WO2019181670A1 - Hydrogen gas generator - Google Patents

Abstract

Provided is a hydrogen gas generator capable of generating hydrogen gas rapidly by accommodating a bag of hydrogen-generating agent in a case and placing the case in a PET bottle, the hydrogen gas generator having a check valve function so that metal ions do not dissolve out into drinking water. A hydrogen-gas-generating space is provided, the hydrogen-gas-generating space placing a hydrogen-generating agent in a sealed cylindrical case to be placed in a PET bottle; a thin pipe for gas release having a check valve function which allows gas but not water to pass is provided to an end portion of the hydrogen-gas-generating space; the end of the thin pipe has a small hole for gas release; and the space between the outer circumference of the thin pipe which projects into the interior of a cylindrical case head and the cylindrical case inner circumference serves as a buoyancy space.

Description

Hydrogen gas generator

The present invention relates to a hydrogen gas generator that can be charged into a drinking water container such as a plastic bottle to generate hydrogen gas in the container and convert the drinking water into hydrogen water.

Hydrogen water generation technology is already known, and hydrogen gas can be generated by reacting water with a mixed powder of a metal such as Al or Mg and a hydrogen generating agent such as Ca oxide or Ca hydroxide. Hydrogen water is produced | generated by making this hydrogen gas contact-dissolve in drinking water.

For this purpose, the hydrogen generating agent is stored in a non-woven sachet, the sachet is contained in a case of a certain shape, and the beverage is placed in a drinking water container such as a plastic bottle when drinking. Technology (for example, see Patent Document 1) has appeared.

Various methods have been considered for the contact between the hydrogen generating agent sachet and water. For example, the hydrogen generating agent bag is dipped in water in advance before being stored in the case, and the bag is moistened. And Thereafter, a bag of wet hydrogen generating agent is accommodated in the case. With the hydrogen gas generating reaction in the case, the case is put in a plastic bottle together with a bag of hydrogen generating agent.

Then, hydrogen gas from the case is filled in the bottle, and at the same time, dissolved in drinking water to generate hydrogen water.

Also, as another technique for producing hydrogen water, a technique for inventing hydrogen water by injecting only a small bag containing a hydrogen generating agent into a plastic bottle and reacting with drinking water in the plastic bottle without using a case was invented.

However, in the invention for producing these hydrogen waters, it is necessary to prevent the metal ions from Al and Mg from eluting into the drinking water of the PET bottle when hydrogen is produced.

Therefore, in the hydrogen generator in which the hydrogen generation bag is put in the case, it is necessary to provide a check valve function that discharges hydrogen gas to the case but does not discharge drinking water so that the drinking water does not enter the case. . On the other hand, in a hydrogen generator that puts only a small bag containing a hydrogen generating agent into a plastic bottle without using a case, the material of the bag containing the hydrogen generating agent is devised. That is, as a material of the bag, water for reacting with the metal is easily penetrated, and a bag capable of releasing hydrogen gas generated in the bag is used, but metal ions are not emitted from the bag. Thus, it is necessary to provide a check function for blocking metal ions in the bag.

This metal ion block is an essential requirement for maintaining health.

JP2015-214372A

However, in a hydrogen generator that uses a case, the hydrogen generating agent and water can be directly contacted in the case to improve the hydrogen generation efficiency. In order to add a valve function, the structure of the device becomes complicated and difficult to use.

In addition, it is difficult to make a hydrogen generator bag material that can reliably block metal ions with a hydrogen generator that puts a bag containing hydrogen generator directly into a plastic bottle, and it cannot fully perform the function of blocking metal ions. In addition, since it takes 10 hours or more for drinking water to soak from a non-woven bag or the like and react with the hydrogen generating agent, hydrogen generation takes a long time.

In the present invention, a bag of a hydrogen generating agent is accommodated in a case, and the case is placed in a plastic bottle so that hydrogen gas can be generated quickly, and the metal ion is not dissolved in the drinking water. We intend to provide a hydrogen gas generator with a valve stop function.

In this invention, a hydrogen gas generation space for containing a hydrogen generating agent is provided in a sealed cylindrical case to be put in a PET bottle, and water is passed through the end of the hydrogen gas generation space through which gas passes. A narrow pipe for gas discharge having a check valve function that does not pass is provided, and the end of the thin pipe is used as a small hole for gas discharge, and the outer periphery of the thin pipe protruding inside the cylindrical case head and the inner periphery of the cylindrical case It is intended to provide a hydrogen gas generator characterized by a buoyant space in between.

Further, the head of the cylindrical case is a cap body that is solidified to the cylindrical case body, and a buoyancy space is provided in the cap body.

Also, the cylindrical case is formed of a flexible film material that can retain its form.

Also, a jacket structure for heat insulation is provided between the hydrogen gas generation space and the outer wall of the cylindrical case.

Also, the cylindrical case is characterized by having a bellows structure in the wall portion that causes a negative pressure inside and generates an external water suction force.

According to the present invention, a hydrogen gas generation space for containing a hydrogen generating agent is provided in a sealed cylindrical case to be placed in a PET bottle, and gas is passed through the end of the hydrogen gas generation space. A thin pipe for gas discharge having a check valve function that does not allow water to pass through is provided, and the end of the thin pipe is used as a small hole for gas discharge, and the outer periphery of the thin pipe protruding into the inside of the cylindrical case head and the cylindrical case A buoyancy space is formed between the inner circumferences, and the cylindrical case of the hydrogen gas generator is used by being put into a plastic bottle. Within the sealed cylindrical case, hydrogen gas generated by the hydrogen generating agent is stored in the hydrogen gas generation space. When the gas pressure in the hydrogen gas generation space increases, the gas passes through the narrow pipe, is released into the PET bottle from the gas discharge hole, and is dissolved in the drinking water in the PET bottle to generate hydrogen water. The drinking water in the PET bottle does not enter the cylindrical case due to the check valve function by the thin pipe, and the water that has reacted to the hydrogen generating agent does not go out of the cylindrical case. There is no risk of metal ions dissolving in drinking water. And when the cylindrical case of the hydrogen gas generator is put into the PET bottle, it floats on the drinking water in the PET bottle with the head up, so the small gas discharge hole at the end of the thin pipe is on the water surface. In addition to the check valve function by the thin pipe, it is possible to reliably prevent the drinking water from flowing back into the cylindrical case.

In addition, the head of the cylindrical case is a cap body that is solidified to the cylindrical case main body, and the cap body provided with a buoyancy space is a processing of a separate cap body that is solidified to the cylindrical case main body. Easy to remove and efficient.

In addition, a cylindrical case made of a flexible membrane material that can retain its form can be simplified as a whole, and can contribute to cost reduction. Moreover, since it can be crushed and discarded, it is suitable as a disposable structure.

In addition, those provided with a jacket structure that insulates between the hydrogen gas generation space and the outer wall of the cylindrical case, the hydrogen gas generation space is insulated, without being adversely affected by the temperature of the drinking water in the plastic bottle, Hydrogen gas can be generated reliably.

In addition, the cylindrical case has a bellows structure on the wall that generates negative water pressure by generating a negative pressure inside the tube, so that it can easily suck water to generate hydrogen in the cylindrical case. Can be efficient.

It is a longitudinal cross-sectional view of one embodiment of the hydrogen gas generator according to the present invention. 1 is a perspective view of an embodiment of a hydrogen gas generator according to the present invention. It is explanatory drawing which shows the state which injected | thrown-in the hydrogen gas generator of one Embodiment of the hydrogen gas generator which concerns on this invention in the PET bottle. 1 shows an embodiment of a hydrogen gas generator according to the present invention, where (a) is a cross-sectional view taken along line AA in FIG. 1, and (b) is a cross-sectional view taken along line BB. It is a longitudinal cross-sectional view of another embodiment of the hydrogen gas generator which concerns on this invention. It is a longitudinal cross-sectional view of further another embodiment of the hydrogen gas generator which concerns on this invention. It is CC sectional drawing in FIG. 6 of the hydrogen gas generator which concerns on this invention. It is a longitudinal cross-sectional view of further another embodiment of the hydrogen gas generator which concerns on this invention. It is explanatory drawing which shows the preparation state of further another embodiment of the hydrogen gas generator which concerns on this invention. It is a longitudinal cross-sectional view of further another embodiment of the hydrogen gas generator which concerns on this invention, Comprising: (a) is the state which shrunk the bellows, (b) shows the state which open | released the bellows. It is a longitudinal cross-sectional view of further another embodiment of the hydrogen gas generator which concerns on this invention, Comprising: (a) is the state which shrunk the bellows, (b) shows the state which open | released the bellows.

The gist of the present invention is that a hydrogen gas generation space for containing a hydrogen generating agent is provided in a sealed cylindrical case for entering a PET bottle, and gas is passed through the end of the hydrogen gas generation space. A thin pipe for gas discharge having a check valve function that does not allow water to pass through is provided, and the end of the thin pipe is used as a small hole for gas discharge, and the outer periphery of the thin pipe protruding into the inside of the cylindrical case head and the cylindrical case It is an object of the present invention to provide a hydrogen gas generator characterized in that a buoyancy space is provided between the inner circumferences.

Also, the head of the cylindrical case is a cap body that is solidified to the cylindrical case main body, and a hydrogen gas generator characterized by providing a buoyancy space in the cap body is provided.

Further, the present invention is intended to provide a hydrogen gas generator characterized by forming a cylindrical case with a flexible membrane material that can retain its form.

Also, the present invention is to provide a hydrogen gas generator characterized by providing a heat insulating jacket structure between the hydrogen gas generating space and the outer wall of the cylindrical case.

Also, the cylindrical case is intended to provide a hydrogen gas generating device characterized in that the wall portion has a bellows structure that generates an external water suction force with a negative pressure inside.

Hereinafter, an embodiment of a hydrogen gas generator according to the present invention will be described in detail with reference to the drawings. 1 to 4 show an embodiment of the present invention, FIG. 1 is a longitudinal sectional view, FIG. 2 is a perspective view, and FIG. 3 is an explanatory view showing a state in which a hydrogen gas generator is put into a PET bottle. 4A is a cross-sectional view taken along the line AA in FIG. 1, and FIG. 4B is a cross-sectional view taken along the line BB.

As shown in FIGS. 1 and 2, the basic configuration of the hydrogen gas generator A is that the cap body 20 is fixed to the head of the cylindrical case body 30, and the bottom member 25 is fixed to the lower end of the cylindrical case body 30. The cylindrical case 10 is tied.

As shown in FIG. 1, the cylindrical case 10 is configured such that the cap body 20 is fitted and fixed to the head of the cylindrical case main body 30 via a seal member 21, and the bottom member 25 is formed at the lower end of the cylindrical case main body 30. A bottomed cylindrical shape fitted and consolidated via a seal member 22 is formed. A buoyancy space 23 is formed inside the cap body 20. Needless to say, the sealing members 21 and 22 may be removed and bonded, or may be screwed together.

If the length of the cylindrical case 10 is longer than the length of the inner diameter of the plastic bottle to be inserted, the upper and lower end portions of the cylindrical case 10 hit the inner peripheral wall of the plastic bottle when the cylindrical case 10 is put in the plastic bottle and do not turn upside down. .

The peripheral wall of the cylindrical case body 30 has a jacket structure 32. Therefore, the temperature of the drinking water outside the cylindrical case 10 is interrupted so that the temperature of the drinking water is not transmitted to the hydrogen generating agent accommodated in the cylindrical case 10, and the reaction heat from the hydrogen generating agent is also received by the cylindrical case. The cylindrical case 10 is provided with a function of blocking transmission from the water to the drinking water.

That is, the jacket structure 32 has a structure in which an inner wall 33 and an outer wall 34 are formed with a heat insulating space 35 between the inner and outer double walls. In addition, the heat shielding effect can be improved as much as possible by forming the peripheral wall of the cylindrical case body 30 to be thick.

With such a configuration, the reaction heat of the hydrogen generating agent is not transmitted to drinking water, the hydrogen generating reaction of the hydrogen generating agent is promoted, and the hydrogen generating agent can generate a large amount of hydrogen gas in a short time. It is said.

A vertically long space is formed inside the cylindrical case body 30. A small bag of the hydrogen generating agent 4 in a vertically long bag can be stored in the space in the vertical direction.

FIG. 1 and FIG. 4 (b) show a state in which a vertically long bag of the hydrogen generating agent 4 is stored in a vertically long space of the cylindrical case body 30. That is, the vertically long space of the cylindrical case body 30 is a housing part for the hydrogen generating agent 4 and forms a hydrogen gas generating space 31.

The hydrogen generating agent 4 is composed of a bag formed of a nonwoven fabric having water permeability and gas permeability, and a generating agent that generates hydrogen by being stored inside the bag and reacting with water. The generating agent is not particularly limited as long as it can generate hydrogen by reacting with water. For example, a mixed powder of Al, Mg, Ca oxide, Ca hydroxide, or the like is used.

Before using the hydrogen generating agent 4 bag, that is, before storing it in the inside of the cylindrical case body 30, immerse it half in water and moisten it. As a result, the generating agent in the bag is brought into contact with water in advance to cause a hydrogen generation reaction. The water that causes the hydrogen generation reaction may be, for example, drinking water in a plastic bottle P or tap water.

Moreover, since the buoyancy space 23 is formed inside the cap body 20 at the upper end portion of the cylindrical case 10, the cylindrical case 10 placed in the plastic bottle P is substantially upright with the upper end portion facing upward. It will float in a hanging position.

Therefore, the cylindrical case 10 floats in a state where the gas discharge small holes 12 are always directed upward in the plastic bottle by the buoyancy of the case.

That is, at the center of the ceiling peripheral wall of the cap body 20 covering the hydrogen gas generation space 31, a narrow pipe 11 having a check valve function protrudes into the buoyancy space 23, and a gas discharge small hole is formed at the end of the thin pipe 11. By drilling 12, the gas discharge small hole 12 is always open in the upper space in the PET bottle P. Thereby, hydrogen gas is discharged to the upper part in the PET bottle P and reacts with the drinking water in the PET bottle P to generate hydrogen water.

The relationship between the internal pressures of the cylindrical case 10 and the PET bottle P is that the upper and lower case internal pressures are equal to or greater than the PET bottle internal pressures at the time of hydrogen gas generation. The hydrogen gas inside the case heated by the heat shrinks or contracts, or when the plastic bottle P is strongly gripped, the upper and lower case internal pressure ≦ the plastic bottle internal pressure.

As a result, if the small gas discharge hole 12 is in the drinking water, the drinking water is sucked into the case by the internal pressure of the PET bottle that is higher than the internal pressure of the upper and lower cases, and metal ionic water is generated. Drinking water is contaminated with metal ions due to inadvertent release.

However, since the small hole 12 for gas discharge is opened in the upper space of the plastic bottle P, when it is thrown in, it prevents metal ions from entering the case by preventing drinking water from entering the case. It becomes possible to block elution into drinking water. Furthermore, since the thin pipe 11 performs the check valve function, drinking water outside the case cannot enter the hydrogen gas generation space 31.

With such a structure, it is possible to effectively release hydrogen gas from the hydrogen gas generation space 31 and to prevent the intrusion water and metal ion water from being discharged into the drinking water.

[Usage example of hydrogen gas generator]
The thus configured hydrogen gas generator A is used in the following manner.

After the cap body 20 is removed, the bag-like hydrogen generating agent 4 is dipped in the drinking water of the plastic bottle P and moistened, and then the hydrogen gas in the decomposed cylindrical case body 30 as shown in FIG. It is quickly stored in the generation space 31.

Next, the cap body 20 is fitted into the cylindrical case body 30 and solidified. In this state, the cylindrical case 10 is put into the plastic bottle P, the lid of the plastic bottle P is closed, and then the plastic bottle is shaken several tens of times.

The cylindrical case 10 is floating in the drinking water in a state where the small hole 12 for gas discharge is always directed upward in the plastic bottle and the substantially vertical posture is maintained.

Next, the hydrogen generating agent 4 stored in the hydrogen gas generating space 31 of the cylindrical case body 30 by standing for 10 to 15 minutes reacts with water dampened the bag to generate hydrogen gas. That is, hydrogen gas bubbles are generated from the gas discharge small holes 12 of the cylindrical case 10.

At this time, the hydrogen generating agent 4 generates heat with the hydrogen gas generation reaction, but as shown in FIG. 4, this reaction heat is blocked by the jacket structure 32 formed on the peripheral wall of the cylindrical case body 30, and the outer peripheral wall of the case. Is not transmitted to the drinking water in the plastic bottle P.

Hydrogen gas generated from the hydrogen generating agent 4 is released into the PET bottle P outside the cylindrical case from the gas discharge small hole 12 through the fine pipe 11 as the internal pressure increases.

And as shown in FIG. 3, hydrogen gas is stored above the PET bottle P to form a hydrogen gas reservoir space H, and the hydrogen gas is dissolved into the drinking water by gradually increasing the internal pressure of the PET bottle. Further, the gas discharge small holes 12 in the hydrogen gas generation space 31 are directed upward in the hole opening direction by the float function of the upper half of the cylindrical case 10. That is, the gas discharge small hole 12 is opened in the hydrogen gas reservoir space H above the surface of the drinking water.

As described above, the hydrogen gas continuously generated from the hydrogen generating agent 4 by the hydrogen gas generation reaction causes the cylindrical case internal pressure to be higher than or equal to the PET bottle internal pressure, and the upper half of the cylindrical case 10. Since it floats by the float function, drinking water does not enter the cylindrical case from the gas discharge small hole 12.

After the hydrogen reaction is completed, the hydrogen gas in the hydrogen gas reservoir space H in the PET bottle is mixed with the drinking water by shaking the PET bottle P so that the hydrogen gas is forcibly dissolved in the drinking water.

However, when the hydrogen gas generation reaction is completed, the temperature inside the cylindrical case 10 decreases, and the internal pressure of the cylindrical case becomes lower than the internal pressure of the plastic bottle due to an increase in the internal pressure of the bottle due to the grip when shaking the plastic bottle. There is a possibility that drinking water may enter the case 10 and metal ions may elute from the intrusion path into the drinking water.

However, the fine pipe 11 having a check valve function performs a check valve function that blocks the metal ion water from leaking into the plastic bottle P.

Moreover, since the peripheral wall of the cylindrical case has a jacket structure, the reaction heat of the hydrogen generating agent is not absorbed by the drinking water and cooled. Therefore, the hydrogen gas generation reaction of the hydrogen generating agent is promoted, a large amount of hydrogen gas is generated in a relatively short time, and hydrogen water can be generated in a short time.

That is, according to the present invention, by constituting the hydrogen generation unit mainly composed of the upper and lower cases, it is possible to generate hydrogen gas quickly and to prevent the metal ions from being dissolved in the drinking water. It is possible to provide a hydrogen gas generator that can perform the function of a valve.

[Another embodiment]
Hereinafter, another embodiment of the hydrogen gas generator according to the present invention will be described. FIG. 5 is a longitudinal sectional view of a hydrogen gas generator according to another embodiment. Hereinafter, the same parts as those in the previous embodiment are denoted by the same reference numerals.

In the present embodiment, there is no bottom member 25 in the previous embodiment, but a thin-film bag-shaped cylindrical case body 30a is provided, and a fitting member 36 is fixed to the upper end opening of the cylindrical case body 30a to be fitted. The cap body 20 is consolidated to the member 36. Further, a bag body 37 that forms the hydrogen gas generation space 31 is held downward from the fitting member 36. The hydrogen generating agent 4 is stored in the bag body 37.

The buoyancy space 23 is formed inside the cap body 20, and the narrow pipe 11 and the gas discharge small hole 12 are provided as in the previous embodiment.

Since the small hole 12 for gas discharge is opened in the upper space of the plastic bottle P, when it is thrown in, it prevents the drinking water outside the case from entering the case, so that the metal ions are in the drinking water. It is possible to block elution into Furthermore, since the thin pipe 11 performs the check valve function, drinking water outside the case cannot enter the hydrogen gas generation space 31.

With such a structure, it is possible to effectively release hydrogen gas from the hydrogen gas generation space 31 and to prevent the intrusion water and metal ion water from being discharged into the drinking water. And since the cylindrical case main body 30a was made into the thin film bag form and the hydrogen gas generation space 31 was made into the bag body 37, since these can be collapsed and made small and can be discarded, it becomes easy to make it a disposable structure.

[Still another embodiment]
6 and 7 show still another embodiment of the hydrogen gas generator according to the present invention. In the present embodiment, the shape can be maintained, but is formed from a flexible film material.

That is, in the sealed cylindrical case 10 for placing in a plastic bottle, a slightly flat outer case 13 and a hydrogen gas generation space 31 for containing the hydrogen generating agent 4 are constituted by an inner bag 38. At the end of the hydrogen gas generation space 31, there are formed a gas release narrow pipe 11 having a check valve function that allows gas to pass but not water, and the end of the narrow pipe 11 serves as a gas discharge small hole 12. Further, a buoyancy space 23 is defined between the outer periphery of the thin pipe 11 protruding inside the cylindrical case head and the inner periphery of the cylindrical case. The interior bag 38 and the space inside the cylindrical case 10 are communicated with each other through a small hole 38a, which is an escape when the internal pressure of the hydrogen gas generation space 31 is increased.

In this embodiment, since there is flexibility, the hydrogen generating agent 4 can be inserted into the interior bag 38 of the hydrogen gas generating space 31 by expanding the gas discharge small hole 12. And since it is flexible as a whole, it can be folded and crushed and discarded, which is suitable as a disposable structure.

[Still another embodiment]
8 and 9 show still another embodiment of the hydrogen gas generator according to the present invention. In the present embodiment, the whole is integrally molded as a flexible resin.

That is, in the sealed cylindrical case 10 for placing in a PET bottle, a hydrogen gas generation space 31 for containing the hydrogen generating agent 4 is integrally formed in the exterior 14. At the end of the hydrogen gas generation space 31, there are formed a gas release narrow pipe 11 having a check valve function that allows gas to pass but not water, and the end of the narrow pipe 11 serves as a gas discharge small hole 12. Further, a buoyancy space 23 is defined between the outer periphery of the thin pipe 11 protruding inside the cylindrical case head and the inner periphery of the cylindrical case.

In this embodiment, as shown in FIG. 9, the cylindrical case 10 is crushed and immersed in a container filled with water, and when the force is released, hydrogen gas is generated from the gas discharge small hole 12 through the thin pipe 11. Water can be put into the space 31.

[Still another embodiment]
FIG. 10 shows still another embodiment of the hydrogen gas generator according to the present invention. In the present embodiment, the whole is integrally molded as a flexible resin, and the upper wall portion of the cylindrical case 10 has a negative pressure inside the cylindrical case to generate an external water suction force. The structure 39 is used.

That is, the sealed cylindrical case 10 for placing in a plastic bottle has a base portion forming a hydrogen gas generation space 31 for containing the hydrogen generating agent 4, and an upper wall portion of the hydrogen gas generation space 31 has A bellows structure 39 is provided, and a gas discharge narrow pipe 11 having a check valve function that allows gas to pass but does not allow water to pass therethrough, and a gas discharge small hole 12 is formed at the end of the thin pipe 11 to form a cylindrical case. A buoyancy space 23 is defined between the outer periphery of the thin pipe 11 protruding inside the head and the inner periphery of the cylindrical case.

In this embodiment, as shown in FIG. 10 (a), when the head of the cylindrical case 10 is pushed and the bellows structure 39 is crushed, it is immersed in a container filled with water, and when the force is removed, FIG. 10 (b) As shown, the bellows structure 39 extends so that water can be put into the hydrogen gas generation space 31 from the gas discharge small hole 12 through the thin pipe 11.

[Still another embodiment]
FIG. 11 shows still another embodiment of the hydrogen gas generator according to the present invention. In the present embodiment, the entirety is integrally formed as a flexible resin, and the entire wall portion of the cylindrical case 10 has a bellows structure 39a.

That is, the sealed cylindrical case 10 for placing in a plastic bottle has a base portion forming a hydrogen gas generation space 31 for containing the hydrogen generating agent 4, and the entire wall portion of the hydrogen gas generation space 31 has a bellows structure. 39a, and a gas discharge narrow pipe 11 having a check valve function that allows gas to pass but not water, and a gas discharge small hole 12 formed at the end of the thin pipe 11 to form a cylindrical case head A buoyancy space 23 is defined between the outer periphery of the thin pipe 11 protruding inside the portion and the inner periphery of the cylindrical case.

In this embodiment, as shown in FIG. 11 (a), when the head of the cylindrical case 10 is pushed and the bellows structure 39a is crushed, it is immersed in a container filled with water, and when the force is released, FIG. 11 (b) As shown, the bellows structure 39a extends to allow water to enter the hydrogen gas generation space 31 from the small gas discharge hole 12 through the thin pipe 11.

The description of each embodiment described above is an example of the present invention, and the present invention is not limited to the above-described embodiment, and the present invention is not limited to the above-described embodiments. It goes without saying that various changes can be made according to the design or the like as long as they do not depart from the technical idea.

A Hydrogen gas generator 4 Hydrogen generating agent 10 Cylindrical case 11 Gas communication narrow pipe 12 having check valve function Gas discharge small hole 20 Cap body 23 Buoyancy space 25 Bottom member 30 Cylindrical case body 31 Hydrogen gas generation space 32 jacket structure 33 inner wall 34 outer wall 35 heat insulation space 39, 39a bellows structure

Claims (5)

1. A hydrogen gas generation space for containing a hydrogen generating agent is provided in a sealed cylindrical case for placing in a PET bottle,
   At the end of the hydrogen gas generation space, a gas discharge fine pipe having a check valve function that allows gas to pass but not water is provided, and the end of the thin pipe is used as a gas discharge small hole,
   A hydrogen gas generator characterized in that a buoyancy space is formed between an outer periphery of a thin pipe projecting inside a cylindrical case head and an inner periphery of the cylindrical case.
2. 2. The hydrogen gas generator according to claim 1, wherein the head of the cylindrical case is a cap body that is solidified to the cylindrical case body, and a buoyancy space is provided in the cap body.
3. 2. The hydrogen gas generator according to claim 1, wherein the cylindrical case is formed of a flexible film material that can retain its form.
4. 2. The hydrogen gas generator according to claim 1, wherein a jacket structure for heat insulation is provided between the hydrogen gas generation space and the outer wall of the cylindrical case.
5. 2. The hydrogen gas generator according to claim 1, wherein the cylindrical case has a bellows structure in the wall portion that generates a suction force of external water by making the inside negative pressure.

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