JP2015217116A - Hydrogen gas sucking method and device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a hydrogen gas generation device capable of efficiently sucking hydrogen gas from a respiratory system and generating hydrogen gas in large quantities.SOLUTION: In a hydrogen gas sucking method, an electrolytic solution in a hydrogen gas generating container 3 is electrolyzed by an electrode 6 to generate hydrogen gas, and the generated hydrogen gas is sucked from a suction tube 23, using a suction mask 24 that covers the mouth and nose to take the hydrogen gas into the body from a respiratory system. In a sucking device 25, air required for respiration is introduced into the suction mask through an air inflow port so that sufficient oxygen is secured for a person sucking the hydrogen gas.

Description

  The present invention relates to a method and an apparatus for efficiently generating and efficiently sucking hydrogen gas.

  Since hydrogen gas has the action of suppressing or eliminating the generation of active oxygen, as a method of taking in this hydrogen gas into the body, a method of drinking hydrogen water in which the so-called hydrogen gas is dissolved, and a method of drinking hydrogen gas directly into the mouth or nose It is widely known that there is a method for taking in via the respiratory system.

  For example, Patent Document 1 proposes hydrogen water in which electrolyzed hydrogen gas is dissolved at a high concentration in drinking water as a method for taking it in as hydrogen water.

  As a method for taking in hydrogen gas as it is via the respiratory system, Patent Document 2 proposes a method for sucking hydrogen gas generated by electrolysis from the mouth or nose using an inhaler.

However, in the case of Patent Document 1, it is necessary to drink a large amount of hydrogen water in order to enhance its function, so there is a limit to the amount to be taken up.
In the case of Patent Document 2, since there is a limit to efficiently sucking hydrogen gas, it takes time to suck a certain amount, and a device for efficiently generating or sucking hydrogen gas is used. There is no introduction.

JP 2007-254435 A JP 2013-146373 A

  An object of the present invention is to provide a hydrogen gas inhalation method and apparatus capable of efficiently taking high concentration hydrogen gas from the respiratory system such as the mouth and nose into the body.

  In order to achieve the above object, the present invention proposed in claim 1 is an inhalation mask for covering the mouth and nose of the hydrogen gas suction method by electrolyzing the electrolyte to generate hydrogen gas. It is characterized by taking directly into the body from the respiratory system using.

  The present invention proposed in claim 2 is directed to a hydrogen gas suction device comprising: a. A hydrogen gas generation container for containing an electrolyte solution, dipping an electrode composed of + and-electrodes in the electrolyte solution and connecting the electrode to a DC power source to generate hydrogen gas; b. A water cup disposed on the hydrogen gas generation container and filled with drinking water; c. Drinking water in which hydrogen gas is sucked from the upper space of the hydrogen gas generating container so that the hydrogen gas generated in the hydrogen gas generating container is transferred into the water cup, and the sucked hydrogen gas is filled in the water cup. A hydrogen gas tube for delivery to the d. A suction mask that can be worn in close contact with the face so as to cover the mouth and nose of a hydrogen gas inhaler, and an air intake with a check valve formed to take in natural air from the outside in this suction mask, Hydrogen gas suction with a check valve connected with an exhaust port with a check valve provided for discharging exhaust gas from the inside of the suction mask to the outside of the suction mask, and an upper space in the water cup with a hydrogen gas suction tube It is characterized by comprising a mouth.

  Further, in the present invention proposed in claim 3, in the hydrogen gas suction device according to claim 2, a shutter having an adjustable opening area is attached to the air intake port in order to adjust the amount of air taken in. It is characterized by this.

  Further, the present invention proposed in claim 4 is the hydrogen gas suction device according to claim 2, wherein the check valve is opened in the hydrogen gas generation container when the upper space in the container falls below a certain pressure. An air introduction device for introducing outside air into the hydrogen gas generation container is provided.

According to the first aspect of the present invention, since the electrolytic solution is electrolyzed to generate hydrogen gas, a large amount of high concentration hydrogen gas can be generated and the generated hydrogen gas covers the mouth and nose. Therefore, hydrogen gas can be efficiently sucked without waste.
For this reason, the suction time can be greatly shortened.

  According to the invention described in claim 2, hydrogen gas can be generated by a compact device, and the generated hydrogen gas can be reliably sucked and taken into the body without waste from a mask covering the mouth and nose. it can.

  In addition, since the suction mask covers the mouth and nose, the intake / exhaust process associated with breathing is smoothly performed by a check valve, and the amount of outside air sucked into the suction mask is controlled to the minimum necessary to adjust the hydrogen gas concentration. Can be prevented from diluting.

Front view of a hydrogen gas generator according to the present invention A-A 'sectional view Explanatory drawing of air introduction device Inside view of suction mask Vertical side view of suction mask Explanatory drawing of the air supply / exhaust device in the suction mask Explanatory drawing of the state where hydrogen gas is sucked

  An embodiment of the hydrogen gas suction method and apparatus according to the present invention will be described in detail with reference to FIGS.

  1 and 2 are explanatory views showing the entire hydrogen gas generator, in which FIG. 1 is a partially cutaway front view, and FIG. 2 is a cross-sectional view taken along line A-A ′. In this hydrogen gas generator 1, a transparent hydrogen gas generation container 3 formed of acrylic resin or the like is formed on a base 2, and an electrolytic solution 4 such as potassium carbonate is contained in the hydrogen gas generation container 3. The electrolyte 6 is filled with an electrode 6 in which a positive electrode 6a and a negative electrode 6b are arranged in parallel, and the electrode 6 is connected to a plug 7 from the plug 7. By applying a voltage from the power supply adapter 8 and the power supply control board 9 that step down the input AC100V to 12V, the electrolytic solution 4 is electrolyzed into hydrogen gas and oxygen, and this hydrogen gas and oxygen (so-called “Brown gas”). ") Fills the upper space 5 in the hydrogen gas generation container 3.

  In FIG. 2, reference numeral 10 denotes an electrode guard.

  Reference numeral 11 denotes an air introduction device provided in the center of the top plate 3a of the hydrogen gas generation container 3. The structure of the air introduction device 11 is specifically disclosed in FIG. The gas is introduced into the device 11 from the opening 12 via the check valve 13, and sent into the space 5 in the hydrogen gas generation container 3 through the inlet 14 provided in the top plate 3 a, and the pressure in the space 5 is reduced. When the pressure exceeds a certain value, the check valve 13 is closed, and when the pressure is less than the value, the check valve 13 is opened to control the pressure in the hydrogen gas generation container 3 (space 5).

  In FIG. 3, reference numeral 15 denotes a water cup base that is detachably mounted on the top plate 3 a of the hydrogen gas generating container 3 using screws 17, and the air introduction device is placed on the bottom plate 15 a of the water cup base 15. 11 and an upward ring wall 16 are formed, and a bottom 18a of a water cup 18 is detachably assembled in the ring wall 16.

  The water cup 18 is a transparent glass or plastic product, and is filled with drinking water 19 inside.

  21 is a lid of the water cup 18, and 22 is a hydrogen gas tube connecting the upper space 5 of the hydrogen gas generating container 3 and the space 20 in the water cup 18. The hydrogen gas filled in the space 5 is the hydrogen gas. After being fed into the drinking water 19 from the outlet 22 b located in the water cup 18 from the tip 22 a of the tube 22, the drinking water 19 is bubbled to fill the space 20.

  The filled hydrogen gas is introduced into a suction device 25 provided in a suction mask 24 shown in FIGS. 4 to 5 from a hydrogen gas suction tube 23 having a tip 23a introduced into a space 20 in the water cup 18.

  The suction mask 25 is formed of silicon rubber and is in close contact with the face, preventing air from entering from the outside and also preventing leakage of hydrogen gas.

  Reference numeral 26 denotes an ear strap.

  Reference numeral 27 denotes a hydrogen gas introduction chamber provided in the suction device 25. The hydrogen gas suction tube 23 is connected to the bottom of the hydrogen gas introduction chamber 27, and the hydrogen sucked from the suction tube 23. The gas once enters the introduction chamber 27 and flows into the suction mask 24 through the check valve 29 of the hydrogen gas inlet 28.

  The above-described check valve 29 of the hydrogen gas inlet 28 opens when the inside of the suction mask 24 becomes negative pressure due to respiration, sucks the hydrogen gas in the water cup 18 from the hydrogen gas suction tube 23 and introduces it into the suction mask 23. When the pressure in the suction mask 24 becomes + pressure due to exhaust, the valve is closed.

  Further, when the pressure inside the suction mask 24 becomes positive pressure due to exhaust during breathing, the check valve 32 of the exhaust port 31 of the exhaust chamber 30 provided in the suction device 25 is opened, and the exhaust flows from the exhaust outlet 33 to the outside of the suction mask 24. To be discharged.

  Reference numeral 34 denotes an air inlet provided in the suction mask 24. The air inlet 34 is provided with a shutter 35 for adjusting the air inflow amount. The intake air amount due to individual differences is adjusted by the opening degree of the shutter 35. It can be carried out.

The above-described check valves 13, 29, 32 employ an elastic body for the check valve or attach a weak coil spring to the base to adjust the opening / closing timing.
Next, a method for sucking the hydrogen gas generated by the action of the hydrogen gas generator 1 described above will be described with reference to FIG.

  In use, as shown in FIG. 7, the plug 7 is inserted into an AC power outlet 7 a and the voltage 6 stepped down to 12 V by the power adapter 8 is applied to the electrode 6, whereby the electrolyte 4 in the hydrogen gas generating container 3 is electrically charged. By being decomposed, the space 5 is filled with hydrogen gas.

  The gas generated by electrolysis is hydrogen gas and oxygen generated at a ratio of 2: 1. Usually, the mixed gas in this state is referred to as brown gas as described above. Collectively used as hydrogen gas.

  The hydrogen gas generated in the hydrogen gas generator 3 is sent from the space 5 through the hydrogen gas tube 22 into the water in the water cup 18 with a differential pressure.

  The hydrogen gas sent into the water is bubbled to fill the space 20 in the water cup 18, and the check valve 29 is opened by the negative pressure in the suction mask 24. Then, the gas flows into the suction mask 24 from the hydrogen gas inlet 28, is sucked from the mouth and nose of the sucker, and is absorbed into the body from the respiratory system.

During this suction, the check valve 32 of the exhaust port 31 is closed in the suction mask 24.
In breathing, air necessary for breathing is introduced into the suction mask 24 together with hydrogen gas from the air inlet 34 into the suction mask 24, so that sufficient oxygen is secured for the aspirator.

  The water cup 15 is made of a transparent resin or glass, and the hydrogen gas generated in the lower hydrogen gas generation container 3 is fed into the transparent water cup 15 so that the hydrogen gas is generated in the flow of bubbles. It can be seen that the suction tube 23 is sucked into the suction mask 24.

  At that time, if fruit juice or collagen powder is put in the water in the water cup 15, the dissolved amount of about 1 ppm can be increased by about 5 to 15% in the case of only water. It can also be provided as water 19 and easy-to-drink hydrogen water.

  The temperature of the electrolyte 4 in the hydrogen gas generation container 3 rises due to heat generation during electrolysis, and the upper space 5, the hydrogen gas tube 22, the space 20, and the hydrogen gas suction tube 23 in the hydrogen gas generation container 3 are filled with water vapor. To do.

  When the electrolysis is stopped, the water vapor returns to the water and the space 5 is in a vacuum state, so that the water in the water cup 15 flows back into the hydrogen gas generation container 3 at atmospheric pressure.

  The water that has flowed back causes a disadvantageous phenomenon such as diluting the concentration of the electrolytic solution or raising the water level more than necessary.

  In order to prevent this, it can be prevented by removing the lid 21 of the water cup 18 immediately after use and returning to the atmospheric pressure. However, since it is often forgotten, the pressure in the hydrogen gas generating container 3 is automatically reduced to a negative pressure. It is necessary to return to the atmospheric pressure state from the state, and when the pressure drops, an automatic valve for adjusting the pressure is attached to the hydrogen gas generating container 3 or the hydrogen gas tube 22 to reduce the pressure of the hydrogen gas generating container 3 to the atmospheric pressure. It is also a good idea to take measures to keep them equal.

  Since human exhalation is usually longer than the exhaust time (intake time is short), hydrogen gas is constantly generated regardless of inhalation / exhaust, so the hydrogen gas generated during exhalation The whole amount cannot be inhaled and is wasted.

  Therefore, when the exhalation is inhaled in the inhalation mask 24, the valve is operated to temporarily stop the inhalation of the gas, and during that time, the hydrogen gas is accumulated in the space such as the hydrogen gas aspiration tube 23, and the check valve 32 is opened during the inspiration. If the hydrogen gas that has been stopped is sucked in at a stroke, the generated hydrogen gas can be effectively used in an amount equivalent to twice.

  In FIG. 1, reference numeral 36 denotes a water level observation window for checking the water level of the electrolytic solution 4 in the hydrogen gas generating container 3.

DESCRIPTION OF SYMBOLS 1 Hydrogen gas generator 2 Base 3 Hydrogen gas generation container 4 Electrolyte 5 Space 6 Electrode 7 Plug 8 Power supply adapter 9 Power supply control board 10 Electrode guard 11 Air inlet 12 Air suction port 13 Check valve 14 Inlet 15 Water cup stand 15a Bottom plate 16 Ring wall 17 Screw 18 Water cup 18a Bottom 19 Drinking water 20 Space 21 Lid 22 Hydrogen gas tube 22a Suction port 22b Outlet 23 Hydrogen gas suction tube 23a Suction port 24 Suction mask 25 Suction device 28 Hydrogen gas inlet 29 Check Valve 31 Exhaust port 32 Check valve 33 Exhaust outlet 34 Air inlet

Claims (4)

  A method for inhaling hydrogen gas, characterized in that the electrolytic solution is electrolyzed to generate hydrogen gas and the generated hydrogen gas is directly taken into the body from the respiratory system using an inhalation mask covering the mouth and nose. a. A hydrogen gas generating container for putting an electrolytic solution and immersing an electrode composed of + and-electrodes in the electrolytic solution and connecting the electrode to a DC power source to generate hydrogen gas;
b. A water cup disposed on the hydrogen gas generation container and filled with drinking water inside;
c. Drinking water in which hydrogen gas is sucked from the upper space of the hydrogen gas generating container so that the hydrogen gas generated in the hydrogen gas generating container is transferred into the water cup, and the sucked hydrogen gas is filled in the water cup. A hydrogen gas tube for delivery to
d. A suction mask that can be worn in close contact with the face so as to cover the mouth and nose of a hydrogen gas inhaler, and an air intake with a check valve formed to take in natural air from the outside in this suction mask, Hydrogen gas suction with a check valve connected with an exhaust port with a check valve provided for discharging exhaust gas from the inside of the suction mask to the outside of the suction mask, and an upper space in the water cup with a hydrogen gas suction tube Mouth,
e. A hydrogen gas suction device comprising:   3. The hydrogen gas suction device according to claim 2, wherein a shutter capable of adjusting an opening area is attached to the air intake port in order to adjust an amount of air to be taken in.   The hydrogen gas generation container is provided with an air introduction device for opening a check valve and introducing outside air into the hydrogen gas generation container when the upper space in the container drops below a certain pressure. The hydrogen gas suction device according to claim 2.

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