disposed. May be connected to 110b.

The first electrode 100a and the second electrode 100b having the above-described configuration may include the second branch electrodes 120b, 130b, 140b, in a space between the first branch electrodes 120a, 130a, 140a, and 150a. 150b) may be arranged to be positioned respectively. By this arrangement structure, the first branch electrodes 120a, 130a, 140a and 150a and the second branch electrodes 120b, 130b, 140b and 150b may be symmetrical to each other. When the first branch electrodes 120a, 130a, 140a and 150a and the second branch electrodes 120b, 130b, 140b and 150b are symmetrical with each other, hydrogen is constantly generated by electrolysis of water, thereby improving electrolytic efficiency. Can be.

The first and second electrodes 100a and 100b may be supported by the electrode support member 200. The electrode support member 200 may include an upper support member 220, an electrode cap 240, and a lower support member 260. The upper support member 220 and the electrode cap 240 are provided inside the container 10, and the lower support member 260 is provided below the bottom wall of the container 10.

The upper support member 220 is a horizontal plate 222 in the shape of a circular plate, a side plate 224 extending vertically upward from the periphery of the edge of the horizontal plate 222, and vertically downward from the central region of the horizontal plate 222. It has a coupling portion 226 extending.

Coupling portion 226 may have a cylindrical shape. A male thread 227 may be formed on the outer circumferential surface of the coupling part 226, or a silicone O-ring may be inserted to waterproof and fix the coupling part 226. The first and second coupling holes 228a and 228b through which the first and second conducting members 300a and 300b to be described later are inserted are formed in the horizontal plate 222 and the coupling part 226.

The first and second electrodes 100a and 100b rest on the horizontal plate 222 of the upper support member 220 and are to be coupled to the horizontal plate 222 by the first and second fastening bolts 229a and 229b. Can be. The electrode cap 240 may be coupled to the upper portions of the first and second electrodes 100a and 100b coupled to the horizontal plate 222.

The lower support member 260 may be provided in a circular plate shape, and the female screw 262 to which the male screw 227 of the engaging portion 226 of the upper support member 220 is fastened to the central region of the lower support member 260. Is formed.

 The coupling portion 226 of the upper support member 220 to which the first and second electrodes 100a and 100b are coupled is inserted through the hole 16 formed in the bottom wall of the container 10. At this time, the waterproof pad 270 may be provided between the bottom wall of the container 10 and the horizontal plate 222 of the upper support member 220 to prevent leakage of water through the hole 16.

The lower support member 260 is disposed below the bottom wall of the container 10, and the male screw 227 of the engaging portion 226 is fastened to the female screw 242 of the lower support member 260. In addition, the lower support member 260 may be provided with a magnetic body 290, which applies a magnetic field to the water such that the water in the container 10 is magnetized water.

The first and second electrodes 100a and 100b are supplied with direct current power from a power system provided to the base 30 by the first and second conducting members 300a and 300b. The first conducting member 300a may be electrically connected to the first electrode 100a, and the second conducting member 300b may be electrically connected to the second electrode 100b. Since the structure of the 1st electricity supply member 300a and the 2nd electricity supply member 300b is the same, only the 1st electricity supply member 300a is demonstrated below.

The first conducting member 300a may include a first power supply pin 310a, a first spring 320a, and a first connection bolt 330a. The first power supply pin 310a, the first spring 320a, and the first connecting bolt 330a are coupled to the first coupling hole 228a of the upper support member 220. Specifically, the first power supply pin 310a is inserted through the upper end of the first coupling hole 228a and then positioned at the lower end of the first coupling hole 228a, and the lower end of the first power supply pin 310a is external. Is exposed. The first spring 320a is inserted into the first coupling hole 228a to be in contact with the top of the first power supply pin 310a, and the first connecting bolt 330a is in contact with the top of the first spring 320a. It is coupled to the upper end of the first coupling hole 228a. The upper end of the first connecting bolt 330a is in contact with the first electrode 100a.

The first connection bolt 330a may have a cylindrical shape. Male threads are formed on the outer circumferential surface of the first connecting bolt 330a, and female threads are formed inside the first connecting bolt 330a. The male screw of the first connecting bolt 330a is fastened to the female screw formed in the first coupling hole 228a of the upper support member 220, and the female screw of the first connecting bolt 330a is fixed to the first electrode 100a. The first fastening bolt 229a for fastening.

Here, reference numeral 310b, which is not described, is the second power supply pin of the second conducting member 300b, reference numeral 320b is the second spring of the second conducting member 300b, and reference numeral 330b is the second It is the 2nd connection bolt of the electricity supply member 300b.

As shown in FIG. 3, the cover 20 opens and closes the open top of the container 10. In addition, the filter 20 and the magnesium hydrogen generator 420 may be coupled to the cover 20. The filter 400 and the magnesium hydrogen generator 420 may protrude from the cover 20 in the direction toward the container 10 and may be immersed in water filled in the container 10.

The filter 400 may contain a deodorant such as activated carbon, illite, zeolite, and the like, and may adsorb and remove gases including oxygen, carbon dioxide, chlorine, or volatile substances contained in the water of the vessel 10. have.

The magnesium hydrogen generator 420 may be manufactured in a circular, granular, rod or plate form by mixing magnesium alone or at least one of magnesium and coral, elvan, ceramic, elite and zeolite, and may be made of plastic or stainless steel. It can be stored in a pressure vessel. The magnesium hydrogen generator 420 may generate hydrogen by a dissolution reaction by contact with water in the vessel 10, thereby increasing the dissolved hydrogen concentration of the water.

Meanwhile, the container 10 is placed on the mounting portion 32 of the base 30. In addition, the input / output unit 36 or the mounting unit 32 of the base 30 may be provided with a vibrator 500 that vibrates water so that the water in the container 10 becomes a wave water. . Here, the frequency of the vibrator 500 may be a curse pile of several tens of Hz band.

First and second connectors 600a and 600b are provided on an upper surface of the mounting portion 32 of the base 30, and a power system for supplying DC power and a control system for controlling the same may be provided inside the mounting portion 32. Can be.

The first connector 600a may contact the first power supply pin 310a to electrically connect the first electrode 100a to the power system, and the second connector 600b may be connected to the second power supply pin 310b. In contact, the second electrode 100b may be electrically connected to the power system.

6 is a block diagram showing a power system and a control system of the hydrogen water production apparatus according to an embodiment of the present invention.

Referring to FIG. 6, the input unit 33 transmits an operation start signal to the control unit 710. When the operation start signal is transmitted to the control unit 710, the control unit 710 controls the operation of the power supply unit 720 and the switching unit 730, so that the DC power source for electrolysis of water is supplied to the first and second electrodes 100a, 100b).

The power supply unit 720 supplies DC power for driving electrodes to the first and second electrodes 100a and 100b and DC power for driving the controller to the controller 710.

The switching unit 730 is provided between the power supply unit 720 and the first and second electrodes 100a and 100b. The switching unit 730 turns on / off the supply of DC power for driving the first and second electrodes 100a and 100b, and the first and second electrodes 100a and 100b. The positive and negative polarities of the DC power supply can be alternated periodically. In addition, between periodic alternating polarities, the supply of the DC power may be interrupted for the predetermined time for the first and second electrodes 100a and 100b.

When the polarity of the DC power applied to the first and second electrodes 100a and 100b is periodically alternated by the switching unit 730, impurities such as calcium carbonate are attached to the first and second electrodes 100a and 100b. Can be prevented, whereby the electrolytic efficiency can be improved.

The detector 740 may measure the current flowing between the first electrode 100a and the second electrode 100b to measure the impedance of water that is electrolyzed. The detection signal for the impedance of the water is transmitted to the controller 710.

The controller 710 may receive the detection signal for the impedance of the water from the detector 740, and generate a control signal for controlling the power supply unit 720 and the switching unit 730 based on the detection signal.

For example, the controller 710 may control the power supply unit 720 to adjust the voltage of the DC power supplied to the first and second electrodes 100a and 100b based on the detection signal of the detection unit 740. Can be. When the impedance of the water is greater than the predetermined reference value, that is, the resistance to the electrolysis of the water is large, the controller 710 may control the power supply unit 720 to supply a strong current by increasing the voltage. On the contrary, when the impedance of the water is smaller than the predetermined reference value, that is, the resistance to the electrolysis of the water is small, the controller 710 may control the power supply unit 720 to supply a weak current by lowering the voltage.

In addition, the controller 710 may control the on / off of the switching unit 730 to adjust the electrolysis time of water based on the detection signal of the detector 740. When the impedance of the water is larger than the preset reference value, the controller 710 may control the on / off of the switching unit 730 to increase the electrolysis time. On the contrary, when the impedance of the water is smaller than the preset reference value, the controller 710 may control the on / off of the switching unit 730 to shorten the electrolysis time.

The display unit 35 may include a plurality of light emitting diodes (LEDs) and display the start, progress, and end of the electrolysis process of water by a control signal of the controller 710. The display unit 35 may be turned on when the input unit 33 transmits an operation start signal to the control unit 710, and may be gradually turned off one by one as time passes during the electrolysis process of water. The display unit 35 may be turned off when the electrolysis process is completed.

Although not shown in FIG. 6, the first and second conducting members 300a and 300b and the first and second connectors 600a and 600b described above with reference to FIGS. 2 to 5 may be connected to the switching unit 730. It is located between the first and second electrodes 100a and 100b.

While the present invention has been described in connection with certain exemplary embodiments thereof, it will be apparent to those skilled in the art that various changes and modifications may be made without departing from the scope of the present invention as defined in the appended claims. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

10: container 20: cover
30: base 33: input unit
35: display portion 100a: first electrode
100b: second electrode 200: electrode support member
270: waterproof pad 290: magnetic material
300a: first energizing member 300b: second energizing member
400: filter 420: magnesium hydrogen generator
500: oscillator 600a: first connector
600b: second connector 710: control unit
720: power supply unit 730: switching unit
740: detector

Claims (12)

In the apparatus for producing hydrogen water by electrolysis of water,
A container filled with the water;
First and second electrodes provided in the container; And
A power supply unit supplying direct current power to the first and second electrodes,
Wherein the first electrode comprises:
A first base electrode; And
A plurality of first ends of which are connected to the first base electrodes, respectively, sequentially disposed on both sides of the first base electrode along a length direction of the first base electrode, and each having the same center and a different sized radius; Including a branch electrode,
The second electrode,
A second base electrode; And
A plurality of first ends of which are connected to the second base electrode, the second base electrode being alternately disposed on both sides of the second base electrode in the longitudinal direction of the second base electrode, and having the same center and different radiuses, respectively; Includes a two branch electrode,
The first electrode and the second electrode,
The apparatus for producing hydrogen water, wherein the second branch electrodes are disposed in the space between the first branch electrodes, respectively. The method of claim 1,
A detector configured to measure an impedance of the water; And
Receiving a detection signal for the impedance of the water from the detection unit, based on the detection signal, further comprising a control unit for controlling the electrolysis process of the water, hydrogen water production apparatus. 3. The method of claim 2,
The control unit,
Hydrogen water production apparatus for controlling the power supply unit so that the voltage of the DC power supplied to the first and second electrodes is adjusted. 3. The method of claim 2,
The detection unit, the hydrogen water production apparatus for measuring the impedance of the water by measuring the current flowing between the first electrode and the second electrode. 3. The method of claim 2,
It further comprises a switching unit for turning on (on) / off (Off) the supply of the DC power, and alternating the positive (+) and negative (-) polarity of the DC power,
The control unit,
Hydrogen water production apparatus for controlling the on / off of the switching unit to adjust the electrolysis time of the water. 3. The method of claim 2,
Receiving a control signal from the control unit, and further comprising a display unit for displaying the elapsed time and the end of the electrolysis, hydrogen water production apparatus. The method of claim 1,
And a magnesium hydrogen generator which is provided in the vessel and generates hydrogen by a dissolution reaction by contact with the water. The method of claim 1,
And a filter provided in the vessel, the filter comprising adsorptive removal of gas containing oxygen, carbon dioxide, chlorine and volatiles. The method of claim 1,
The apparatus for producing hydrogen water, further comprising a magnetic body that applies a magnetic field to the water such that the water is magnetized water. The method of claim 1,
The apparatus for producing hydrogen water, further comprising a vibrator for applying vibration to the water so that the water becomes wave water. The method of claim 1,
An electrode support member supporting the first and second electrodes and coupled to the bottom wall through holes formed in the bottom wall of the container;
First and second conducting members provided in a portion of the electrode supporting member penetrating the hole and electrically connected to the first and second electrodes, respectively;
A base on which the container is placed; And
And a first and second connectors provided on an upper surface of the base and electrically connecting the first and second conducting members and the power supply unit. The method of claim 11,
And a waterproof pad provided between the upper surface of the bottom wall and the electrode support member to prevent leakage of the water through the hole.

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