KR20200006785A - Injection Device of Hydrogeen water Mist - Google Patents

Abstract

The present invention relates to a hydrogen mist spray device which improves the efficiency of oxidation and reduction reactions. The hydrogen mist spray device of the present invention comprises: an electrolytic bath installed inside a main body; an ultrasonic vibrator installed in the electrolytic bath; a pair of electrolysis electrodes installed in an electrolysis chamber; an on/off manipulation unit having an on/off switch; and a power supply unit.

Description

Injection Device of Hydrogeen water Mist

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hydrogen water mist spraying apparatus, and more particularly, to an apparatus for spraying hydrogen mist after generating hydrogen water.

As interest in health increases, functional water having a function that is beneficial to health goes beyond drinking water to be purified. Recently, hydrogen water has attracted attention as one of the functional water.

Hydrogen water is water in which hydrogen is dissolved in a high dissolved amount. It prevents aging, prevents diabetes, hypertension, arteriosclerosis, cancer, and dementia, skin care, diet, fatigue, sexual function, exercise ability, and immunity. Effective for reinforcement and hangover

A device for producing such hydrogen water is widely used, and recently, a hydrogen water mist spraying device that generates hydrogen water for cosmetic purposes and sprays it in a mist (fog or mist) state has been devised and used.

12 is a sectional view of a conventional hydrogen water mist spraying device, and FIG. 13 is a cross-sectional view of main parts of a conventional hydrogen water mist spraying device.

As shown in these figures, the conventional hydrogen water mist spraying device has a concave main body 111 open to the upper end, an electrolytic cell 120 and an ultrasonic vibrator 171 provided on the main body 111. And, the pumping unit 180 installed in the electrolytic cell 120, the upper cap 191 coupled to the electrolytic cell 120 to surround the pumping unit 180, the operation of the ultrasonic vibrator 171 and the electrolysis electrode 130 Has an on / off switch 141 for turning on / off the operation of the < RTI ID = 0.0 >), < / RTI >

The main body 111 has the injection guide hole 111a formed in the side wall, and the intermediate storage chamber 111h is formed in the rear region of the injection guide hole 111a.

The electrolytic cell 120 has an electrolytic chamber 121 having an electrolytic chamber 121a formed therein and a neck 126 formed at an upper end of the electrolytic chamber 121.

The electrolytic chamber portion 121 is a bottom electrolytic chamber portion 121b having a concave shape, a tubular upper electrolytic chamber portion 121c coupled to an upper end of the lower electrolytic chamber portion 121b, and a bottom of the lower electrolytic chamber portion 121b. It has the electrode seating groove part 121d of the upward opening formed in the surface.

 The ultrasonic vibrator 171 mists the hydrogen water stored in the intermediate storage chamber 111h and sprays it to the outside through the injection guide hole 111a. Since the ultrasonic vibrator 171 having such a function is widely known in the art, detailed description thereof will be omitted.

The pumping part 180 includes an inner cap 181 coupled to the neck 126, a nozzle hole 182a, and a guide tube part 182 installed on an upper surface of the inner cap 181, and a guide tube part 182. It has a button 183 provided in the, and the pumping pipe 184 is installed so that the lower end reaches the electrolytic chamber 121a through the guide tube portion 182, the electrolytic chamber 121a in conjunction with the pressing operation of the button 183 The hydrogen water is pumped inside to operate through the nozzle hole 182a.

The pair of electrolysis electrodes 130 are provided in the electrode seating grooves 121d to be disposed up and down.

Each electrolysis electrode 130 may be made of a material such as titanium, as is widely known in the art, and the surface may be plated with platinum.

An insulating member is provided between the pair of electrolysis electrodes 130.

On-off switch 141 is implemented by a push button method.

The power supply unit (not shown) has a battery (not shown) and a PC ratio (not shown) installed inside the main body 111, and a voltage conversion unit (not shown) provided in the PC ratio (not shown).

A battery (not shown) is installed below the electrolytic cell 120.

A PCB (not shown) is installed below the electrolytic cell 120.

The voltage converter (not shown) converts the voltage of the battery (not shown) into the operating voltage of the ultrasonic vibrator 171 and the electrolysis electrode 130. Since the voltage conversion unit (not shown) having such a configuration is widely known in the art, detailed description thereof will be omitted.

The power supply unit (not shown) having such a configuration applies an operating voltage to the ultrasonic vibrator 171 and the electrolysis electrode 130 when the on-off switch 141 is pressed, and presses the on-off switch 141. When this is released, the operating voltage applied to the ultrasonic vibrator 171 and the electrolysis electrode 130 is blocked.

The operation of the conventional hydrogen water mist spray device having the above-described configuration will be described below. For convenience of explanation, it is assumed that the on-off switch 141 is disposed in the off position.

First, the upper cap 191 and the pumping unit 180 are separated from the electrolytic chamber 121, and then water is stored in the electrolytic chamber 121a.

Next, the on-off switch 141 is pressed to move to the on position.

When the on-off switch 141 is moved to the on position, an operating voltage is applied to the electrolysis electrode 130 and the ultrasonic vibrator 171 from a power supply unit (not shown).

When operating voltage is applied to the electrolysis electrode 130, hydrogen water is generated in the electrolytic chamber 121a.

When the operating voltage is applied to the ultrasonic vibrator 171, the hydrogen water generated in the electrolytic chamber 121a is discharged to the outside through the mist injection guide hole 111a.

Next, the pressing operation on the on-off switch 141 is released to move to the off position.

When the on-off switch 141 is moved to the off position, the operating voltage applied to the electrolysis electrode 130 and the ultrasonic vibrator 171 is cut off from the power supply unit (not shown).

When the operating voltages applied to the electrolysis electrode 130 and the ultrasonic vibrator 171 are blocked, the hydrogen water generation operation in the electrolytic chamber 121a and the misting operation by the ultrasonic vibrator 171 are also stopped.

However, according to the conventional hydrogen water mist spraying device, a pair of electrolysis electrodes 130 are disposed so as to be disposed up and down in the electrode seating groove portion 121d (parallel to the bottom surface of the electrolyte chamber part), so that water electrolysis occurs. Of products (including hydroxide ions and hydrogen when the lower electrolysis electrode is the cathode, hydrogen ions and oxygen when the lower electrolysis electrode is the anode) and other substances (including substances that act as electrolytes during electrolysis) The product generated during electrolysis moves to the bottom of the upper electrolysis electrode and is oxidized by the upper electrolysis electrode 130 (when the upper electrolysis electrode is the anode) or the reduction reaction (the upper electrolysis electrode). In the case of the negative electrode), the efficiency is lowered, and there is a problem that the amount of foreign matter attached to the upper electrolysis electrode is increased. If the amount of foreign matter attached to the upper electrolysis electrode increases. Secondary problems arise that the service life is reduced and the spacing between the electrolysis electrodes 130 is not uniform.

In addition, since the pair of electrolysis electrodes 130 are installed to be disposed up and down in the electrode seating grooves 121d, it is difficult to form the electrolysis electrodes 130 in various forms (only in a flat form).

In addition, since the pair of electrolysis electrodes 130 are installed to be disposed up and down in the electrode seating groove portion 121d, there is a problem that it is difficult to install the electrolysis electrodes 130.

In addition, there is a problem that the wiring work between the power supply and the electrolysis electrode 130 is difficult because it is difficult to access the lower electrolysis electrode 130.

Related prior documents include Korean Patent Publication No. 10-1783366 (Registration date September 25, 2017, the name of the invention: apparatus for hydrogen water injection and mist supply using a membrane-free hydrogen water generation module and ultrasonic oscillator injection module) In the above-mentioned prior art, a technique related to the conventional hydrogen water mist spraying apparatus described above is disclosed.

Accordingly, an object of the present invention is to improve the efficiency of the oxidation reaction and the reduction reaction by the electrolysis electrode, to reduce the amount of foreign matter attached to the electrolysis electrode and to install the electrolysis electrode and wiring work between the power supply and the electrolysis electrode It is to provide a hydrogen water mist spraying device to facilitate the formation of various types of electrolysis electrodes.

The above object is, according to the present invention, in the hydrogen water mist spraying apparatus having a main body of a concave shape in which injection guide holes are formed in a side wall, an electrolytic chamber of an upward opening is formed in a concave shape. Hydrogen water discharge holes communicating with the electrolytic chamber are formed on the sidewalls, and an electrolytic chamber portion having a pair of electrode exposure holes is formed on the bottom surface thereof, and the hydrogen water discharge holes face the injection guide holes. An electrolytic cell installed in the; An ultrasonic vibrator installed in the electrolytic cell to mist the hydrogen water discharged through the hydrogen water discharge hole and spray the hydrogen water to the outside through the injection guide hole; And a contact terminal formed on an electrode body portion and a lower end of the electrode body portion, wherein the contact terminal is exposed beyond the bottom surface of the electrolytic cell through the electrode exposure hole and the electrode body portion is disposed perpendicular to the bottom surface of the electrolytic chamber portion. A pair of electrolysis electrodes provided in the electrolytic chamber; An on-off operation unit having an on-off switch installed in the main body, for on-off operation of the operation of the ultrasonic vibrator and the electrolysis electrode; An operating voltage is applied to the ultrasonic vibrator and the electrolysis electrode when the on-off switch is operated in an on state, and an operating voltage applied to the ultrasonic vibrator and the electrolysis electrode when the on-off switch is operated in an off state. It is achieved by a hydrogen water mist spray device characterized in that it comprises a power supply unit operable to shut off.

The lower opening is formed to be connected to the upper opening and the upper opening and smaller than the upper opening so that water can be easily injected into the electrolytic chamber and the oxygen generated during electrolysis can be efficiently discharged. It is preferable that the cover further includes a cover body coupled to the upper end of the body cover is formed so that the opening is in communication with the electrolytic chamber, the gas discharge hole is formed and the upper opening of the body cover.

And the electrolytic cell is a socket portion having a socket bottom surface portion extending outward from the upper outer surface of the electrolytic chamber portion and a socket side wall portion extending upward from the circumferential edge of the socket bottom surface to improve the sealing of the electrolytic chamber, An electrolytic chamber sealing ring installed on an upper surface of the socket bottom surface portion; The main body cover has a concave shape and has a main body cover body portion having a cover through hole formed therein and a fastening tube portion extending from the main body cover body so as to communicate with the cover through hole. It is preferable that the socket-side wall portion is provided and the lower end of the fastening tube portion is in contact with the electrolytic chamber sealing ring.

In addition, in order to further improve the efficiency of the oxidation reaction and the reduction reaction by the electrolysis electrode, it is preferable that the electrode separation protrusion for separating the electrode body portion from the bottom surface of the electrolytic chamber is preferably formed in the electrolytic chamber portion.

In addition, the electrolytic cell is equipped with a pair of packings formed to surround the electrode exposure hole on the bottom surface of the electrolytic chamber so as to prevent leakage caused by the installation structure of the electrolysis electrode passing through the bottom surface of the electrolytic chamber. It is preferable to further include a packing installed in the tube and the packing mounting tube one by one.

Therefore, according to the present invention, by placing a pair of electrolysis electrodes in the electrolytic chamber so that the electrode body portion is disposed perpendicular to the bottom surface of the electrolytic chamber portion and the contact terminal is exposed to the outside through the bottom surface of the electrolytic chamber portion, Can improve the efficiency of oxidation and reduction reactions, reduce the amount of foreign matter attached to the electrolysis electrode, facilitate the installation of the electrolysis electrode and wiring work between the power supply and the electrolysis electrode, and Can be formed.

When the amount of foreign matter attached to the electrolysis electrode is reduced, the secondary effect of increasing the service life and maintaining the spacing between the electrolysis electrodes can be obtained.

1 is a combined perspective view of a hydrogen water mist spray apparatus according to an embodiment of the present invention;
2 and 3 are exploded perspective views of the hydrogen water mist spraying apparatus according to an embodiment of the present invention, respectively;
4 is a cross-sectional view of a hydrogen water mist spraying apparatus according to an embodiment of the present invention;
5 is a view showing the inside of the body by partially cutting the body according to an embodiment of the present invention;
6 is a view showing an on-off control unit area according to an embodiment of the present invention;
7, 8 and 9 show the electrolytic cell region according to the embodiment of the present invention, respectively.
10 is a view showing a main body cover according to an embodiment of the present invention;
11 is a view showing a method of using a hydrogen water mist spray device according to an embodiment of the present invention;
12 is a cross-sectional view of a conventional hydrogen water mist spray device;
Fig. 13 is a sectional view showing the main parts of a conventional hydrogen water mist spraying device.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a combined perspective view of a hydrogen water mist spray device according to an embodiment of the present invention, Figures 2 and 3 are exploded perspective views of the hydrogen water mist spray device according to an embodiment of the present invention, Figure 4 is a 5 is a cross-sectional view of the hydrogen water mist spraying apparatus according to an embodiment, and FIG. 5 is a view showing the inside of the main body by partially cutting the main body according to an embodiment of the present invention, and FIG. 6 is an on-off operation unit according to an embodiment of the present invention. 7, 8 and 9 show the electrolytic cell area according to the embodiment of the present invention, and FIG. 10 shows the main body cover according to the embodiment of the present invention.

As shown in these drawings, the hydrogen water mist spraying device according to the embodiment of the present invention includes a main body 11 having a concave shape, an electrolyzer 20 and an ultrasonic vibrator 71 provided in the main body 11. And a main body cover 72 installed to be supported by the main body 11, a cover cap 73 coupled to an upper end of the main body cover 72, and a pair of electrolysis electrodes 30 installed inside the electrolytic cell 20. And an operating voltage is applied to the on / off control unit 40 for turning on / off the operation of the ultrasonic vibrator 71 and the operation of the electrolysis electrode 30, and to the ultrasonic vibrator 71 and the electrolysis electrode 30. Has a power supply unit 50.

The main body 11 has a spray guide hole (11a) is formed on the side wall,

The main body 11 has a pair of sliding guide grooves 11b and locking member guide grooves 11e formed below the injection guide hole 11a.

The pair of sliding guide grooves 11b are formed along the height direction of the main body 11.

One of the pair of sliding guide grooves 11b has a lower section 11d having a wider width than the upper section 11c.

The locking member guide groove 11e is formed between the pair of sliding guide grooves 11b.

The locking member guide groove 11e is formed by cutting off the locking locking groove 11f in the middle region and the locking locking groove 11g in the lower region.

The electrolytic cell 20 includes an electrolytic chamber portion 21 in which an electrolytic chamber 21a of an upward opening is formed in a concave shape, a socket portion 22 extending from an upper end of the electrolytic chamber portion 21, and a socket portion ( An electrolytic chamber sealing ring 23 provided at 22, a pair of packing mounting tube 24 formed at the bottom of the electrolytic chamber portion 21, and a packing 25 provided at the packing mounting tube 24 one by one.

In the electrolytic chamber portion 21, a hydrogen water discharge hole 21b communicating with the electrolytic chamber 21a is formed through the side wall, and a pair of left electrode support grooves 21c are arranged side by side along the height direction on the inner surface of the side wall. Formed.

The electrolytic chamber portion 21 has a pair of right electrode support grooves 21d corresponding to each of the left electrode support grooves 21c in the height direction in a region of the side wall inner surface facing the pair of left electrode support grooves 21c. It is formed side by side.

In the electrolytic chamber portion 21, a pair of electrode exposure holes 21e are formed in the bottom surface thereof.

In the electrolytic chamber portion 21, an electrode separation protrusion 21f is formed on the bottom surface to separate the electrode body 31 from the bottom surface of the electrolytic chamber 21a.

The socket portion 22 includes a socket bottom surface portion 22a extending outward from an outer surface of the upper end of the electrolytic chamber portion 21, and a socket side wall portion 22b extending upwardly from a circumferential edge of the socket bottom surface portion 22a. And the socket flange 22c bent outward from the upper end of the socket side wall portion 22b.

A pair of fastening grooves 22d are formed in the socket side wall portion 22b and the socket flange 22c.

The electrolytic chamber sealing ring 23 is installed on the upper surface of the socket bottom surface portion 22a.

A pair of packing tube 24 is formed to surround the electrode exposure hole (21e).

The packing 25 may be made of an elastic material such as silicon.

The electrolytic cell 20 having such a configuration is installed inside the main body 11 such that the hydrogen water discharge hole 21b faces the injection guide hole 11a.

The ultrasonic vibrator 71 is installed in front of the hydrogen water discharge hole 21b. The initial installation state of the ultrasonic vibrator 71 is maintained by the vibrator cover 75 and the vibrator seating ring 76.

The vibrator cover 75 has a vibrator cover body portion 75a in which a contact hole is formed in the center, and a pair of cover arms 75b extending from the vibrator cover body portion 75a. The vibrator cover 75 is detachably coupled to the electrolytic cell 20 through a cover arm 75b that engages the outer surface of the electrolytic cell 20.

The vibrator seating ring 76 is fastened to the front surface of the vibrator cover body portion 75a.

The ultrasonic vibrator 71 is installed to be immersed in the hydrogen water discharged through the hydrogen water discharge hole 21b and electrically connected to the power supply unit 50 through a wiring path (not shown) formed in the vibrator cover body portion 75a. Connected.

The ultrasonic vibrator 71 mists the hydrogen water discharged through the hydrogen water discharge hole 21b and sprays it to the outside through the injection guide hole 11a. Since the ultrasonic vibrator 71 having such a function is widely known in the art, detailed description thereof will be omitted.

The main body cover 72 has a concave main body cover body portion 72a having a tubular side wall, and a fastening tube portion 72b extending from the main body cover body portion 72a.

The body cover body portion 72a has a cover through hole 72c formed on the bottom surface thereof.

The upper end of the body cover body portion 72a forms an upper opening of the body cover 72.

The fastening tube portion 72b extends from the body cover body portion 72a so as to communicate with the cover through hole 72c.

The fastening pipe portion 72b has a pair of fastening protrusions 72d formed on an outer surface thereof.

The main body cover 72 having such a configuration is coupled to the socket portion 22 by inserting the fastening protrusion 72d into the fastening groove 22d and rotating the same.

The lower end of the body cover body portion 72a forms a lower opening of the body cover 72.

The main body cover 72 having such a configuration is provided so that the fastening pipe portion 72b enters the socket side wall portion 22b and the lower end of the fastening pipe portion 72b contacts the electrolytic chamber sealing ring 23. As a result, the lower opening of the main body cover 72 communicates with the electrolytic chamber 21a.

The cover cap 73 is formed with a gas discharge hole 73a in the central region, and is coupled to the upper end of the body cover body portion 72a to seal the upper opening of the body cover body portion 72a.

Each electrolysis electrode 30 has an electrode body 31 of a plate body and a communication terminal 32 formed at the lower end of the electrode body 31.

The electrode body portion 31 is formed with a plurality of electrode through holes 31a.

In each electrolysis electrode 30 having such a configuration, the left end of the electrode body portion 31 is supported by the left electrode support groove 21c, and the right end of the electrode body portion 31 is the right electrode support groove 21d. It is supported on, and the communication terminal 32 is installed in the electrolytic chamber 21 so as to pass through the electrode exposure hole (21e) and the packing 25 to be exposed beyond the bottom of the electrolytic cell 20.

As the electrolysis electrode 30 is installed so that both ends are supported in the left electrode support groove 21c and the right electrode support groove 21d, the gap between the electrolysis electrodes 30 may be kept constant.

Each electrolysis electrode 30 may be made of a material such as titanium as is widely known in the art, and the surface may be plated with platinum.

The on-off operation part 40 has the on-off switch 41 of the substantially rectangular slider form, the locking member 42 and the magnet 43 provided in the back surface of the on-off switch 41. As shown in FIG.

The on-off switch 41 has a locking member fixing protrusion 41a, a magnet holder 41b, and a pair of sliding guide wall portions 41c formed on the rear surface thereof.

Each sliding guide wall portion 41c is formed at the upper end with a locking step bent outward.

The locking member 42 has a locking member body portion 42a having a fastening hole 42b formed at the center thereof, and a pair of locking member arms 42c extending in the same direction from the locking member body portion 42a. have.

Each locking member arm 42c has a locking protrusion 42d formed on the lower end of the locking member arm 42c.

The locking member 42 is coupled to the locking member fixing protrusion 41a through the fastening hole 42b.

The on-off operation portion 40 having such a configuration allows the sliding guide wall portion 41c and the magnet holder 41b to enter the sliding guide groove 11b, and the locking member 42 to enter the locking member guide groove 11e. Is installed.

Installation of the on-off operation part 40 is made so that the on-off switch 41 may be arrange | positioned in the off position in which the locking protrusion 42d enters the off-locking groove 11f.

The on-off operation part 40 can move to the on position which the locking protrusion part 42d enters the on-locking groove 11g by the operation which presses the on-off switch 41 downward.

The power supply unit 50 has a battery 51 and a PCB 52 installed in the main body 11, a reed switch 53 and a voltage converter (not shown) provided in the PC 52.

The battery 51 is installed below the electrolytic cell 20. An external power source may be used instead of the battery 51.

The PCB 52 is installed below the electrolytic cell 20.

The reed switch 53 is attached to the PC 52 so as to be close to the magnet 43 when the on-off switch 41 reaches the on position. Accordingly, the reed switch 53 is in the on state when the on-off switch 41 is lowered to the on position, and is turned off when the on-off switch 41 is raised from the initial position or the on position to reach the off position. Becomes

The voltage converter (not shown) converts the voltage of the battery 51 into an operating voltage of the ultrasonic vibrator 71 and the electrolytic electrode 30. Since the voltage conversion unit (not shown) having such a configuration is widely known in the art, detailed description thereof will be omitted.

The power supply unit 50 applies an operating voltage to the ultrasonic vibrator 71 and the electrolysis electrode 30 when the reed switch 53 is on, and the ultrasonic vibrator 71 when the reed switch 53 is off. The operation voltage applied to the electrolysis electrode 30 is operated to be cut off.

The operation of the hydrogen water mist spraying apparatus according to the embodiment of the present invention having the above-described configuration will be described with reference to FIG. For convenience of explanation, it is assumed that the on-off switch 41 is disposed in the off position.

First, after removing the cover cap 73, water is injected into the electrolytic chamber 21a.

Next, the on-off switch 41 is pushed downward to move to the on position.

When the on-off switch 41 is moved to the on position, the reed switch 53 is turned on, and thus an operating voltage is applied from the power supply unit 50 to the electrolysis electrode 30 and the ultrasonic vibrator 71.

When an operating voltage is applied to the electrolysis electrode 30, hydrogen and oxygen are generated by the electrolysis operation. Hydrogen water is generated inside the electrolytic chamber 21a by the generated hydrogen, and oxygen is discharged to the outside through the gas discharge hole 73a.

When the operating voltage is applied to the ultrasonic vibrator 71, the hydrogen water generated in the electrolytic chamber 21a is discharged to the outside through the injection guide hole 11a in a misted state.

Next, the on-off switch 41 is pushed upward to move to the off position.

When the on-off switch 41 is moved to the off position, the reed switch 53 is turned off, and thus the operating voltage applied to the electrolysis electrode 30 and the ultrasonic vibrator 71 from the power supply unit 50 is cut off. .

When the operating voltages applied to the electrolysis electrode 30 and the ultrasonic vibrator 71 are cut off, the hydrogen water generation operation in the electrolytic chamber 21a and the misting operation by the ultrasonic vibrator 71 are also stopped.

Meanwhile, in the above-described embodiment, the electrode body part 31 is formed in a planar shape, but the present invention can be implemented by configuring the electrode body part in other forms such as cross section of a tracer and circular cross section.

According to the embodiment of the present invention as described above, the electrode body 31 is disposed perpendicular to the bottom surface of the electrolytic chamber portion 21 and the contact terminal 32 to the outside through the bottom surface of the electrolytic chamber portion 21. By installing a pair of electrolysis electrodes 30 in the electrolytic chamber 21a so as to be exposed, the efficiency of oxidation and reduction reactions by the electrolysis electrodes 30 is improved and the amount of foreign matter attached to the electrolysis electrodes 30 is increased. In addition, the installation of the electrolysis electrode 30 and the wiring work between the power supply unit 50 and the electrolysis electrode 30 can be facilitated, and the shape of the electrode body 31 can be variously formed.

When the amount of foreign matter attached to the electrolysis electrode 30 is reduced, a secondary effect of increasing the service life and maintaining the spacing between the electrolysis electrodes 30 can be obtained.

In addition, the main body cover 72 formed to have a lower opening having a smaller size than the upper opening is installed so that the lower opening communicates with the electrolytic chamber 21a, and the cover cap 73 having the gas discharge hole 73a is formed in the main body cover ( By coupling to the upper end of 72, water can be easily injected into the electrolytic chamber 21a (the upper opening of the body cover is larger than the lower opening), and the oxygen generated during electrolysis can be efficiently discharged.

In addition, by providing the main body cover 72 so that the fastening pipe portion 72b enters the socket side wall portion 22b and the lower end of the fastening pipe portion 72b contacts the electrolytic chamber sealing ring 23, the sealing property of the electrolytic chamber 21a is prevented. This is improved.

In addition, by forming the electrode separation protrusion 21f on the bottom surface of the electrolytic chamber portion 21, the efficiency of the oxidation reaction and the reduction reaction by the electrolysis electrode 30 is further improved (oxidation even at the bottom of the electrolysis electrode. Reaction or reduction reaction).

In addition, since the electrolytic cell 20 is configured to include the packing mounting tube 24 and the packing 25, leakage occurs due to the installation structure of the electrolysis electrode 30 passing through the bottom surface of the electrolytic chamber part 21. Can be prevented.

11, 111: main body 20, 120: electrolytic cell
21, 121: electrolytic chamber part 30, 130: electrolysis electrode
31: electrode body 32: contact terminal
40: on-off control unit 41, 141: on-off switch
42: locking member 43: magnet
50, 150: power supply unit 180: pumping unit

Claims (5)

In the hydrogen water mist spraying device comprising a main body of a concave shape, the injection guide hole is formed in the side wall,
The upstream opening of the electrolytic chamber is formed in a concave shape, and the side wall has an electrolytic chamber portion through which a hydrogen water discharge hole communicating with the electrolytic chamber is formed, and a pair of electrode exposure holes are formed in the bottom surface thereof. An electrolytic cell installed inside the main body such that a hydrogen water discharge hole faces the injection guide hole;
An ultrasonic vibrator installed in the electrolytic cell to mist the hydrogen water discharged through the hydrogen water discharge hole and spray the hydrogen water to the outside through the injection guide hole;
And a contact terminal formed at an electrode body portion and a lower end of the electrode body portion, wherein the contact terminal is exposed beyond the bottom surface of the electrolytic cell through the electrode exposure hole and the electrode body portion is disposed perpendicular to the bottom surface of the electrolytic chamber portion. A pair of electrolysis electrodes provided in the electrolytic chamber;
An on-off operation unit having an on-off switch installed in the main body, for on-off operation of the operation of the ultrasonic vibrator and the electrolysis electrode;
An operating voltage is applied to the ultrasonic vibrator and the electrolysis electrode when the on-off switch is operated in an on state, and an operating voltage applied to the ultrasonic vibrator and the electrolysis electrode when the on-off switch is operated in an off state. Hydrogen water mist spraying device comprising a power supply to operate to be cut off. The method of claim 1,
A main cover which is connected to the upper opening and the upper opening and has a lower opening having a smaller size than the upper opening and is installed to communicate with the electrolytic chamber, and a gas discharge hole is formed and the upper opening of the main cover is formed. Hydrogen water mist spraying device further comprises a cover cap coupled to the top of the body cover to seal the. The method of claim 2,
The electrolytic cell includes a socket portion having a socket bottom portion formed outwardly from an upper outer surface of the electrolytic chamber portion and a socket side wall portion extending upwardly from a circumferential edge of the socket bottom portion; A sealant ring further;
The main body cover has a concave shape and has a main body cover body portion having a cover through hole formed therein and a fastening tube portion extending from the main body cover body to communicate with the cover through hole. Hydrogen water mist spraying device characterized in that it enters the socket side wall portion and is installed such that the lower end of the fastening pipe portion contacts the electrolytic chamber sealing ring. The method according to any one of claims 1 to 3,
And an electrode separation protrusion for separating the electrode body portion from the bottom surface of the electrolytic chamber on a bottom surface of the electrolytic chamber portion. The method according to any one of claims 1 to 3,
The electrolytic cell further includes a pair of packing mounting pipes formed on the bottom surface of the electrolytic chamber part to surround the electrode exposure hole and packings installed one by one in the packing mounting pipe.

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