JP2023173966A - Hydrogen gas suction tool - Google Patents

Abstract

To provide a hydrogen gas suction tool capable of being carried, and stably generating a large amount of hydrogen gas with simple operation for suction of the hydrogen gas.SOLUTION: There is provided a hydrogen gas suction tool comprising: a container formed of a bottomed cylindrical trunk part and a mouth part, a lid body fitted to the mouth part, and a core stored in the container. In the hydrogen gas suction tool, water is scattered to a nonwoven fabric package including therein a hydrogen gas generator, for allowing a user to suck the generated hydrogen gas, the mouth part of the container has a cross sectional area greater than that of the trunk part, and a step part is formed on a boundary between the mouth part and the trunk part of the container. The lid body has a hole into which a suction pipe can be inserted. The core is formed in a cylindrical shape with an open upper end and a lower end as a bottom, a flange part is formed on the upper end edge of the core, and the core is supported to the step part at the flange part and is suspended from the container. On the bottom part of the lower end of the core, a hole into which the suction pipe can be inserted, a recess, and a hole through which the hydrogen gas can pass to the bottom of the recess, are formed. In the recess, an aroma ball is fitted.SELECTED DRAWING: Figure 4

Description

The present invention relates to a hydrogen gas suction device, and particularly to a hydrogen gas suction device suitable for carrying.

In recent years, attention has been focused on maintaining and improving health by taking hydrogen gas into the body. Inhaling hydrogen gas into the body is said to remove active oxygen such as hydroxyl radicals, which are deeply involved in many diseases such as aging, cancer, diabetes, and high blood pressure, and is also being incorporated into advanced medical care.

Hydrogen gas is a gas that can be easily produced by electrolysis of water, etc., and Patent Document 1 describes an invention of a suction tool that sucks hydrogen gas generated by electrolysis of water. This suction tool is small enough to be carried around in a bag, etc. It uses a built-in battery to supply electricity for electrolysis, and has controls to control the supply of electricity. It has a large number of parts, such as a mesh electrode plate connected to a titanium electrode, and the operations involved in generating hydrogen gas are complicated and expensive. It is something.
Since this suction tool is miniaturized to be portable, it is limited by the electrode area and battery capacity, and can only generate a relatively small amount of hydrogen gas in a short period of time.

On the other hand, Patent Document 2 discloses an invention of a hydrogen gas suction device that is small, lightweight, and portable and is not based on water electrolysis. This is a cylindrical nonwoven fabric whose front and rear ends are closed, and a cylindrical nonwoven fabric containing a hydrogen gas generator made of magnesium powder, citric acid powder, and powdered cellulose is housed in a cylindrical case. The cartridge, which is filled with a water-retaining material at the end and a water-absorbing material at the rear end, is attached to the holder of the suction tool to suck out hydrogen gas.

In the hydrogen gas suction device described in Patent Document 2, when the tip of a cartridge containing a hydrogen gas generator is immersed in water stored in a container, cup, etc. for a few seconds and pulled up, the device is filled into the tip of the cartridge. Water is retained in the water retaining material. This retained water then penetrates into the hydrogen gas generator due to the water absorption effect of the powdered cellulose, and magnesium and citric acid react to generate hydrogen gas.
When the generated hydrogen gas begins to be sucked through the suction port of the holder, water is replenished from the water retaining material at the tip of the cartridge to the hydrogen gas generator, and the reaction continues and hydrogen gas continues to be generated for a predetermined period of time.

In the hydrogen gas suction device described in Patent Document 2, the cartridge containing the hydrogen gas generator is approximately 5 cm long, and the holder is approximately 7 cm long, so it can be used in bags, handbags, clothing pockets, etc. It can be carried around by putting it in a bag.
However, in this invention, hydrogen gas is generated by immersing the tip of the cartridge in water stored in a container or cup for a predetermined period of time and then pulling it out. , it is necessary to pay close attention to operations such as how to soak the tip of the cartridge with water and how to tilt it, and it is somewhat difficult to stably generate the hydrogen gas to be aspirated. It took a long time for the hydrogen gas generation reaction to complete, making it impossible to aspirate a relatively large amount of hydrogen gas in a short period of time.

Patent No. 6464385 Patent No. 6436325

In view of these circumstances, the present invention has been developed to be able to be carried by putting it in a bag or handbag, to generate hydrogen gas stably with simple operations, and to inhale a relatively large amount of hydrogen gas in a short period of time. The purpose of the present invention is to provide a hydrogen gas suction tool that can perform

In order to solve the above problems, the present invention employs the following means.
[1] It has a container consisting of a bottomed cylindrical body and a mouth, a lid that fits into the mouth, and a core stored in the container, and contains hydrogen made of magnesium, citric acid, and cellulose. This is a hydrogen gas suction tool that can aspirate hydrogen gas generated by spraying water on a nonwoven fabric package containing a gas generating body, and the mouth of the container has a larger cross-sectional area than the body. A step part is formed at the boundary between the part and the body part, the lid has a hole through which the suction pipe can be inserted, and the core has a cylindrical shape with an open top end and a bottomed bottom end. The core is formed with a flange part, and is suspended and held by the stepped part of the container, and the bottom of the lower end of the core has a hole and a recess through which a suction pipe can be inserted, and the bottom of the recess allows hydrogen gas to pass through. A suction pipe is housed in the hole through which the suction pipe can be inserted, and an incense bead is housed in the recess, and when hydrogen gas is inhaled, the suction pipe is inserted into the hole formed in the lid body. 1. A hydrogen gas suction tool, characterized in that the hydrogen gas suction tool is capable of suctioning hydrogen gas by bringing the core into contact with a recess formed at the bottom of the lower end of the core.
[2] A sloped part is provided at a part other than the depression at the bottom of the lower end of the core, a hole through which the suction pipe can be inserted is formed in the sloped part, and the water sprayed at the lowest part of the slope is discharged. The hydrogen gas suction tool according to [1], characterized in that the hydrogen gas suction tool has a hole formed therein.
[3] According to [1] or [2], a gap is formed between a part of the flange portion of the core and the container, and a water pack is inserted and stored through the gap. Hydrogen gas suction device described.
[4] A gap is formed between the core and the container, a water pack is inserted and stored through the gap, and a nonwoven fabric packaging body containing a hydrogen gas generator is stored in the bottom of the container. The hydrogen gas suction tool according to [1] or [2], characterized in that:
[5] The hydrogen gas suction tool according to [1] or [2], characterized in that the hollow in which the incense beads are contained in the core is covered with a piece of sponge.

The hydrogen gas suction device of the present invention is composed of a container, a lid, a core, a suction pipe, etc., and can be made compact, so it can be carried in a bag or handbag, and the hydrogen gas generation device can be carried around. The nonwoven fabric packaging containing the gas is placed in a container, water is sprayed on it to generate hydrogen gas, and the suction pipe stored in the container is inserted into the hole formed in the lid to generate hydrogen gas. Since hydrogen gas can be inhaled, hydrogen gas can be generated and inhaled with a simple operation, and when inhaling, the scent of incense beads transfers to the hydrogen gas and you can feel that you are inhaling it. Hydrogen gas is generated by spraying water on a non-woven fabric package containing a hydrogen gas generator made of magnesium, citric acid, and cellulose, ensuring stable hydrogen gas and producing a relatively large amount in a short period of time. Hydrogen gas can be generated.

A front view (a) and a side view (b) of the entire external appearance of the hydrogen gas suction tool are shown. A front view (a) and a side view (b) of a container of a hydrogen gas suction tool are shown. A vertical cross-sectional view (a) and a top view (b) of the lid of the hydrogen gas suction tool are shown. A vertical cross-sectional view of the hydrogen gas suction tool is shown. In (a), the suction pipe is inserted through a hole in the core and housed, and in (b), it is inserted through a hole in the lid body and housed. A vertical cross-sectional view (a) and a top view (b) of the core are shown. It shows a state in which a piece of sponge covers the depression formed at the bottom of the core suspended in the container, in which the incense beads are contained. It is a photograph substituted for a drawing showing an example of a nonwoven fabric package containing a hydrogen gas generator. This is a photograph substituted for a drawing showing a stick-type water pack. This is a photograph substituted for a drawing showing a water pack different from a stick type.

Embodiments of the hydrogen gas suction tool of the present invention will be described based on the drawings. Hereinafter, the hydrogen gas suction tool will be simply referred to as a "suction tool."
Figure 1 shows the overall appearance of the suction tool. The suction tool 1 has a container 2 and a lid 3, and has a core 4 inside the container 2 (see FIG. 4).
As will be described later, the container 2 houses a non-woven fabric package 8 containing a hydrogen gas generator, and when sucking hydrogen gas, water is sprayed onto the non-woven fabric package 8 containing the hydrogen gas generator. The hydrogen gas generated can be sucked through a suction pipe 5 made of a tube.

FIG. 2 shows the container 2. As shown in this figure, the container 2 has a bottomed cylindrical body 21 and a mouth 22, and the body 21 and the mouth 22 have similar cross sections. The cross-sectional area of the mouth part 22 is larger than the cross-sectional area of the body part 21, and a step part 23 is formed at the boundary between the body part and the mouth part.
By forming the stepped portion 23, the container becomes strong and does not easily deform even if it is gripped. As will be described later, the core 4 is suspended on the stepped portion 23.

The lid 3 is fitted into the mouth 22 of the container 2 . As shown in FIG. 3, a hole 31 through which the suction pipe 5 can be inserted is formed in the lid 3. As will be described later, when sucking hydrogen gas, the suction pipe 5 is inserted into the hole 31 to suck the hydrogen gas. The diameter of the hole 31 is equal to the outer diameter of the suction pipe 5, so that there is no gap between the outer circumference of the suction pipe 5 and the hole 31. This prevents hydrogen gas from easily leaking from between the outer periphery of the suction pipe 5 and the hole 31 when hydrogen gas is suctioned. Although the hole 31 is formed near the edge of the lid 3 in the embodiment shown in FIG. 3, it is not limited to this location. Note that although a recess (no drawing number) is formed in the lid 3 to make the lid 3 difficult to deform, this recess may be omitted.
In this embodiment, as shown in FIG. 4, the lower end of the outer periphery of the lid 3 is inserted and fitted into the inner periphery of the mouth 22 of the container 2, but the reverse may be possible. Further, the present invention is not limited to this, and it is only necessary that there is no gap between the container 2 and the lid 3 and that the lid 3 can be attached and detached.

As shown in FIG. 4, the core is stored in the container 2 in a suspended state.
As shown in FIG. 5, the core 4 is a cylindrical body with an open upper end and a bottomed lower end.
A flange portion 41 is formed at the open upper end edge of the core 4, and this flange portion 41 is supported by the stepped portion 23 of the container 2, so that the core 4 is stored in a suspended state in the container 2. .

Since the core 4 is only supported by the stepped portion 23 and suspended from the container 2, the core 4 can be easily removed from the container 2. Before sucking hydrogen gas, the nonwoven fabric package 8 containing the hydrogen gas generator can be placed and stored on the bottom of the body 21 of the container 2 with the core 4 removed. When water is sprinkled on the nonwoven fabric package 8 containing the hydrogen gas generator, hydrogen gas is generated.

The bottom 42 at the lower end of the core 4 is formed with a hole 42a through which the suction pipe 5 can be inserted, and a recess 42b into which an incense ball (fragrance ball) 6 is housed. A hole 42c through which hydrogen gas can pass is formed at the bottom of the depression 42b. Further, a discharge hole 42d is formed in the bottom portion 42 at the lower end of the core 4 so that the water sprayed when hydrogen gas is sucked does not remain. Therefore, in the embodiment shown in FIG. 4, the bottom part 42 of the core has a portion other than the three holes 42a through which the suction pipe 5 can be inserted, the hole 42c through which hydrogen gas can pass, and the hole 42d through which the sprayed water is discharged. The bottom of the core is closed.

When suctioning hydrogen gas, the suction pipe 5 inserted into the hole 42a is pulled out to suction the hydrogen gas, but the water sprayed when suctioning the hydrogen gas is drawn out from the hole 42a through which the suction pipe 5 can be inserted. Since the liquid also drips, it is not necessary to provide the discharge hole 42d. When the hole 42d is provided, as shown in FIGS. 4 and 5, an inclined part is provided in a part other than the recess 42b of the bottom part 42 at the lower end of the core 4, and the lowest part of this inclined part is used for discharging the sprayed water. It is desirable to form a hole 42d for this purpose.

The hole 42a formed at the bottom of the lower end of the core 4 is used to accommodate the suction pipe 5 in the container 2, as shown in FIG. 4(a). As will be described later, these holes are also used as holes through which water to be sprayed on the nonwoven fabric package 8 containing the hydrogen gas generator passes. The suction pipe 5 is long enough to fit into the container 2 with the lid 3 fitted, and when not suctioning hydrogen gas, the suction pipe 5 is inserted into the hole 42a and stored in the suction tool 1. can be carried.

A hole 42c formed in the bottom 42 at the lower end of the core 4 through which hydrogen gas can pass is formed at the bottom of a recess 42b in which an incense ball (fragrance ball) 6 is housed. At the time of gas suction, hydrogen gas generated from the nonwoven fabric package 8 containing the hydrogen gas generator passes through this hole 42c, then passes through the outer circumference of the incense ball 6, and is inserted into the hole 31 of the lid body to form the recess 42b. is suctioned by the suction pipe 5 that comes into contact with the body [see FIG. 4(b)]. At this time, the scent of the incense beads 6 is transferred to the hydrogen gas, and this scent has the effect that the person inhaling can feel that he or she is inhaling hydrogen gas. Further, in the early stage of hydrogen gas generation, the odor of metal (Mg) in the hydrogen gas generator may be transferred to the hydrogen gas, but the incense beads 6 also have the effect of alleviating this odor.

The incense ball 6 used has a diameter of around 5 mm, and the inner diameter of the recess 42b in which the incense ball 6 is housed is also about that size, and the diameter of the hole 42c through which hydrogen gas passes is also sufficient to be around 1 to 3 mm. . There is a fine gap between the incense ball 6 and the depression 42b, and extremely small hydrogen gas molecules can pass through this gap, and the suction of hydrogen gas is not hindered.

It is desirable that the inner diameter of the suction pipe 5 is equal to or slightly larger than the inner diameter of the opening section of the recess 42b. Further, as shown in FIGS. 4 and 5, it is desirable to cover the opening of the depression 42b with a plate-shaped sponge piece 7, and to apply suction by contacting the suction pipe from above. By doing so, the suction pipe 5 can come into contact with the recess 42b without being displaced.

As shown in FIG. 4(b), the recess 42b is formed so as to be located directly below the hole 31 of the lid 3 when the suction tool 1 is vertically erected. This makes it easier for the suction pipe 5 to stably come into contact with the recess 42b during suction of hydrogen gas. Here, the recess 42b is formed near the edge of the bottom 42 of the core 4 in the same way that the hole 31 is formed near the edge of the lid 3, but the recess 42b is not limited to this position. Both the groove 42b and the depression 42b may be formed closer to the center.

As shown in FIG. 5(b), the cross-sectional shape of the cylindrical part of the core 4, which is a cylindrical body with a bottom, is constricted near the center and has an irregular shape. The flange width of the flange portion 41 formed at the upper end is also not constant, and the flange width is narrow in some parts of the cylindrical part [lower part in FIG. 5(b)], and in other parts [ In the upper part of FIG. 5(b), the flange width is wider. In a part of the region where the flange width is narrow, the flange portion 41 is not supported by the stepped portion 23 of the container 2, and a gap is formed between the container 2 and the flange 41 of the core 4. A water pack 9 can be inserted into this gap. In this way, the water pack 9 is inserted through the gap formed between the flange part 41 of the core 4, which is supported by the stepped part 23 and suspended in the container 2, and the container 2, and the water pack 9 is inserted into the container 2. 9 can be stored.
It is desirable that the length of the flange portion 41 that forms a gap with the container 2 be within 1/3 of the total circumferential length of the flange portion 41. Within this range, the core 4 can be stably suspended in the container 2.

The water pack 9 is dimensioned so that the upper end of the stored water pack 9 protrudes a little from the gap between the container 2 and the flange part 41. By doing so, when sucking hydrogen gas, the water pack 9 stored in the container 2 can be easily taken out, and then by opening it, the water pack 9 stored under the core 4 in the container 2 can be removed. Water can be sprayed onto the nonwoven fabric package 8 containing the hydrogen gas generator from above the container 2. As shown in FIG. 8, the water pack 9 is preferably stick-shaped so that it can be easily stored in the above-mentioned gap.

In the embodiment shown in FIG. 5(b), the flange width is narrowed in some parts of the cylindrical portion of the core 4 to form a gap between the container 2 and the flange 41 of the core 4. However, without forming such a gap, the flange part 41 is supported by the step part 23 of the container 2 at all parts of the flange part 41 of the core 4, and there is no gap between the container 2 and the flange 41 of the core 4. It is possible to prevent the formation of gaps.
In this case, the cross-sectional shape of the cylindrical portion of the core 4 does not need to be constricted near the center and have an irregular shape, and the width of the flange 41 can also be made approximately constant. In this embodiment, although it is not possible to insert a water pack into the gap between the flange 41 of the core 4 and the container 2, the core 4 suspended from the container 2 is removed and the water pack is inserted into the bottom 42 of the container 2 as shown in FIG. It can be stored by using a stick-type water pack 9 with shorter sides as shown.

The sprayed water passes through holes 42a and 42d formed in the bottom 42 of the core, and is dripped onto the nonwoven fabric package 8 containing the hydrogen gas generator. As shown in FIGS. 4 and 5, the bottom part 42 of the core is preferably provided with an inclined part, and a drainage hole 42d is provided in the lowest part, so that the sprayed water does not accumulate.
As described above, the suction tool 1 of the present invention can supply hydrogen gas even in places where water is not available, by storing the nonwoven fabric package 8 containing a hydrogen gas generator, the water pack 9, and the suction pipe 5 in the container 2. can be generated and sucked.

The suction tool 1 is preferably thick enough to be held by a person inhaling hydrogen gas, and preferably has a height of about 80 mm for carrying. The cross-sectional shape of the container 2 is not particularly limited, but a substantially rectangular, elliptical, or oval shape is suitable for gripping. Furthermore, if the container 2 is tapered toward the bottom, it will be easier to hold.
The container 2, lid 3, and core 4 of the suction tool 1 can be manufactured integrally by injection molding a resin material, respectively. They may also be manufactured from paper materials.

Water from a faucet or water from a plastic bottle can be used as the water to be sprayed onto the non-woven fabric package 8 containing the hydrogen gas generator, but the water pack 9 may be sprayed onto the non-woven fabric package 8 containing the hydrogen gas generator. Since an appropriate amount of water is sealed in accordance with the hydrogen gas generation reaction in step 8, there is an advantage that it is possible to avoid spraying too much water or too little water.

FIG. 7 shows an example of a nonwoven fabric package 8 containing a nonwoven fabric containing a hydrogen gas generator.
The non-woven fabric package 8 containing the hydrogen gas generator can be produced by, for example, folding a rectangular non-woven fabric in half and closing the width ends to form a bag shape, putting the hydrogen generator inside through the opening, and then closing the opening. You can make it. As the nonwoven fabric, for example, a hydrophilic food grade nonwoven fabric used for tea packs and the like can be used.
When water is sprinkled on the nonwoven fabric package 8 containing the hydrogen gas generator, the water easily passes through the nonwoven fabric and permeates into the hydrogen gas generator, generating hydrogen gas.

A mixture containing magnesium metal and citric acid can be used as a hydrogen gas generator that generates hydrogen gas by spraying water, but as described in Patent Document 2, magnesium powder, citric acid powder, Mixtures of cellulose and powdered cellulose can be employed. When water is sprinkled on this mixture, the magnesium and citric acid react, producing hydrogen gas. Unlike electrolysis of water, this reaction does not generate oxygen gas.
Note that the term "powder or granular material" here refers to particles constituting powder or granular material that include powder-like particles or granular particles with a particle size of approximately 1 mm or less (Patent Document (see 2).

In the case of a mixture of magnesium powder, citric acid powder, and powdered cellulose, preventing the materials of the mixture from separating allows the chemical reaction to continue and generates hydrogen gas more stably and efficiently. It is desirable to use an agglomerated mixture of three materials consisting of magnesium powder, citric acid powder, and powdered cellulose. A method of agglomerating is also described in Patent Document 2.

Approximately 3 g of hydrogen gas generator, which is made by mixing magnesium powder, citric acid powder, and powdered cellulose in a mass ratio of 1:3 to 9:1 to 3, is stored in a nonwoven fabric packaging. When water is sprayed and reacted, the reaction continues for about 1 minute, and a total amount of about 80 ml of hydrogen gas can be generated during that time. At this time, approximately 2.5 cc of water is required for the reaction, but approximately 3 to 5 cc of water is sufficient for spraying.

As mentioned above, the amount of the hydrogen gas generator may be about 3 grams, and the nonwoven fabric package 8 containing the hydrogen gas generator has a closing margin of about 8 mm, and even including the closing margin, the length and width are about 50 mm. It can be made into a flat shape with a thickness of about 8 mm.
Since the flat nonwoven fabric packaging body 8 containing hydrogen gas is flexible, it can be easily placed in contact with the surface of the bottom 42 of the container 2 from which the core 4 has been removed, so that the bottom 42 of the core 4 and the container It can be stored in the space between the bottom of the two.

A nonwoven fabric package 8 containing a hydrogen gas generator and a water pack 9 are stored in a container 2, and the suction tool 1 can be carried in a bag or handbag, so hydrogen gas can be suctioned anywhere.
Moreover, if the nonwoven fabric package 8 containing a spare hydrogen gas generator and the water pack 9 are carried in a bag or handbag, hydrogen gas can be repeatedly sucked using a suction tool.

FIG. 8 shows a stick-type water pack 9. This stick-type water pack has a long shape (the long side is longer than the short side) and is made of a laminated film of polyethylene resin and aluminum foil that encloses water. If you make a notch in one end, it will be easier to tear through the notch and disperse the sealed water. However, the present invention is not limited to this, and a flat water pack in which water is wrapped in a transparent resin film as shown in FIG. 9 can also be used.

The water pack 9 only needs to contain water corresponding to the amount of the hydrogen gas generator. If the amount of the hydrogen gas generator is about 3 g, 3 to 5 cc of water is sufficient, so the container 2 It can be made into a size that can be stored in.
In addition, the use of the water pack 9 can spray an amount of water commensurate with the amount of hydrogen gas generator, but the use of the water pack 9 prevents the spraying of too little water and not enough hydrogen gas, and the risk of spraying too much water. can be avoided.

When water is sprinkled from above the core 4 onto the nonwoven fabric package 8 containing the hydrogen gas generator placed at the bottom of the container 2, hydrogen gas is generated. At this time, the sprayed water drips from the holes 42a and 42d of the core 4 and immediately reaches the nonwoven fabric package 8 containing the hydrogen gas generator, so that the water quickly reaches the hydrogen gas generator in the nonwoven fabric. It permeates, a reaction occurs reliably, and hydrogen gas is generated stably.
In this way, the suction person pulls out the suction pipe 5, sprinkles water on the nonwoven fabric package 8 containing the hydrogen gas generator in the container 2, and then, after attaching the lid 3, sucks water into the hole 31 of the lid. Hydrogen gas can be sucked by inserting the pipe 5 [see FIG. 4(b)].

As already mentioned, approximately 80 ml of hydrogen gas can be generated per minute by spraying water onto the nonwoven fabric package 8 containing approximately 3 g of hydrogen gas generator. In the suction tool described in Patent Document 2, the amount of hydrogen gas generated is about 80 ml at most in 15 minutes. Further, since the suction tool described in Cited Document 1 is also a small electrolytic type, the amount of hydrogen gas generated is considered to be about several ml per minute at most.
As described above, the suction tool of the present invention can suction a relatively large amount of hydrogen gas in a short period of time, and can shorten the time that the suction device is restricted to suctioning a predetermined amount of hydrogen gas.

Since the reaction between magnesium, which is a hydrogen generator, and citric acid is an exothermic reaction, when hydrogen is generated within the container 2, the surface of the container 2 may reach a temperature of about 50°C. This can be achieved by using a container 2 that has a heat insulating effect, for example, one that is embossed, or by wrapping a cardboard sleeve around a paper cup.

The size of the suction tool 1 is not particularly limited as long as it can be held by a person, but if the hydrogen gas generator packaged in the nonwoven fabric package 8 is about 3 g, the suction tool 1 can be used for suction with the lid 3 fitted. The height of the tool 1 can be approximately 80 mm, the length of the cross section of the opening 22 of the container 2 can be approximately 60 mm, and the length of the cross section of the bottom 42 can be approximately 40 mm.
In this case, since the amount of water in the water pack 9 may be about 3 to 5 cc, the water pack 9 can be made to have a size that can be stored in the container 2.

Below, the basic procedure for sucking hydrogen gas from the suction tool 1 will be shown in steps 1 to 3. It is assumed that the container 2 of the suction tool 1 contains a nonwoven fabric package 8 containing a hydrogen gas generator, a water pack 9, and a suction pipe 5 in advance. The nonwoven fabric package 8 containing the hydrogen gas generator is stored by removing the core 4 and placing it on the bottom of the container 2. The water pack 9 is placed between the side of the core 4 and the body 21 of the container 2. The suction pipe 4 is housed in the gap formed between the two or in the bottom 2 of the container 2, and the suction pipe 4 is inserted and housed in the hole 42a formed in the bottom 42 of the core. Note that the procedure for sucking hydrogen gas is not limited to steps 1 to 3.

<Step 1>
Remove the lid 3 from the container 2, pull out the suction pipe 5 inserted into the hole 42a of the core inside the container 2, and take it out. The gap formed therebetween or the core 4 is removed and taken out from the bottom of the container 2.
<Step 2>
The water pack 9 is opened and water is sprinkled over the core 4 suspended in the container 2 again. Water drips from holes 42a and 42d formed in the bottom 42 of the core 4, permeates the nonwoven fabric package 8 containing the hydrogen gas generator, and generates hydrogen gas.
<Step 3>
Immediately fit the lid to the mouth 22 of the container 2, insert the suction pipe 5 into the hole 31 formed in the lid, and contact the opening of the recess 42b formed in the bottom 42 of the core 4. to aspirate hydrogen gas.

As shown in steps 1 to 3, if you carry the suction tool 1, which contains the nonwoven fabric package 8 containing the hydrogen gas generator, the water pack 9, and the suction pipe 5, even in places where water is not available. Can inhale hydrogen gas.
In addition, if you prepare a nonwoven fabric package 8 containing a spare hydrogen gas generator and a water pack 9, the container 2 and lid 3 of the suction tool 1 used in steps 1 to 3 can be used repeatedly to generate hydrogen gas. Can inhale gas.

If the suction pipe 5, the nonwoven fabric package 8 containing the hydrogen gas generator, and the water pack 9 are stored in the container 2 of the suction device 1 and carried, hydrogen gas can be suctioned even in places where water is difficult to obtain. It's convenient. At that time, if the nonwoven fabric package 8 containing the hydrogen gas generator and the water pack 9 are carried as spares in a bag or handbag, hydrogen gas can be repeatedly sucked with a simple operation.

The present invention meets the expectations of people who wish to inhale hydrogen gas on a daily basis because hydrogen gas can be aspirated with simple operations and the suction tool can be used repeatedly.

1: Hydrogen gas suction tool 2: Container 21: Body part 22: Mouth part 23: Step part 3: Lid body 31: (Suction pipe can be inserted through it) Hole 4: Core 41: Flange part 42: Bottom part 42a: (Suction Hole 42b (through which a pipe can be inserted): Hole 42c (through which hydrogen gas can pass): Hole 42d (through which hydrogen gas can pass): Drainage hole for sprayed water 5: Suction pipe 6: Incense ball (air freshener ball)
7: Sponge piece 8: Non-woven fabric package containing hydrogen gas generator 9: Water pack

Claims (5)

A hydrogen gas generator made of magnesium, citric acid, and cellulose, comprising a container consisting of a bottomed cylindrical body and a mouth, a lid fitted to the mouth, and a core housed in the container. A hydrogen gas suction tool that can aspirate hydrogen gas generated by spraying water on a nonwoven fabric package containing
The mouth of the container has a larger cross-sectional area than the body, and a step is formed at the boundary between the mouth and the body of the container.
The lid has a hole through which the suction pipe can be inserted.
The core has a cylindrical shape with an open top end and a bottomed bottom end, and a flange portion is formed at the edge of the top end, and the core is suspended and held by the stepped portion of the container,
A hole and a depression through which a suction pipe can be inserted are formed at the bottom of the lower end of the core, and a hole through which hydrogen gas can pass through the bottom of the depression, and a suction pipe is housed in the hole through which the suction pipe can be inserted. Incense beads are kept in the hollow,
When suctioning hydrogen gas, the suction pipe is inserted into a hole formed in the lid body and brought into contact with a depression formed at the bottom of the lower end of the core to suction hydrogen gas. Gas suction device. A sloped part is provided at a part other than the depression at the bottom of the lower end of the core, a hole through which the suction pipe can be inserted is formed in the sloped part, and a hole through which the sprayed water can be discharged is formed in the lowest part of the sloped part. The hydrogen gas suction tool according to claim 1, characterized in that the hydrogen gas suction tool is formed. Hydrogen gas suction according to claim 1 or 2, characterized in that a gap is formed between a part of the flange portion of the core and the container, and a water pack is inserted and stored through the gap. Ingredients. A gap is formed between the core and the container, a water pack is inserted and stored through the gap, and a nonwoven fabric package containing a hydrogen gas generator is stored in the bottom of the container. , The hydrogen gas suction tool according to claim 1 or 2. The hydrogen gas suction device according to claim 1 or 2, characterized in that the hollow in which the incense balls of the core are contained is covered with a piece of sponge.