KR20220144426A - Hydrogen gas-oxygen gas supply apparatus - Google Patents

Abstract

The present invention relates to a hydrogen gas-oxygen gas supply apparatus and, more specifically, to a hydrogen gas-oxygen gas supply apparatus for supplying optimal amounts of hydrogen gas and oxygen gas so that a user may breathe. The hydrogen gas-oxygen gas supply apparatus according to an embodiment of the present invention comprises: a water tank (100) for storing water; an electrolytic cell (200) for electrolyzing water supplied from the water tank (100); a control unit (300) for controlling an amount of the water in the water tank (100) supplied to the electrolytic cell (200) by calculating a user's individual respiratory volume; a hydrogen gas storage unit (400) for storing hydrogen gas generated by electrolysis in the electrolytic cell (200); an oxygen gas storage unit (500) for storing oxygen gas generated by electrolysis in the electrolytic cell (200); and a respirator (600) for receiving hydrogen gas and oxygen gas from the hydrogen gas storage unit (400) and the oxygen gas storage unit (500), respectively, and providing the hydrogen gas and the oxygen gas to a user's respiratory system, wherein the control unit (300) comprises a big data module (310) for calculating the user's individual respiratory volume.

Description

Hydrogen gas-oxygen gas supply apparatus

The present invention relates to a hydrogen gas-oxygen gas supply device, and more particularly, to a hydrogen gas-oxygen gas supply device for allowing a user to breathe by supplying optimal amounts of hydrogen gas and oxygen gas. The present invention is a device for inhaling hydrogen gas and oxygen gas into the human body through respiration. From generation to injection of hydrogen gas and oxygen gas, natural materials and non-polluting materials are used for all potential pipelines and contact surfaces. As a beneficial non-polluting inhalation device that excludes materials, 100% of harmful materials are excluded (excluded) from the generation of hydrogen gas to the introduction of hydrogen gas into the human body.

The respiratory system consists of the lungs, the airway, and the central nervous system elements involved in the control of the muscle of respiration, and the chest wall. The chest wall consists of the respiratory muscles (diaphragm, intercostal muscles, and abdominal muscles) and the rib cage. The exchange of oxygen gas and carbon dioxide between capillaries and tissue cells is called 'internal respiration'. Unnecessary carbon dioxide produced as a result of respiration is discharged through the respiratory system. However, depending on the animal's body structure and living place, it seems that the most efficient respiratory organs have been developed in each animal over a long evolutionary history. In addition, in the cell, not only the decomposition of nutrients by respiration, but also various chemical reactions are performed. As a result, a lot of waste products are generated, and these must be discharged outside the body. In simple animals such as amoeba, waste products diffuse directly from the cell membrane into extraterrestrial water and are discharged, and absorb oxygen gas and release carbon dioxide to the body surface.

Water is required for gas exchange during respiration. Respiratory organs such as gills are in direct contact with water, and the respiratory organs of animals that breathe air are also covered with a thin layer of water where gas exchange occurs directly. For example, because the skin of a frog is moist, skin respiration occurs. On the other hand, although the skin of snakes and lizards is dry, gas exchange through the skin is almost impossible, but the inner surface of the lungs is a mucous membrane and is always covered with a membrane of water, so there is no hindrance to breathing. This fact tells us that extraterrestrial oxygen gas is absorbed into the body once it is dissolved in water. Except for low-grade animals that consume not much oxygen gas, most of the animal's respiratory organs have developed intricately to increase the surface area that oxygen gas comes into contact with, and develop in combination with the blood or circulatory system to transport oxygen gas more efficiently. have been doing

However, recently, a beneficial phenomenon due to the respiration of hydrogen gas has been noted. Hydrogen gas molecules are detoxified by reacting with hydroxyl radical (OH), which is a 'bad' active oxygen gas with the strongest oxidizing power. There are no side effects because it does not react to 'good' reactive oxygen species.

H ₂ + 2OH (active oxygen gas) = 2H ₂ O

Hydrogen gas is also physiologically generated from intestinal bacteria, so there is no risk of explosion at the concentration used for treatment. Because the molecule is small and soluble in water and oil, it diffuses much faster than vitamins, etc., and the efficiency of reaching the cells is very good. Vitamins C and E, known as antioxidants, also remove 'good' free radicals, and then undergo oxidation on their own and become 'bad'.

Hydrogen gas (H ₂ ) is very safe because it removes only 'bad' active oxygen gas and is converted into water (H ₂ O).

Keio University's Department of Cardiovascular Medicine (Associate Professor Motoaki Sano et al.) reported that hydrogen gas inhalation therapy for acute diseases such as acute myocardial infarction and cardiopulmonary arrest showed excellent effects in animal experiments. Clinical application to humans has already started. Clinical trials for cerebral infarction, rheumatoid arthritis, chronic obstructive pulmonary disease (COPD), and the alleviation of side effects of anticancer drugs have been started at other facilities, and efficacy is reported.

All of the above-mentioned "diseases involving 'bad' reactive oxygen species" can be expected to be effective. It is thought to be effective in preventing the development of arteriosclerosis in people with diabetes or dyslipidemia, and in treating stiff shoulder, headache, back pain, muscle pain, arthralgia, bronchitis after a cold, cough asthma, etc. Efficacy has already been reported for rheumatoid arthritis. In addition, it was reported that administration of hydrogen gas to soccer players suppressed lactic acid production through exercise and improved performance. Among those who do not exercise on a regular basis, those who plan to exercise can also expect the effect of preventing muscle pain.

Active oxygen gas is not only caused by disease, but also by exercise, work, and stress in daily life, causing bodily harm. It can be expected to have an effect of increasing concentration for people who have slow recovery from fatigue due to a lot of stress, anti-aging measures, and students studying for exams.

Inhalation of hydrogen gas can mainly be expected to have an effect on the brain, bronchi, lungs, and muscles. Hydrogen gas instillation can be expected to have a certain effect on the whole body because it diffuses into the blood circulation. Inhalation therapy can also be implemented during the course.

On the other hand, on November 26, 2020 (UK time), it was reported that hydrogen gas prevents or alleviates organic or functional disorders of the body according to the stress response in Nature Scientific Reports, UK.

In addition, in China, there is a report that hydrogen gas inhalation is used for the treatment of severe pneumonia caused by coronavirus infection (COVID-19). Hereinafter, related prior literatures are introduced. Identifiers in the following prior art are irrelevant to the present invention.

Republic of Korea Utility Model Registration No. 20-0484079 'Hydrogen gas respirator' is equipped with a breathing mask and an electrolyzer that electrolyzes water to generate hydrogen gas and supplies it to the breathing mask. A hydrogen gas generator that operates alternately, a hydrogen gas transfer tube that moves the hydrogen gas of the hydrogen gas generator to a breathing mask, and a hydrogen gas outlet or a hydrogen gas transfer tube that is coupled to the hydrogen gas generator to remove moisture from the hydrogen gas A moisture eliminator is provided. No. 20-0484079 discloses a hydrogen gas respirator comprising: a respirator; a hydrogen gas generator comprising an electrolyzer for supplying hydrogen gas to the breathing mask after electrolysis of water, wherein the electrolyzer is composed of two or more groups and each group operates alternately; a hydrogen gas moving tube for moving the hydrogen gas of the hydrogen gas generator to the breathing mask; and a water eliminator coupled to the hydrogen gas discharge port or the hydrogen gas moving tube of the hydrogen gas generator to remove moisture from the hydrogen gas, wherein the electrolytic cell includes a first cover coupled to the negative electrode side and the positive electrode side and a second cover coupled to the , wherein the first and second covers form a labyrinth-shaped water passage on opposite surfaces, and a plurality of water movement delay members are provided in the water passage, and the water movement delay member disclosed a hydrogen gas respirator, characterized in that it is arranged in a zigzag with respect to the direction of water movement and has a curved surface to generate a vortex.

Korean Patent Laid-Open No. 10-2010-0100753 'A device for producing oxygen gas and/or hydrogen gas in an environment where there is no oxygen gas to breathe' relates to an apparatus for generating oxygen gas in an atmosphere substantially free of oxygen gas for breathing will be. No. 10-2010-0100753 consists of a housing; the housing is divided into a first chamber and a second chamber; the first chamber comprises a catalytic filter material comprising a plurality of repeating units; The repeating unit comprises a porous boron-doped carbon film comprising diruthenium/diruthenium molecules and at least one type of negatively charged ion, wherein the diruthenium/diruthenium molecules and the negative A first screen in which malleable ions are in direct contact with the porous boron-doped carbon film, wherein the porous boron-doped carbon film further includes a nano-carbon tubular mesh network and sideropores for collecting ruthenium ions; , a plurality of nanocarbon tubes attached to and/or embedded on the surface of a synthetic film to form a nanocarbon tubular mesh network, and at least one zeolite crystal in direct contact with the nanocarbon tubes; a composite film comprising a composite film comprising a plurality of pores having a diameter of from about 0.1 to about 3.0 nm, wherein the zeolite crystals attached to the nanocarbon tubes are at least one of the pores a second screen partially overlapping and a plurality of nanocarbon tubes attached to and/or embedded on the surface of the composite film to form a nanocarbon tubular mesh network, positioned in close contact with the surface of the composite film; a third screen comprising a synthetic film for generating hydrogen peroxide gas comprising diruthenium/diruthenium molecules and a zeolite; Disclosed is an apparatus for producing oxygen gas in an environment substantially free of oxygen gas, wherein the second chamber includes a catalyst for generating oxygen gas in contact with the oxygen gas generating liquid.

However, in the prior art, including Nos. 20-0484079 and No. 10-2010-0100753, it was not possible to find a technique for providing an appropriate amount for a user's personal respiration volume in hydrogen gas respiration.

Republic of Korea Registered Utility Model No. 20-0484079 'Hydrogen Gas Respirator' Announcement Date July 28, 2017 Republic of Korea Patent Publication No. 10-2010-0100753 'A device for producing oxygen gas and/or hydrogen gas in an environment where there is no oxygen gas to breathe' Publication date September 15, 2010

The technical problem to be achieved by the present invention is to provide a hydrogen gas-oxygen gas supply device capable of supplying and breathing optimal hydrogen gas and oxygen gas by calculating the user's personal respiration amount.

The technical problems to be achieved by the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned can be clearly understood by those of ordinary skill in the art to which the present invention belongs from the description below. There will be.

In order to achieve the above technical problem, an embodiment of the present invention provides a hydrogen gas-oxygen gas supply device, comprising: a water tank 100 for storing water; an electrolyzer 200 for electrolyzing water supplied from the water tank 100; a control unit 300 for controlling the amount of water in the water tank 100 supplied to the electrolytic cell 200 by calculating the user's individual respiration rate; a hydrogen gas storage unit 400 for storing hydrogen gas generated by electrolysis in the electrolyzer 200; an oxygen gas storage unit 500 for storing oxygen gas generated by electrolysis in the electrolyzer 200; and a respirator 600 that receives hydrogen gas and oxygen gas respectively from the hydrogen gas storage unit 400 and the oxygen gas storage unit 500 and provides them to the user's respirator, wherein the control unit 300 controls the user's individual respiration rate It provides a hydrogen gas-oxygen gas supply device, characterized in that it includes a big data module 310 for calculating .

According to an embodiment of the present invention, by calculating the user's personal respiration amount using big data, the optimum amount of hydrogen gas and oxygen gas is supplied so that the user can breathe.

In addition, by breathing hydrogen gas,

1. Migraine reduction effect

2. Relief effect of atopic dermatitis without steroid use

3. The effect of lowering blood sugar

4. Low back pain improvement effect

5. Effect of relieving chronic pain around the scapula

6. Stiff shoulder improvement effect

7. The effect of moisturizing the skin

8. Hair loss improvement effect

9. Muscle pain relief effect

10. Cold prevention effect

etc can be expected.

In addition, the present invention provides an advantageous non-polluting suction device excluding existing resins and synthetic materials by using natural and non-polluting materials for the entire pipe line and contact surface from generation to injection of hydrogen gas and oxygen gas. That is, 100% of harmful materials are excluded in the entire process from hydrogen gas generation to hydrogen gas entering the human body.

The effects of the present invention are not limited to the above effects, and it should be understood to include all effects that can be inferred from the configuration of the invention described in the detailed description or claims of the present invention.

1 is a configuration diagram of a hydrogen gas-oxygen gas supply device of the present invention.
2 is a block diagram of the control unit of the hydrogen gas-oxygen gas supply device of the present invention.
3 is an explanatory view for explaining the operation of the hydrogen gas-oxygen gas supply device of the present invention.
4 is a configuration diagram of the respirator of the hydrogen gas-oxygen gas supply device of the present invention.
5 is a perspective view of the diaphragm diaphragm applied to the respirator of the hydrogen gas-oxygen gas supply device of the present invention.

Hereinafter, the present invention will be described with reference to the accompanying drawings. However, the present invention may be embodied in several different forms, and thus is not limited to the embodiments described herein. And in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification.

Throughout the specification, when a part is "connected (connected, contacted, coupled)" with another part, it is not only "directly connected" but also "indirectly connected" with another member interposed therebetween. "Including cases where In addition, when a part "includes" a certain component, this means that other components may be further provided without excluding other components unless otherwise stated.

The terms used herein are used only to describe specific embodiments, and are not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise. In the present specification, terms such as “comprise” or “have” are intended to designate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, but one or more other features It is to be understood that this does not preclude the possibility of the presence or addition of numbers, steps, operations, components, parts, or combinations thereof.

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

1 is a configuration diagram of a hydrogen gas-oxygen gas supply device of the present invention, and FIG. 2 shows a configuration diagram of a control unit of the hydrogen gas-oxygen gas supply device of the present invention.

Hydrogen gas-oxygen gas supply device according to the present invention

Water supplied from the water tank 100 is electrolyzed in the electrolyzer 200 , and the generated hydrogen gas and oxygen gas are stored in the hydrogen gas storage unit 400 and the oxygen gas storage unit 500 , respectively.

At this time, the control unit 300 calculates the user's individual respiration amount and controls the amount of water in the water tank 100 supplied to the electrolytic cell 200 and the amount of hydrogen gas and oxygen gas moving to the respirator 600 . The control unit 300 includes a big data module 310 for calculating a user's individual respiration amount.

The big data module 310 includes a database 320 in which data including weight, age, gender, body fat percentage, height, and medical history of users is stored; It is preferable to include; a calculation module 330 for calculating the amount of water in the water tank 100 supplied to the electrolytic cell 200 according to the information described in the database.

That is, the big data module 310 receives the big data collected from the database 320 in order to calculate the user's individual respiration rate. The taller you are, the higher your body weight, the lower your body fat percentage, and the younger you are, the higher your metabolic rate and the more you need to breathe. Accordingly, the present invention provides a configuration for calculating the optimal respiration volume for each individual by collecting the respiration amount information and body information of a plurality of users and turning it into big data.

In the present invention, hydrogen gas and oxygen gas necessary for respiration are generated by electrolysis of water. Therefore, the amount of hydrogen gas and oxygen gas provided to the user is due to the amount of water to be electrolyzed. Accordingly, the big data module 310 determines the amount of water to be electrolyzed by calculating the amount of water in the water tank 100 supplied to the electrolytic cell 200 . The database 320 of the big data module 310 may be configured as a separate server if necessary.

The control unit 300 includes an electrolytic cell setting module 340 for determining the electrolytic capacity of the electrolytic cell according to the amount of water supplied to the water tank 100; a static pressure control module 350 for regulating the pressures of hydrogen gas and oxygen gas supplied to the respirator 600; a temperature control module 360 for controlling the temperature of hydrogen gas and oxygen gas supplied to the respirator 600; It is preferable to include

It is preferable that the concentration of hydrogen gas to the user is about 4% concentration, and also hydrogen gas droplet (about 1 ppm concentration). In order to control the predetermined concentration, pressure, and temperature, a static pressure control module 350 and a temperature control module 360 are applied.

The electrolyzer setting module 340 controls the electrodes of the anode and the cathode of the electrolyzer 200 in order to electrolyze the water supplied from the water tank 100 to the electrolyzer 200 .

The static pressure control module 350 for controlling the pressures of hydrogen gas and oxygen gas supplied to the respirator 600 is an oxygen gas pump for sending the electrolyzed oxygen gas from the electrolyzer 200 to the oxygen gas storage unit 500 . 510 and the hydrogen gas pump 410 for sending the electrolyzed hydrogen gas from the electrolyzer 200 to the hydrogen gas storage unit 400 is controlled. In addition, the pressure is adjusted by controlling the valves 430 and 530 that control the pipelines 420 and 520 from the oxygen gas storage unit 500 and the hydrogen gas storage unit 400 to the respirator 600 . It is preferable that the conduits 420 and 520 are configured as coils as shown so that their length can be adjusted according to the user.

The temperature control module 360 checks the temperature through a thermometer installed in the electrolyzer 200 , the hydrogen gas storage unit 400 and the oxygen gas storage unit 500 , and prevents accidents due to overheating. When the temperature is excessively increased, the cooling module is operated, and the cooling module may be applied with a conventional cooling means such as water cooling or air cooling.

In addition, the control unit 300 receives the measurement value of the user's blood oxygen saturation from the blood check module 370 and controls the pressure of hydrogen gas and oxygen gas supplied to the respirator 600 by the static pressure control module 350 . ) can be controlled. The blood check module 370 measures the user's blood oxygen saturation in real time by contacting the user's body, such as a finger, and the controller 300 controls the static pressure control module 350 based on the measured value.

4 is a configuration diagram of the respirator 600 of the hydrogen gas-oxygen gas supply device of the present invention, and FIG. 5 is a diaphragm diaphragm 700 applied to the respirator 600 of the hydrogen gas-oxygen gas supply device of the present invention. is a perspective view of

The respirator 600 is characterized in that it includes a one-way valve for discharging the supplied hydrogen gas and oxygen gas after the user breathes in the carbon dioxide that is exhaled. The one-way valve is preferably a valve to which a diaphragm for controlling the flow of air in one direction is applied, and the user breathes by receiving hydrogen gas and oxygen gas from the pipelines 420 and 520, respectively, and the diaphragm installed in the respirator 600 Carbon dioxide is released through the valve.

The respirator 600 includes a hemispherical cup frame 610 to be worn on the user's face; a gas supply unit 620 formed on the front side of the hemispherical cup frame 610; It is preferable to include a gas discharge unit 630 formed adjacent to the gas supply unit 620 . The gas supply unit 620 includes two conduits 420 and 520 through which two types of gases are introduced; a gas collecting member 640 in which the gas of the pipelines 420 and 520 is collected; It includes a gas inlet hole 621 through which the gas collecting member 640 is fastened and the collected gas is introduced into the hemispherical cup frame 610, and the gas is supplied to the gas supply unit 620 and the gas outlet unit 630. A diaphragm diaphragm 700 that can pass only in one direction is installed. The diaphragm diaphragm 700 is composed of a dome 710 and a flange 720 formed on a rim of the dome 710, and a plurality of fine slits 711 in the dome 710. It is preferred that this is formed.

The fine slit 711 of the diaphragm diaphragm 700 is formed by lancing processing. The fine slit 711 is easily expanded under pressure from the inside, but is opened and closed using the structural feature of a hemispherical dome that has a strong force to maintain its shape under a uniform pressure from the outside to control the flow of gas in one direction. .

In addition, the present invention further includes a monitor 700 for monitoring the control status of the control unit 300 to the user,

The monitor 700 is mainly used to display the injection status of oxygen gas and hydrogen gas, but has an interface that can manually adjust the respiration amount, oxygen gas supply amount, and hydrogen gas supply amount according to the user's needs. A hydrogen gas-oxygen gas supply device is provided. The monitor 700 is preferably a touch screen, and may include an interface for inputting personal information such as a user's weight, age, gender, body fat percentage, height, medical history, etc., if necessary. The hydrogen gas-oxygen gas supply device of the present invention is preferably operated by a medical professional, so that personal information is preferably entered through information such as a medical certificate, but, if necessary, to enable direct manipulation by the user. In addition, it is preferable that the monitor 700 has a built-in speaker so that it can output audio and video of protocols such as mp3 and mp4, so that not only the output of a warning signal but also the visually/hearing impaired can easily use it.

On the other hand, the present invention is a device for injecting hydrogen gas and oxygen gas into the human body through respiration. From generation of hydrogen gas and oxygen gas to injection, natural materials and non-polluting materials are used for all pipe lines and contact surfaces of existing resins. , to provide an advantageous non-polluting suction device excluding synthetic materials. In other words, 100% of harmful materials are excluded (excluded) from the generation of hydrogen gas to the introduction of hydrogen gas into the human body.

To this end, the hydrogen gas storage unit 400, the oxygen gas storage unit 500, and the pipelines 420 and 520 may be plated with silver or copper or lacquered, or non-corrosive stainless steel or copper tube. can be applied.

3 is an explanatory view for explaining the operation of the hydrogen gas-oxygen gas supply device of the present invention. According to one embodiment of the present invention,

Individual respiration volume setting step (s100) by the big data module 310 of the control unit 300;

Electrolyzer setting step (s200) by the electrolyzer setting module 340 of the control unit 300;

Adjusting the pressure by the static pressure control module 350 and the amount of hydrogen gas and oxygen gas provided (s300);

Temperature maintaining step (s400) by the temperature control module (360);

the user's breathing step (s500);

According to the individual respiration volume set in the big data module 310, the supply of hydrogen gas and oxygen gas is stopped by the control of the valves 430 and 530 by the static pressure control module 350 to perform breathing by the hydrogen gas-oxygen gas supply device. stopping (s600);

provides

In the control step (s300) of the pressure control by the static pressure control module 350 and the amount of hydrogen gas and oxygen gas provided, the amount and pressure of the supplied hydrogen gas and oxygen gas are adjusted in consideration of the user's lung capacity calculated in advance. do.

In the user's respiration step (s500), as described above, after breathing hydrogen gas and oxygen gas, carbon dioxide is discharged through a diaphragm application valve whose flow is controlled in one direction.

Although the present invention has been described in conjunction with the accompanying drawings, this is only one embodiment of various embodiments including the gist of the present invention, and is intended to be easily implemented by those of ordinary skill in the art. For the purpose, it is clear that the present invention is not limited to the embodiments described above. Accordingly, the protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent range by changes, substitutions, substitutions, etc. within the scope not departing from the gist of the present invention are the rights of the present invention. will be included in the scope. In addition, it is clarified that some components of the drawings are provided in an exaggerated or reduced form than in reality to more clearly describe the components. In addition, the claim signs are only for helping understanding, and do not mean to limit the shape and structure of the present invention to the accompanying drawings.

100. Aquarium
200. Electrolyzer
300. Control
310 Big Data Module
320. Database
330. Calculation module
340. Electrolyzer setting module
350. Static pressure control module
360. Temperature control module
370. Blood check module
400. Hydrogen gas storage unit
410. Hydrogen gas pump
420. Pipeline
430. Valve
500. Oxygen gas storage unit
510. Oxygen gas pump
520. Pipeline
530. valve
600. Respiratory
610. Hemispherical cup frame
620. Gas supply unit
621. Gas inlet hole
630. Gas outlet
640. Gas assembly member
700. Diaphragm diaphragm
710. Dome
711. Slit
720. Flange

Claims (5)

In the hydrogen gas-oxygen gas supply device,
a water tank 100 for storing water;
an electrolyzer 200 for electrolyzing water supplied from the water tank 100;
a control unit 300 for controlling the amount of water in the water tank 100 supplied to the electrolytic cell 200 by calculating the user's individual respiration rate;
a hydrogen gas storage unit 400 for storing hydrogen gas generated by electrolysis in the electrolyzer 200;
an oxygen gas storage unit 500 for storing oxygen gas generated by electrolysis in the electrolyzer 200;
and a respirator 600 that receives hydrogen gas and oxygen gas respectively from the hydrogen gas storage unit 400 and the oxygen gas storage unit 500 and provides them as a user's respirator,
The control unit 300 is hydrogen gas-oxygen gas supply device, characterized in that it comprises a big data module 310 for calculating the individual respiration amount of the user.
According to claim 1,
The big data module 310,
a database 320 for storing data including weight, age, gender, body fat percentage, height, and medical history of users;
a calculation module 330 for calculating the amount of water in the water tank 100 supplied to the electrolytic cell 200 according to the information described in the database;
Hydrogen gas comprising a - oxygen gas supply device.
3. The method of claim 2,
The control unit 300 includes an electrolytic cell setting module 340 for determining the electrolytic capacity of the electrolytic cell according to the amount of water supplied to the water tank 100;
a static pressure control module 350 for regulating the pressures of hydrogen gas and oxygen gas supplied to the respirator 600;
a temperature control module 360 for controlling the temperature of hydrogen gas and oxygen gas supplied to the respirator 600;
Hydrogen gas comprising a - oxygen gas supply device.
According to claim 1,
The respirator 600 is a hydrogen gas-oxygen gas supply device, characterized in that it includes a one-way valve for discharging the supplied hydrogen gas and oxygen gas and then exhaled carbon dioxide after the user breathes.
5. The method according to any one of claims 1 to 4,
It includes a monitor 700 for monitoring the control status of the control unit 300 to the user,
The monitor 700 is hydrogen gas-oxygen gas supply device, characterized in that it has an interface that can manually adjust the respiration amount, oxygen gas supply amount, and hydrogen gas supply amount according to the user's needs.

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