JP2016182153A - Hydrogen gas inhalation method, hydrogen gas permeation method, hydrogen gas inhalator and hydrogen gas permeation device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a hydrogen gas inhalation method which can inhale or make permeate a high-concentration hydrogen gas which is generated by hydrogen water production equipment for producing high-concentration hydrogen water, and is suitable for portability, a hydrogen gas permeation method, a hydrogen gas inhalator, and a hydrogen gas permeation device.SOLUTION: When degassing a hydrogen gas which is generated by and stored in hydrogen water production equipment in order to raise a hydrogen gas concentration of hydrogen water in the hydrogen water production equipment, a hydrogen gas inhalation method inhales the degassed hydrogen gas. When degassing the hydrogen gas which is generated by and stored in the hydrogen water production equipment in order to raise the hydrogen gas concentration of the hydrogen water in the hydrogen water production equipment, a hydrogen gas permeation method makes the degassed hydrogen gas permeate.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a hydrogen gas inhalation method, a hydrogen gas infiltration method, a hydrogen gas inhalation device, and a hydrogen gas infiltration device, and in particular, can efficiently inhale or infiltrate high-concentration hydrogen gas and be portable. It relates to something that was devised.

For example, Patent Literature 1, Patent Literature 2, and the like disclose the configuration of a hydrogen gas suction method and a hydrogen gas suction device.
First, the “hydrogen gas suction method and apparatus” according to the invention described in Patent Document 1 is generally configured as follows. First, there is a hydrogen generation container, and the hydrogen generation container is filled with water and charged with a hydrogen generating agent. The hydrogen gas generated in the hydrogen generation container is released to the gas cleaning device through the tube. The gas cleaning device is filled with water, and the hydrogen gas released into the water floats on the liquid surface. The hydrogen gas floating on the liquid surface is inhaled through the tube and a nostril cannula connected to the tube.

  In addition, the “hydrogen gas suction device” according to the invention described in Patent Document 2 is generally configured as follows. First, there is a container body, and the container body is filled with water and charged with a hydrogen generating material. The hydrogen gas generated in the container main body is released into water in another container main body through the connection tube. The hydrogen gas released into the water in the other container body floats on the liquid surface. The floated hydrogen gas is inhaled through an intermediate tube and a nostril cannula connected to the intermediate tube.

JP 2014-61275 A Utility Model Registration No. 3184470

The conventional configuration has the following problems.
First, there was a problem that high concentration hydrogen gas could not be inhaled. For example, in the case of the invention described in Patent Document 1, since the inside of the gas cleaning device provided separately from the hydrogen generation container is opened to the atmosphere via the tip of the nostril cannula, the hydrogen in the gas cleaning device This is because the gas concentration cannot be increased. In other words, air is present in the gas layer of the gas cleaning device because it is open to the atmosphere, and the hydrogen gas generated in the hydrogen generation container is mixed with this air. Can not be raised.
This is the same in the case of the invention described in Patent Document 2, and the second container body is opened to the atmosphere via the nostril cannula, so the hydrogen gas concentration in the second container body is reduced. It cannot be increased, and eventually high concentration hydrogen gas cannot be sucked.
Another problem is that it is unsuitable for carrying. For example, in the case of the invention described in Patent Document 1, a gas cleaning device is required in addition to the hydrogen generation container, and it is difficult to inhale hydrogen gas while carrying them. Similarly, in the case of the invention described in Patent Document 2, two container bodies are required, and it is difficult to suck hydrogen gas by carrying these two container bodies.

  The present invention has been made based on such points, and the object of the present invention is to inhale or infiltrate high-concentration hydrogen gas generated by a hydrogen water production apparatus for producing high-concentration hydrogen water. Another object of the present invention is to provide a hydrogen gas suction method, a hydrogen gas permeation method, a hydrogen gas suction device, and a hydrogen gas permeation device that are suitable for carrying.

In order to achieve the above object, a hydrogen gas suction method according to claim 1 of the present invention is directed to a method of generating and storing hydrogen gas generated and stored in a hydrogen water production apparatus in order to increase the hydrogen gas concentration in the hydrogen water in the hydrogen water production apparatus. When degassing, the degassed hydrogen gas is sucked.
Further, the hydrogen gas infiltration method according to claim 2 is characterized in that when degassing the hydrogen gas generated and stored in the hydrogen water production apparatus in order to increase the hydrogen gas concentration in the hydrogen water in the hydrogen water production apparatus, The hydrogen gas to be extracted is permeated.
According to a third aspect of the present invention, there is provided a hydrogen gas suction device comprising a hydrogen water production device and a hydrogen gas suction device connected to the hydrogen water production device.
According to a fourth aspect of the present invention, there is provided a hydrogen gas permeation apparatus comprising a hydrogen water production instrument and a hydrogen gas permeation instrument connected to the hydrogen water production instrument.
A hydrogen gas suction device according to claim 5 is the hydrogen gas suction device according to claim 3, wherein the hydrogen water producing instrument is provided with a gas vent, and the hydrogen gas suction instrument is disposed in the gas vent. It is characterized by being connected.
A hydrogen gas permeation apparatus according to claim 6 is the hydrogen gas permeation apparatus according to claim 4, wherein the hydrogen water production instrument is provided with a degassing part, and the hydrogen gas permeation instrument is provided in the degassing part. It is characterized by being connected.
A hydrogen gas inhaler according to claim 7 is the hydrogen gas inhaler according to claim 5, wherein the hydrogen water production apparatus includes a functional water container having a produced water outlet. Is closed by a cap so as to be openable and closable, and the degassing portion is provided in the cap.
The hydrogen gas permeation apparatus according to claim 8 is the hydrogen gas permeation apparatus according to claim 6, wherein the hydrogen water production apparatus includes a functional water container having a produced water spout. Is closed by a cap so as to be openable and closable, and the degassing portion is provided in the cap.
A hydrogen gas inhaler according to claim 9 is the hydrogen gas inhaler according to claim 3, 5 or 7, wherein the hydrogen gas inhaler uses a nostril cannula. Is.
The hydrogen gas suction device according to claim 10 is the hydrogen gas suction device according to claim 3, 5 or 7, wherein the hydrogen gas suction device uses a suction mask. Is.
The hydrogen gas suction device according to claim 11 is the hydrogen gas suction device according to claim 10, characterized in that the suction mask is substantially directly attached to the degassing portion.
The hydrogen gas permeation apparatus according to claim 12 is the hydrogen gas permeation apparatus according to claim 4 or claim 6 or claim 8, wherein the hydrogen gas permeation instrument uses a percutaneous permeation chamber. It is what.
The hydrogen gas inhaler according to claim 13 is the hydrogen gas inhaler according to claim 3 or claim 5 or claim 7 or claim 9 or claim 10 or claim 11. A hydrogen gas generating agent mainly composed of aluminum and calcium oxide is used.
The hydrogen gas permeation apparatus according to claim 14 is the hydrogen gas permeation apparatus according to claim 4 or claim 6 or claim 8 or claim 12, wherein the hydrogen water producing instrument is mainly composed of aluminum and calcium oxide. A hydrogen gas generating agent is used.

As described above, according to the hydrogen gas suction method according to claim 1 of the present invention, the hydrogen gas generated and stored in the hydrogen water producing device is increased in order to increase the hydrogen gas concentration in the hydrogen water in the hydrogen water producing device. When degassing, the hydrogen gas to be degassed is sucked, so that the high-concentration hydrogen gas that was originally exhausted can be used effectively.
Further, according to the hydrogen gas infiltration method according to claim 2, when degassing the hydrogen gas generated and stored in the hydrogen water production tool in order to increase the hydrogen gas concentration in the hydrogen water in the hydrogen water production tool, Since the hydrogen gas to be degassed is permeated, the high-concentration hydrogen gas that has been exhausted as it is can be used effectively.
Further, according to the hydrogen gas suction device according to claim 3, since it comprises the raw water production instrument and the hydrogen gas suction instrument connected to the hydrogen water production instrument, the high concentration that was originally exhausted as it was Since the hydrogen gas suction device is attached to the hydrogen water production device, the configuration is simple and the portability can be improved.
Moreover, according to the hydrogen gas permeation device according to claim 4, since the hydrogen water production apparatus and the hydrogen gas permeation apparatus connected to the hydrogen water production apparatus were provided, the high concentration that was originally exhausted as it was Since the hydrogen gas permeation device is attached to the hydrogen water production device, the configuration is simple and the portability can be improved.
According to a hydrogen gas suction device according to claim 5, in the hydrogen gas suction device according to claim 3, the hydrogen water producing device is provided with a gas vent portion, and the hydrogen gas suction device has the gas vent portion. Therefore, it is not necessary to separately provide a connecting portion of the hydrogen gas suction device, and the configuration can be simplified.
According to a hydrogen gas permeation device according to claim 6, in the hydrogen gas permeation device according to claim 4, the hydrogen water production instrument is provided with a gas vent part, and the hydrogen gas permeation instrument has the gas vent part. Therefore, it is not necessary to separately provide a connecting portion of the hydrogen gas permeation instrument, and the configuration can be simplified.
According to a hydrogen gas inhaler according to claim 7, in the hydrogen gas inhaler according to claim 5, the hydrogen water production apparatus includes a functional water container having a drinking port for the produced hydrogen water, Since the mouth is closed by a cap so as to be freely opened and closed, and the gas venting portion is provided in the cap, the configuration can be simplified also by this.
According to a hydrogen gas permeation device according to claim 8, in the hydrogen gas permeation device according to claim 6, the hydrogen water production apparatus includes a functional water container having a drinking port for the produced hydrogen water, Since the mouth is closed by a cap so as to be freely opened and closed, and the gas venting portion is provided in the cap, the configuration can be simplified also by this.
Further, according to the hydrogen gas inhaler according to claim 9, in the hydrogen gas inhaler according to claim 3, 5 or 7, the hydrogen gas inhaler uses a nostril cannula. Hydrogen gas can be sucked efficiently with a simple configuration.
According to a hydrogen gas suction device according to claim 10, in the hydrogen gas suction device according to claim 3, 5 or 7, the hydrogen gas suction device uses a suction mask. In addition, hydrogen gas can be efficiently sucked with a relatively simple configuration.
Further, according to the hydrogen gas suction device according to claim 11, in the hydrogen gas suction device according to claim 10, since the suction mask is substantially directly attached to the gas vent portion, the portability is further improved. it can.
Moreover, according to the hydrogen gas permeation device according to claim 12, in the hydrogen gas permeation device according to claim 4, 6 or 8, the hydrogen gas permeation instrument uses a percutaneous permeation chamber. Hydrogen gas can be permeated efficiently.
According to a hydrogen gas inhaler according to claim 13, in the hydrogen gas inhaler according to claim 3, 5 or 7, 7 or 9, 10 or 11, the hydrogen water producing instrument is Since a hydrogen gas generator mainly composed of aluminum and calcium oxide is used, hydrogen gas can be generated efficiently.
According to a hydrogen gas permeation device according to claim 14, in the hydrogen gas permeation device according to claim 4 or claim 6, or claim 8 or claim 12, the hydrogen water production instrument comprises aluminum and calcium oxide as main ingredients. Therefore, hydrogen gas can be generated efficiently.

It is a figure which shows the 1st Embodiment of this invention, and is a figure which shows a mode that hydrogen gas is inhaled using a hydrogen gas inhalation device. It is a figure which shows the 1st Embodiment of this invention, and is sectional drawing which expands and shows the II section of FIG. 3A and 3B are diagrams showing a first embodiment of the present invention, in which FIG. 3A is a longitudinal sectional view showing a configuration of a hydrogen gas generation unit, and FIG. 3B is a sectional view taken along line bb in FIG. is there. It is a figure which shows the 2nd Embodiment of this invention, and is a figure which shows a mode that hydrogen gas is inhaled using a hydrogen gas inhalation device. It is a figure which shows the 3rd Embodiment of this invention, and is a figure which shows a mode that hydrogen gas is inhaled using a hydrogen gas inhalation device. It is a figure which shows the 4th Embodiment of this invention, and is a figure which shows a mode that hydrogen gas is inhaled using a hydrogen gas inhalation device. FIG. 7A is a view showing a fifth embodiment of the present invention, FIG. 7A is a view showing a state in which hydrogen gas is infiltrated into the skin of the face using a hydrogen gas penetration device, and FIG. It is sectional drawing of a percutaneous penetration jig. FIG. 8A is a view showing a sixth embodiment of the present invention, FIG. 8A is a view showing a state in which hydrogen gas is permeated into the skin of the face using a hydrogen gas penetration device, and FIG. It is sectional drawing of a percutaneous penetration jig. It is a figure which shows the 7th Embodiment of this invention, and is sectional drawing which expands and shows the structure of the upper part of a hydrogen water production instrument.

Hereinafter, a first embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a diagram showing a state in which a user 2 is inhaling hydrogen gas degassed from the hydrogen water producing instrument 1 through a hydrogen gas inhaler 101, and FIG. 2 is an enlarged view of a portion II in FIG. FIG. Details will be described below.
First, there is a functional water container 5 in which a hydrogen gas generation unit 3 is charged. As the functional water container 5, for example, use of a so-called “carbonated plastic bottle” made of polyethylene terephthalate (PET) and having 530 ml can be considered.
Incidentally, a “carbonated plastic bottle” is also used in the first embodiment.
The functional water container 5 is filled with, for example, about 510 ml of functional water 7. The internal volume of the functional water container 5 is 530 ml, and the volume (approximately 20 ml) of the hydrogen gas generation unit 3 is subtracted therefrom to calculate 510 ml which is the amount of the functional water. In FIG. 1 and FIG. 2, the functional water container 5 is expanded by the generation of hydrogen gas, whereby the liquid level of the functional water 7 is lowered. The functional water 7 in the first embodiment is used as drinking water.
In addition to drinking water, various uses such as cosmetics and animal and plant cultivation are conceivable.

  The upper end opening of the functional water container 5 is a drinking mouth (or spout) 9. The drinking mouth 9 is configured to be opened and closed by a cap 11. That is, a male screw portion 13 is formed on the outer periphery of the drinking mouth 9, while a female screw portion 15 is formed on the inner periphery of the cap 11. The cap 11 is attached to and detached from the drinking mouth 9 by a screwed structure of the male screw portion 13 and the female screw portion 15. Further, a plurality of operation projections 17 are provided radially on the outer periphery of the cap 11, thereby facilitating the rotation operation of the cap 11.

The cap 11 is provided with a gas vent valve 19. That is, a through hole 21 is formed at the center of the cap 11, and a valve seat sleeve 23 is inserted into the through hole 21 from the lower side in FIGS. 1 and 2. A male thread portion 25 is formed on the outer periphery of the upper end portion of the valve seat sleeve 23 in FIGS. A nut 27 is screwed into the male screw portion 25, whereby the cap 11 and the valve seat sleeve 23 are integrated.
A rubber packing 24 is interposed between the flange 23 a of the valve seat sleeve 23 and the cap 11.

A hollow shaft 29 for gas venting is screwed into the valve seat sleeve 23 from above in the figure. That is, as shown in FIG. 2, a male screw portion 29d is provided at the longitudinal center portion of the degassing hollow shaft 29, while a female screw portion 23c is provided at the longitudinal center portion of the valve seat sleeve 23. It has been. The degassing hollow shaft 29 is screwed into the valve seat sleeve 23 through the male screw portion 29d and the female screw portion 23b.
A gap is formed above and below in FIG. 2 of the threaded portion comprising the male screw portion 29d and the female screw portion 23b.

The degassing hollow shaft 29 has a hollow portion 29a. A seat portion 31 is provided on the inner bottom portion of the valve seat sleeve 23, while the distal end portion of the degassing hollow shaft 29 is a valve portion 33 having a diameter reduced in a tapered shape. Further, a vent hole 34 for venting gas is formed in the sheet portion 31. A rotation operating portion 29b is provided at the upper end of the degassing hollow shaft 29. The degassing hollow shaft 29 is formed with a degassing through hole 29c communicating with the hollow portion 29a.
A valve seat packing 36 is installed between the seat portion 31 and the valve portion 33, and an O-ring 40 is installed between the valve seat sleeve 23 and the gas vent hollow shaft 29. Yes.

  And, normally, the valve portion 33 is seated on the seat portion 31, and the vent hole 34 for gas venting is closed. On the other hand, by rotating the rotation operation portion 29b to loosen the threaded hollow shaft 29 to the valve seat sleeve 23 and pulling it upward, the valve portion 33 is removed from the seat portion 31. Separate. As a result, the gas vent hole 34 is opened, and gas is vented through the gas vent hole 34, the gas vent hole 29c, and the hollow portion 29a. This type of venting is performed for the following purposes.

  That is, hydrogen gas is generated in the hydrogen gas generation unit 3, and the hydrogen gas is released into the functional water 7 as fine bubbles and is efficiently dissolved. At that time, since the drinking mouth 9 is closed by the cap 11, the atmospheric pressure in the functional water container 5 gradually increases. As a result, release / dissolution of the hydrogen gas generated in the hydrogen gas generation unit 3 into the functional water 7 is suppressed, and as a result, the hydrogen gas is stored in the hydrogen gas generation unit 3. Therefore, immediately before drinking, the gas vent valve 19 is gradually opened to perform gas venting, whereby the hydrogen gas stored in the hydrogen gas generating unit 3 is gradually released into the functional water 7 as fine bubbles. To effectively dissolve it.

  Next, the configuration of the hydrogen gas generation unit 3 will be described. As shown in an enlarged view in FIG. 3A, first, there is an outer container 51, and an upper end opening 51 a of the outer container 51 is closed by a cap 53. The outer container 51 is composed of a hollow portion 55 and a solid portion 57 provided below the hollow portion 55. A portion of the hollow portion 55 on the solid portion 57 side is a tapered portion 59, and the tapered portion 59 is gradually reduced in diameter from the hollow portion 55 side toward the solid portion 57 side. A fine bubble generator 61 is connected to the lower end of the solid portion 57. The reason why the tapered portion 59 is provided is to smoothly raise the hydrogen gas bubbles released from the fine bubble generator 61 without colliding with the outer container 51. That is, when hydrogen gas bubbles released by the fine bubble generator 61 collide with the outer container 51, they may adhere to the outer container 51 and not float up. When new bubbles emerge in this state, they may collide and fuse with the attached bubbles and change into larger bubbles. Such large bubbles are exhausted onto the functional water 7 without breaking and dissolving in the functional water 7 even if they rise thereafter. Therefore, by providing the taper portion 59, such an enlarged phenomenon of bubbles is prevented.

  Further, a plurality of projections 53a (three in this embodiment) are provided on the upper end of the cap 53. These protrusions 53 a form a gap between the lower end of the valve seat sleeve 23 and the cap 53.

An inner container 63 is accommodated in the hollow portion 55. The opening 63a at the upper end of the inner container 63 is open. Further, a hydrogen gas ventilation path 65 is provided upright from the solid portion 57 side of the outer container 51, and the inner container 63 is installed on the hydrogen gas ventilation path 65. The upper end opening 65a of the hydrogen gas ventilation path 65 is opened in an inclined state. A hydrogen gas generating agent kit 67 is accommodated in the inner container 63. The configuration of the hydrogen gas generating agent kit 67 will be described in detail later.
Examples of the material of the outer container 51 and the inner container 63 include polypropylene (PP), polymethylpentene (TPX), polycarbonate (PC), polyamide (PA66), and polytetrafluoroethylene (PTFE). Conceivable.

  The solid portion 57 is provided with a hydrogen gas vent passage 69 that communicates with the hydrogen gas vent passage 65, and a spiral hydrogen gas vent passage 71 that communicates with the hydrogen gas vent passage 69. Yes. That is, a spiral hydrogen gas vent groove is formed on the outer peripheral surface of the solid portion 57, and the spiral hydrogen gas vent path 71 is formed by covering the covering tube 72 therewith. Further, another hydrogen gas ventilation path 73 is connected to the lower end of the spiral hydrogen gas ventilation path 71 in FIG. Further, the hydrogen gas vent path 75 is also formed in the fine bubble generator 61 described above, and the hydrogen gas vent path 75 communicates with the hydrogen gas vent path 73.

  The hydrogen gas generated in the inner container 63 flows down through the upper end opening 63a of the inner container 63. The hydrogen gas flowing down functions through the hydrogen gas vent 65, the hydrogen gas vent 69, the spiral hydrogen gas vent 71, the hydrogen gas vent 73, the hydrogen gas vent 75, and the fine bubble generator 61. It is discharged into the functional water 7 of the water container 5.

  A plurality of protrusions 77 are projected and formed on the outer peripheral surface of the inner container 61 already described. By providing such a plurality of protrusions 77, a heat insulating space 79 is formed between the inner container 63 and the outer container 51, and a desired heat insulating function is exhibited. As shown in the figure, the heat insulating space 79 is configured to be small at the upper end of the inner container 63 (a gap between the outer container 51 and the inner container 63 is, for example, about 1 mm) and gradually increase downward. ing.

  The reason why such a heat insulating space 79 is provided is to allow the temperature of the reaction site to quickly reach the reaction start temperature for generating hydrogen gas (for example, 40 ° C. to 45 ° C.). That is, the temperature of the functional water 7 depends on seasonal factors (winter season), conditions of the water supply equipment, and the like, and is about 4 ° C. to 35 ° C., for example. There is a concern that the functional water 7 in such a temperature range impairs the temperature rise at the reaction site. Therefore, by providing the heat insulating space 79, the temperature of the reaction site can be quickly reached to the reaction start temperature (for example, 40 ° C. to 45 ° C.) without being affected by the temperature of the functional water 7. It is. In addition, it also has the meaning of optimizing the transition between sensible heat and latent heat of the functional water 7 and the reaction water 80.

  The space above the inner vessel 63 is a hydrogen gas storage chamber 64 in which the generated hydrogen gas is compressed and stored. This hydrogen gas storage chamber 64 delays the pressure increase due to the pressurized pressure storage interference when the hydrogen gas is generated and pressurized, and performs the delay interference of the air pressure depressurization that delays the pressure release time when the pressure is reduced. It is provided for the purpose of leveling. The hydrogen gas compressed and stored in the hydrogen gas storage chamber 64 by degassing immediately before use, which has already been described, is reduced by, for example, 120 times in the process of reducing the pressure from 0.7 Mpa to normal pressure. While being expanded to the extent, it will be discharged through the fine bubble generator 61 already described.

  The hydrogen gas storage chamber 64 also has a function of condensing the reaction water 80 evaporated and evaporated by reaction heat and returning it to the inner container 63, for example. At that time, as described above, since the heat insulating space 79 is small at the upper end of the inner vessel 63, the condensed reaction water 80 does not flow down to the outside of the inner vessel 63.

When the hydrogen gas generating agent kit 67 is set, first, the inner container 61 is taken out, and the hydrogen gas generating agent kit 67 is put therein and a predetermined amount of reaction water 80 is put therein. Next, the inner container 61 is placed in the outer container 51, and the outer container 51 is sealed with the cap 53.
This completes the setting of the hydrogen gas generation unit 3. Thereafter, the hydrogen gas generation unit 3 may be put into the functional water 7 in the functional water container 5.

  The fine bubble generator 61 is made of a porous material having hydrophilicity, for example, a fired porous material made of ceramics, metal, glass, or the like, or a resin porous material. The diameter of the hole is, for example, about several nm to 5 μm.

  Next, the configuration of the hydrogen gas generator kit 67 will be described. First, there is a non-woven bag body 81, and this non-woven bag body 81 has hydrophilicity, water permeability and air permeability. A hydrogen gas generating agent 83 is accommodated in the nonwoven fabric bag 81. Examples of the hydrogen gas generating agent 83 include a hydrogen generating reaction accelerator (main agent) comprising a metal (main agent A) such as metal aluminum, metal magnesium, metal zinc, metal nickel, and metal cobalt, and an acid agent, an alkali agent, and the like. B). As said acid agent, solid acid, such as what produces a solid precipitate after reaction and an ion exchange resin, can be considered, for example. Moreover, as said alkaline agent, use of all well-known things, such as calcium hydroxide (slaked lime), calcium oxide (quick lime), calcined calcium, magnesium oxide, magnesium hydroxide, an anion exchange resin etc., can be considered, for example.

Incidentally, in the case of the present embodiment, the main agent A of the hydrogen gas generating agent 83 is aluminum (Al) powder, which is 100 to 300 mesh grade and has a particle size of about 100 to 300 μm. The main agent B is a calcium oxide (CaO) powder having a particle size of about 100 to 300 μm in a 100 to 300 mesh grade. The mass of the main agent A and the main agent B is about 0.7 g to 1.2 g, for example. By using such an amount of the hydrogen gas generating agent 83, 100 to 400 ml of hydrogen gas can be generated.
In addition, what is used as the hydrogen gas generating agent 83 is arbitrary, and this is not particularly specified.
In addition to the main agent A and the main agent B, it is conceivable to use some other auxiliary material for the purpose of controlling / suppressing reaction efficiency and reaction time.

  Further, the amount of the reaction water 80 is preferably about 1.0 to 3.0 times, more preferably about 1.5 to 2.0 times that of the hydrogen gas generating agent 83.

  Next, the configuration of the spiral hydrogen gas ventilation path 71 already described will be described in detail. The spiral hydrogen gas ventilation path 71 is literally bent and formed in a spiral shape, and such a bent configuration is the release of hydrogen gas generated by the hydrogen gas generation reaction in the reaction chamber to the functional water 7 side. This is to allow the reaction water / reactant produced by the reaction to flow out to the functional water 7 side and to flow the functional water 7 into the reaction chamber side.

  In addition, the length of the spiral hydrogen gas passage 71, when the functional water container 5 is pressed, when the functional water container 5 is dropped, when the functional water container 5 expands / contracts due to environmental temperature change, In such a case, the hydrogen gas generated by the hydrogen gas generation reaction in the reaction chamber is allowed to be released to the functional water 7 side, and the reaction water generated by the reaction It is set to a value that can regulate the outflow of the reactant to the functional water 7 side and the inflow of the functional water 7 to the reaction chamber side.

The weir cross-sectional area of the spiral hydrogen gas passage 71 is preferably (π × 0.25 ² ) mm ² to (π × 3.0 ² ) mm ² , more preferably (π × 0. It is arbitrarily set within the range of 5 ² ) mm ² to (π × 1.5 ² ) mm ² .

  As described above, the hydrogen gas suction device 101 is connected to the hollow shaft 29 for gas venting. The hydrogen gas suction device 101 has the following configuration. First, a connector 103 is attached to the gas vent hollow shaft 29, and a hydrogen gas suction tube 105 is connected to the connector 103. The connection tool 103 includes a hollow screw shaft 103a, a nut 103b, and a washer 103c. This hydrogen gas suction tube 105 is connected to another looped hydrogen gas suction tube 109 via a connector 107. A nostril cannula 111 is attached to the hydrogen gas suction tube 109. The user 2 inserts the nostril cannula 111 into his nostril 113 and inhales hydrogen gas.

  As described above, the valve portion 33 is normally seated on the seat portion 31 and the vent hole 34 for gas venting is closed. On the other hand, by rotating the rotation operation portion 29b to loosen the threaded hollow shaft 29 to the valve seat sleeve 23 and pulling it upward, the valve portion 33 is removed from the seat portion 31. Separate. As a result, the vent hole 34 is opened, and gas is vented through the vent hole 34, the vent hole 29 c, and the hollow portion 29 a of the vent shaft 29. The degassed hydrogen gas is sucked into the user 2 through the hydrogen gas suction device 101.

The operation will be described based on the above configuration.
First, the hydrogen gas generation unit 3 is outside the functional water container 5, and the inner container 63 is outside the outer container 51. First, a hydrogen gas generating agent kit 67 is put into the inner container 63 and a predetermined amount of reaction water 80 is put therein. Next, the inner container 63 is placed in the outer container 51 and sealed with the cap 53.

  On the other hand, the functional water container 5 is filled with a predetermined amount of functional water 7. Next, the hydrogen gas generation unit 3 is put into the functional water 7 in the functional water container 5 and sealed with the cap 11. If left in that state, the hydrogen gas generating agent 81 and the reaction water 80 contact and react in the hydrogen gas generating unit 3 to generate hydrogen gas.

  When this point is explained in detail, when water for reaction 80 at 4 ° C. to 30 ° C. is permeated into and impregnated into the hydrogen gas generator kit 67, calcium oxide (CaO) of the main agent B and water (2H 2 O) react. As a result, calcium hydroxide (CaOH) is generated, and at the same time, heat of hydration is generated. The alkali solution of calcium hydroxide (CaOH) heated to 40 ° C. or more by the heat of hydration reacts with aluminum (Al) as the main agent A to generate hydrogen gas. And aluminum (Al) of the main ingredient A further generates hydrogen gas while generating its own reaction heat.

  The generated hydrogen gas flows through the upper end opening 63 a of the inner container 63 and flows down in the heat insulating space 79 between the inner container 63 and the outer container 51. The flowing down hydrogen gas passes through the hydrogen gas vent 65, the hydrogen gas vent 69, the spiral hydrogen gas vent 71, the hydrogen gas vents 73 and 75, and the fine bubble generator 61 in the functional water in the functional water container 5. 7 is released. The released hydrogen gas is dissolved in the functional water 7, and as a result, highly concentrated hydrogen water is generated.

The description of the operation of the fine bubble generator 61 will be supplemented. When hydrogen gas is released through the fine bubble generator 61, it is released in the form of microbubbles. The microbubbles of hydrogen gas floating in the functional water 7 are further dissolved in the functional water 7 so that the diameter thereof is further reduced, and the transition from floating to staying is performed. Then, the dissolution of microbubbles into the functional water 7 proceeds to form nanobubbles (bubble diameter is 10 to 100 nm), and finally, it becomes a critical state and self-destructs. As a result, the functional water 7 becomes high-concentration dissolved hydrogen water. Further, the self-destruction causes super-high pressure and super-impact, thereby promoting self-destruction.
Further, the pressure in the functional water container 5 rises to, for example, 0.7 Mpa due to the generation of hydrogen gas. Although the hydrogen gas saturated dissolved concentration at normal pressure is about 1.6 ppm, by increasing the pressure to 0.7 Mpa, the hydrogen gas saturated dissolved concentration rises to about 7.0 ppm.

Next, inhalation of the generated hydrogen gas and drinking of the functional water 7 as the produced hydrogen water will be described.
Before opening the cap 9 to drink the functional water 7 as hydrogen water, the gas vent valve 19 is gradually opened. Accordingly, the pressure in the functional water container 5 is gradually reduced (for example, 0.7 Mpa is released into the atmosphere), and at the same time, the pressure in the hydrogen gas storage chamber 64 is not released into the functional water 7. The hydrogen gas remaining in is gradually released and dissolved in the functional water 7 through the fine bubble generator 61. The operation of the fine bubble generator 61 at that time is as described above. Thereby, the hydrogen concentration of the functional water 7 is significantly increased.

  The hydrogen gas released by gradually opening the gas vent valve 19 is sucked into the user 2 through the hydrogen gas suction device 101. That is, hydrogen gas is sucked through the connecting portion 103, the hydrogen gas suction tube 105, the connector 107, the hydrogen gas suction tube 109, and the nostril cannula 111. Thereby, the user 2 can inhale high concentration hydrogen gas efficiently.

  When the inhalation of hydrogen gas is finished, the cap 11 is opened and the functional water 7 that has become hydrogen water is directly drunk through the drinking mouth 9 or is poured into a cup (not shown) for drinking.

As described above, according to the present embodiment, the following effects can be obtained.
First, since hydrogen gas released by degassing performed as a pretreatment when drinking hydrogen water is sucked, the hydrogen gas can be effectively used. Moreover, hydrogen gas can be inhaled in a high concentration state.
In this embodiment, since the hydrogen gas suction device 101 is directly attached to the gas vent valve 19 of the functional water container 5, for example, the hydrogen water production device 1 is gripped to suck the hydrogen gas. It is possible to provide high portability.
In the case of the present embodiment, the reactants during the hydrogen gas generation reaction in the hydrogen water production apparatus 1 are not mixed into the functional water 7, and the reactants are not contained in the hydrogen gas. Therefore, unlike the prior art, a configuration for cleaning the generated hydrogen gas is not necessary in the first place, and this is the degassing of the functional water container 5 of the hydrogen gas suction device 101. The direct attachment to the valve 19 is made possible, whereby the configuration can be simplified.
Further, since the hydrogen gas suction device 101 is detachably attached to the degassing valve 19 of the functional water container 5, when the hydrogen gas is not sucked, the hydrogen gas suction device 101 is attached to the degassing valve 19 of the functional water container 5. You can remove it from.
Further, the hydrogen gas inhaler 26 used in the present embodiment has a simple configuration using a nostril cannula 38, and for example, a commercially available product can be used.

  Next, a second embodiment of the present invention will be described with reference to FIG. In the case of the first embodiment, the hydrogen gas suction device 101 using the nostril cannula 111 has been described as an example. However, in the case of the second embodiment, the suction mask 121 is used. The hydrogen gas suction device 101 will be described as an example. This will be described below.

The suction mask 121 is connected to the connector 107. The inhalation mask 121 includes a mask main body 123 and string members 125 and 127 connected to the left and right of the mask main body 123. A connection port 129 is formed in the mask main body 123, and the connection tool 107 is detachably attached to the connection port 129. The mask main body 123 has a plurality of air suction holes 131 and an air exhaust hole 133.
The other configuration is the same as that of the first embodiment, and the same parts are denoted by the same reference numerals in the drawings, and the description thereof is omitted.

  According to the above configuration, the user 2 sucks hydrogen gas through the suction mask 121 when the gas vent valve 19 is opened. At that time, it is possible to reduce the feeling that the user 2 feels short of breath and the like by generating an appropriate air flow through the air intake port 131 and the air exhaust hole 133. Can be improved.

  Therefore, the same effect as in the case of the first embodiment can be obtained, and safety during use can be improved.

Next, a third embodiment of the present invention will be described with reference to FIG. In the case of the third embodiment, the suction mask 121 in the case of the second embodiment is directly attached to the gas vent shaft 29 via the connectors 103 and 107.
The other configurations are the same as those in the first and second embodiments, and the same reference numerals are given to the same portions in the drawings, and the description thereof is omitted.

  According to the above configuration, the same effects as those of the first and second embodiments can be obtained, and the configuration of the hydrogen gas suction device 101 is further simplified, so that portability is greatly increased. Can be improved.

Next, a fourth embodiment of the present invention will be described with reference to FIG. In this case, the suction mask 121 in the second embodiment is made larger, thereby increasing the amount of air inflow / outflow.
The other configurations are the same as those in the second embodiment, and the same parts are denoted by the same reference numerals in the drawings, and the description thereof is omitted.

  According to the above configuration, the same effects as those of the second embodiment can be obtained, and the amount of inflow / outflow of air can be increased by increasing the size of the suction mask 121. Thereby, further improvement in safety when inhaling hydrogen gas can be achieved.

  Next, a fifth embodiment of the present invention will be described with reference to FIG. In the case of the first to fourth embodiments, the case where hydrogen gas is inhaled from the nose and / or mouth has been described as an example. In the case of the fifth embodiment, the hydrogen gas permeation device is used. 101 'is used as an example in which hydrogen gas is permeated from the skin and used mainly for cosmetic purposes.

  Details will be described below. As shown in FIG. 7A, a percutaneous permeation jig 151 is connected to the distal end of the hydrogen gas permeation tube 105 via a connector 107. As shown in FIG. 7 (b), the percutaneous penetration jig 151 is composed of a base portion 151a made of a hard member and a ring-shaped pressing member 151b made of a soft member. A chamber 151c is formed.

  And when using, as shown to Fig.7 (a), the said ring-shaped pressing member 151b is pressed on the skin of the face 161, for example. As a result, the hydrogen gas in the percutaneous penetration chamber 151c penetrates into the skin and provides various cosmetic effects.

Next, a sixth embodiment of the present invention will be described with reference to FIG. In the case of the sixth embodiment, instead of the percutaneous penetration jig 151 in the fifth embodiment, a transpenetrating jig 171 having another configuration is attached. The percutaneous permeation jig 171 includes a jig main body 171a and a percutaneous permeation attachment 171b detachably attached to the tip of the jig main body 171a. A skin permeation chamber 171c is formed. A ring-shaped member 171d is provided at the tip of the percutaneous penetration attachment 171b. The jig body 171a is formed in a hollow shape.
Other configurations are the same as those of the fifth embodiment, and the same reference numerals are given to the same portions in the drawing, and the description thereof is omitted.

According to the above configuration, the user 2 grasps the jig body 171 a and slides the percutaneous penetration attachment 171 b while touching the skin of the face 161, for example. As a result, the hydrogen gas in the percutaneous penetration chamber 171c penetrates into the skin, and the desired beauty effect can be obtained.
The percutaneous penetration attachment 171b is prepared in various sizes, and an appropriate size is selected and attached to the tip of the jig body 171a.

  Therefore, the same effect as in the case of the fifth embodiment can be obtained.

  Next, a seventh embodiment of the present invention will be described with reference to FIG. In the case of the first to sixth embodiments, the relief valve is not provided at the site of the degassing hollow shaft 29. In the case of the fifth embodiment, the gas venting is performed. The relief valve 301 is provided at the site of the hollow shaft 29 for use. This will be described below.

First, a relief exhaust hole 303 is formed in the degassing hollow shaft 29, and a ball valve 305 is accommodated on the relief exhaust hole 303. The ball valve 305 is always urged downward by a coil spring 307 so as to close the relief exhaust hole 303. The coil spring 307 is pressed in a state compressed by a predetermined amount by a spring pressing member 309. The spring pressing member 309 has a through hole 39a. On the other hand, when the pressure in the functional water container 5 exceeds a predetermined pressure, the ball valve 305 is lifted upward against the spring force of the coil spring 307, thereby opening the relief exhaust hole 303. Is done. By opening the relief exhaust hole 303, the hydrogen gas in the functional water container is exhausted via the degassing hollow shaft 29 and the hydrogen gas suction device 26.
The other configurations are the same as those in the first to sixth embodiments, and the same parts are denoted by the same reference numerals in the drawings, and the description thereof is omitted.

  According to the said structure, while being able to show the same effect as the case of the said 1st-6th embodiment, a safety valve function can be obtained.

The present invention is not limited to the first to seventh embodiments.
First, the configuration itself of the hydrogen water production apparatus is not particularly limited.
Further, the hydrogen gas generating agent is not particularly limited.
Further, the configuration of the hydrogen gas inhaler is not limited to that using a nostril cannula or a suction mask, and various configurations are conceivable.
Further, the configuration of the hydrogen gas permeation apparatus has been described by taking the permeation chamber as an example, but is not limited thereto.
Further, the site of percutaneous penetration for cosmetic purposes is not limited to the face.
In addition, the illustrated configuration is merely an example.

  The present invention relates to a hydrogen gas inhalation method, a hydrogen gas infiltration method, a hydrogen gas inhalation device, and a hydrogen gas infiltration device, and in particular, can efficiently inhale or infiltrate high-concentration hydrogen gas and be portable. For example, it is suitable for a portable hydrogen gas suction device and a hydrogen gas permeation device.

DESCRIPTION OF SYMBOLS 1 Hydrogen gas water production apparatus 3 Hydrogen gas generation unit 5 Functional water container 7 Functional water 9 Cap 19 Degassing valve 101 Hydrogen gas suction instrument 101 'Hydrogen gas permeation instrument 103 Connector 105 Hydrogen gas suction tube (hydrogen gas permeation tube)
107 connector 109 hydrogen gas suction tube 111 nostril cannula 121 suction mask 151 percutaneous permeation jig 151c percutaneous permeation chamber 171 percutaneous permeation jig 171c percutaneous permeation chamber

Claims (14)

  In order to increase the hydrogen gas concentration in the hydrogen water in the hydrogen water production equipment, when the hydrogen gas generated and stored in the hydrogen water production equipment is vented, the hydrogen gas to be vented is sucked. A method for inhaling hydrogen gas.   In order to increase the hydrogen gas concentration in the hydrogen water in the hydrogen water production equipment, when the hydrogen gas generated and stored in the hydrogen water production equipment is vented, the hydrogen gas to be vented is permeated. A hydrogen gas infiltration method characterized by the above. Hydrogen water production equipment,
A hydrogen gas suction device connected to the hydrogen water production device;
A hydrogen gas suction device comprising: Hydrogen water production equipment,
A hydrogen gas permeation instrument connected to the hydrogen water production instrument;
A hydrogen gas permeation apparatus comprising: The hydrogen gas inhaler according to claim 3, wherein
A hydrogen gas suction device, wherein the hydrogen water producing device is provided with a gas vent, and the hydrogen gas suction device is connected to the gas vent. The hydrogen gas infiltration device according to claim 4,
A hydrogen gas permeation apparatus, wherein the hydrogen water producing instrument is provided with a gas vent, and the hydrogen gas permeation instrument is connected to the gas vent. The hydrogen gas inhaler according to claim 5, wherein
The hydrogen water production apparatus includes a functional water container having a produced hydrogen water drinking port, the drinking port is closed by a cap so as to be freely opened and closed, and the gas vent is provided in the cap. A hydrogen gas suction device characterized by that. The hydrogen gas infiltration device according to claim 6,
The hydrogen water production apparatus includes a functional water container having a produced hydrogen water drinking port, the drinking port is closed by a cap so as to be freely opened and closed, and the gas vent is provided in the cap. A hydrogen gas permeation apparatus characterized by that. The hydrogen gas inhaler according to claim 3 or claim 5 or claim 7,
A hydrogen gas inhaler according to claim 1, wherein the hydrogen gas inhaler uses a nostril cannula. The hydrogen gas inhaler according to claim 3 or claim 5 or claim 7,
A hydrogen gas inhaler according to claim 1, wherein the hydrogen gas inhaler uses an inhalation mask. The hydrogen gas inhaler according to claim 10, wherein
2. The hydrogen gas suction device according to claim 1, wherein the suction mask is directly attached to the gas vent portion. In the hydrogen gas infiltration device according to claim 4 or claim 6 or claim 8,
The hydrogen gas permeation apparatus uses a percutaneous permeation chamber. In the hydrogen gas inhaler according to claim 3, or claim 5, or claim 7, or claim 9, or claim 10 or claim 11,
The hydrogen water producing apparatus is characterized in that a hydrogen gas generating agent mainly composed of aluminum and calcium oxide is used. In the hydrogen gas infiltration device according to claim 4 or claim 6 or claim 8 or claim 12,
The hydrogen water permeation apparatus, wherein the hydrogen water producing instrument uses a hydrogen gas generating agent mainly composed of aluminum and calcium oxide.

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