JP2023145257A - Hydrogen gas inhalator and hydrogen gas inhalation set - Google Patents

Abstract

To provide a portable hydrogen gas inhalator allowing a user to stably inhale a large amount of hydrogen gas to be inhaled with an easy operation, and hydrogen gas inhalation set.SOLUTION: A hydrogen gas inhalator is comprised of a paper cup with an inverted truncated conical shape, and a lid body. The lid body includes a lid main body to be fitted to an opening of the paper cup, a nozzle part formed on the lid main body and serving as a hydrogen gas suction port, and an annular part and a plate-like hanging part formed on the back side of the lid body. When the lid body is fitted around the opening of the paper cup, the outer peripheral surface of the annular part comes into contact with the inner peripheral surface of the opening of the paper cup, and as for the plate-like hanging part, a lower part of one lateral face of the plate-like hanging part comes into contact with the inner peripheral surface of the paper cup. An inhalation kit consists of a combination of a hydrogen-gas inhalator, a nonwoven fabric packaging body containing a hydrogen-gas generator and a water container containing water to be sprayed onto the nonwoven fabric packaging body.SELECTED DRAWING: Figure 1

Description

The present invention relates to a hydrogen gas suction tool and a hydrogen gas suction set.

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 and a hydrogen gas suction set that can do the following.

In order to solve the above problems, the present invention employs the following means.
[1] A hydrogen gas suction device consisting of a paper cup having an inverted truncated conical shape and a lid, which generates hydrogen gas by spraying water on a nonwoven fabric package containing a hydrogen gas generator housed in the paper cup. The lid body includes a lid body that fits into the upper end of the opening of the paper cup, a nozzle portion formed in the lid body that serves as a hydrogen gas suction port, and an annular portion formed on the back surface of the lid body. and a plurality of plate-like hanging parts, the annular part has an inverted truncated conical shape, and when the lid body fits into the upper end of the opening of the paper cup, the outer peripheral surface of the annular part The plate-shaped hanging part is in contact with the inner circumferential surface of the opening, and the lower end extends below the lower edge of the annular part, and the upper part of one side surface is joined to the inner surface of the annular part, A hydrogen gas suction device characterized in that, when the lid body is fitted into the upper end of the opening of the paper cup, a lower part of one side of the plate-like hanging part is close to or in contact with the inner surface of the paper cup.
[2] The hydrogen gas suction device according to [1], wherein a mouthpiece in which a suction hole is formed is placed over the tip of the nozzle portion.
[3] The hydrogen gas suction tool according to [1] or [2], wherein the suction hole of the nozzle portion or the mouthpiece is filled with a sponge.
[4] The hydrogen gas suction device according to any one of [1] to [3], wherein an aromatic agent ball is inserted into the suction hole of the nozzle portion or the mouthpiece.
[5] Consists of a combination of the hydrogen gas suction device according to any one of [1] to [4], a nonwoven fabric package containing a hydrogen gas generator, and a water container containing water to be sprayed onto the nonwoven fabric package. Hydrogen gas suction set.

The hydrogen gas suction device of the present invention and the hydrogen gas suction set including the same can be made small because the hydrogen gas suction device is composed of a paper cup and a lid, so it can be carried around by putting it in a bag or handbag, etc. Hydrogen gas can be generated by directly spraying water on a non-woven fabric package containing a hydrogen gas generator housed in a paper cup, then attaching a lid to a paper cup and sucking it in through a nozzle provided in the lid. Therefore, hydrogen gas can be generated and suctioned with a simple operation. In addition, since hydrogen gas is generated by spraying water directly onto the non-woven fabric package containing the hydrogen gas generator housed in a paper cup, hydrogen gas is reliably stabilized and a relatively large amount of hydrogen can be generated in a short period of time. Can generate gas.

A perspective view (a) and a vertical cross-sectional view (b) of a hydrogen gas suction tool are shown. A perspective view (a) and a vertical cross-sectional view (b) of a paper cup of a hydrogen gas suction device are shown. The lid of the hydrogen gas suction tool is shown. (a) is a perspective view seen from the front side of the lid 3, and (b) is a perspective view seen from the back side of the lid 3. A front view (a), a bottom view (b), and a longitudinal cross-sectional view (c) of the lid of the hydrogen gas suction tool are shown. It is a photograph substituted for a drawing showing an example of a nonwoven fabric package containing a hydrogen gas generator. It is a photograph substituted for a drawing showing a water pack as an example of a water container. It is a photograph substituted for a drawing showing a stick-type water package as an example of a water container. It is a photograph substituted for a drawing showing a sauce bottle type water container as an example of a water container. A perspective view (a) and a longitudinal cross-sectional view (b) of a hydrogen gas suction device with a mouthpiece attached to the upper end of the nozzle part are shown.

Embodiments of the hydrogen gas suction tool of the present invention will be described based on the drawings.
Figure 1 shows a hydrogen gas suction tool.
Here, 1 is a hydrogen gas suction tool, 2 is a paper cup, 3 is a lid body, 31 is a lid body, 32 is a nozzle part that serves as a suction port for hydrogen gas, 33 is an annular part, and 34 is a plate-like hanging part. be.
The hydrogen gas suction tool 1 consists of a paper cup 2 and a lid 3. A nonwoven fabric package containing a hydrogen gas generator is housed in the paper cup 2, and when water is sprinkled on the nonwoven fabric package, hydrogen gas is generated. A hydrogen gas aspirator can attach the lid 3 to the paper cup 2 and aspirate hydrogen gas from the nozzle portion 32 of the lid 3. The annular portion 33 and the plate-like hanging portion 34 will be described later.

A paper cup 2 is shown in FIG. As shown in this figure, the paper cup 2 has the shape of an inverted truncated cone, that is, a truncated cone upside down, and can be stacked. Further, the upper edge of the opening of the paper cup 2 is usually rolled up to the outside to form a curl 21. The curl 21 may be omitted.
Note that the paper cup 2 can be laminated with a polyethylene film to make it heat resistant and waterproof. Such paper cups are commercially available and well known.

The lid body 3 is shown in FIGS. 3 and 4. 3(a) is a perspective view of the lid 3 viewed from the front side, and FIG. 3(b) is a perspective view of the lid 3 viewed from the back side. FIGS. 4(a) to 4(c) show a front view, a bottom view, and a longitudinal cross-sectional view of the lid body 3.
The lid body 3 includes a lid body 31 that fits into the upper end of the opening of the paper cup 2, a nozzle part 32 that is formed to protrude from the front side of the lid body 31, an annular part 33 that is formed on the back side of the lid body 31, and A plurality of plate-like hanging parts 34 are provided.
The nozzle portion 32 has a suction hole formed therein and serves as a suction port for hydrogen gas. In FIGS. 1, 3 and 4, the nozzle portion 32 is formed at the center of the lid body 31, but it may not be located at the center.

A side portion is formed at the periphery of the lid body 31 of the lid body 3, and as shown in FIGS. 1(b) and 4(c), a stepped portion 311 projecting outward is formed on this side portion. ing. When the lid 3 is attached to a paper cup, the outer periphery of the stepped portion 311 fits over the upper end of the opening of the paper cup 2, and curls over the upper end of the opening of the paper cup. If a curl 21 is formed, the curl 21 is fitted over the curl 21.

An annular portion 33 having a low height, hollow, substantially cylindrical shape, and an inverted truncated cone shape is formed at the peripheral edge of the back surface of the lid body 31. The peripheral edge here is located a little inside the outer peripheral edge of the stepped portion 311, and a gap is formed between the outer peripheral edge of the stepped portion 311 and the annular portion 33. When the lid 3 is attached to the paper cup 2, the upper end of the opening of the paper cup fits into this gap, and the lid 3 is fitted onto the paper cup 2.
The height of the annular portion 33 may be 15 to 40% of the height of the cup, and the formation of the annular portion 33 makes the lid body 31 difficult to deform.

As shown in FIGS. 3 and 4, the annular portion 33 has an inverted truncated conical shape like the paper cup 2, so the outer diameter of the annular portion 33 changes depending on the position in the height direction. , the outer diameter of the annular portion 33 is made equal to the inner diameter which changes according to the height direction of the opening of the paper cup 2. With this arrangement, when the lid 3 is attached to the paper cup 2, the outer peripheral surface of the annular portion 33 will come into contact with the inner surface of the opening of the paper cup 2, and the lid 3 will fit into the opening of the paper cup 2. match.

On the inner surface of the annular portion 33, a plurality of plate-like hanging portions 34 extending downward from the back surface of the lid body 31 are formed at intervals and facing toward the center of the lid body 31 [see FIG. 4(b)]. ]. The lower end of the plate-like hanging portion 34 reaches further below the lower edge of the annular portion 33 [see FIGS. 4(a) and 4(c)].
The position of the lower end of the plate-like hanging part 34 is not limited as long as it does not touch the bottom of the paper cup 2, but it is below the lower edge of the annular part 33 and from the bottom of the paper cup 2 to the upper end of the opening. It is effective to reach a position between 1/2 of the height up to.

Until the plate-like hanging part 34 reaches the position of the upper edge of the annular part from the back surface of the lid main body 31, one side of the plate-like hanging part 34 is joined to the side inner surface of the peripheral edge of the lid main body 31, Furthermore, it is joined to the inner surface of the annular portion 33 from the position of the upper end edge of the annular portion to the position of the lower end edge. At a portion below the lower edge of the annular portion 33, one side surface of the plate-like hanging portion 34 extends downward parallel to the inclined surface of the inner surface of the paper cup having the shape of an inverted truncated cone. , or extend downward so as to touch this slope, that is, to become more perpendicular.
Note that the other side surface of the plate-like hanging portion 34 extends vertically downward from the back surface of the lid body 31, as shown in FIGS. 1(b) and 4(c).

By doing this, when the lid 3 is fitted to the paper cup 2, the opening at the top of the paper cup 2 is firmly supported by the annular part joined to the upper part of the plate-like hanging part 34. be able to. In addition, in the part below the opening at the top of the paper cup 2, the part on the lower side of one side of the plate-like hanging part 34 (the part below the position of the lower edge of the annular part 33) is connected to the paper cup 2. Since it can be made to be close to or in contact with the inner surface, the lower part of one side of the plate-like hanging part 34 is also close to or in contact with the paper cup 2, and is similar to the rib of the reinforcing material for the paper cup 2. can have the effect of

Therefore, when the lid 3 is attached to the paper cup 2 and the lid 3 is fitted into the opening of the paper cup 2, the upper end of the opening of the paper cup 2 is aligned with the step 311 on the outer periphery of the lid body 31. At the same time, the opening of the paper cup 2 is supported by the annular part 33 to which the upper part of the plate-shaped hanging part 34 is joined, and further, the part below the opening of the paper cup 2 is supported by the plate-shaped hanging part 34. 34 is close to or in contact with the side surface of the paper cup 2, so even if the paper cup 2 with the lid 3 attached is held, the paper cup 2 will not easily deform. do not. At this time, the opening of the paper cup 2 is sealed by the stepped part 311 and the annular part 33 of the lid body 31, so that the hydrogen gas in the paper cup 2 is transferred to the lid 3 and the paper cup. There is no leakage from the fitting surface of 2.
In addition, when the lower part of one side of the plate-shaped hanging part 34 is close to the side of the paper cup 2, it is preferable that the gap between both sides is about 0.25 mm or less at the closest point.

It is desirable that three or more, preferably five or more, plate-like hanging parts 34 be formed on the back surface of the lid 3 at equal intervals. In addition, in FIGS. 3 and 4, five plate-like hanging portions 34 are formed.
The width of the plate-shaped hanging portion 34 is approximately 1/2 or less of the radius of the annular portion 33 in the one shown in FIG. 4(b), but it may be wider. Further, it is preferable that the lower end of the plate-like hanging portion 34 be rounded.

The lid body 3 can be integrally manufactured with the lid body 31, the nozzle portion 32, the annular portion 33, and the plurality of plate-shaped hanging portions 34 by injection molding a resin material or the like. Alternatively, a similar integral lid 3 may be manufactured from a paper material. In addition, in FIG. 1(b), FIG. 3(b), and FIG. 4(c), the upper edge of the annular portion 33 is shown as a solid line, but the inner surface of the side back surface of the lid body 31 and the annular portion It is formed integrally with the inner surface of 33 so that there is no step.

When a nonwoven fabric package 4 containing a hydrogen gas generator is stored in the bottom of a paper cup 2 and water is sprinkled on it, hydrogen gas is generated. By attaching the lid 3 to the paper cup 2, hydrogen gas can be sucked through the nozzle portion 32 of the lid 3.
FIG. 5 shows an example of a nonwoven fabric package 4 containing a hydrogen gas generator.

The non-woven fabric package 4 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, and then closing the opening after putting the hydrogen generator inside through the opening. You can make it. As the nonwoven fabric, for example, a food grade nonwoven fabric used for tea bags and the like can be used.
When water is sprinkled on the nonwoven fabric package 4 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, It is desirable to employ a mixture of solid and powdered cellulose. When water is sprinkled on this mixture, the magnesium and citric acid react, producing hydrogen gas. Hydrogen gas is generated by the reaction between magnesium and citric acid. Unlike electrolysis of water, this reaction does not generate oxygen gas.
Note that the term "powder or granular material" herein means that the particles constituting the powder or granular material include powder-like particles or granular particles with a particle size of about 1 mm or less.

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 means for 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. By spraying water and causing a reaction, a total amount of about 150 ml of hydrogen gas can be generated per minute. 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 4 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.
The flat non-woven fabric packaging body 4 containing hydrogen gas can be formed on the bottom surface of the paper cup 2 by making the area of the bottom surface of the paper cup 2 equal to or larger than the area determined from the length and width of the packaging body 4. They can be placed so that they touch each other.

Since the hydrogen gas suction tool 1 can be carried together with the nonwoven fabric package 4 containing the hydrogen gas generator in a bag or handbag, hydrogen gas can be suctioned anywhere where water can be obtained.
The water to be sprayed on the non-woven fabric package 4 containing the hydrogen gas generator can be taken from a tap or a plastic bottle, but it is also possible to use a portable water pack, stick-type water package, or sauce bottle-type water container. It is also possible to take water from a water container 5 such as the like and spray it.

6 to 8 show a water pack, a stick-type water package, and a sauce bottle water container as examples of the water container 5, respectively.
The water pack shown in FIG. 6 has a flat shape in which water is wrapped in a transparent resin film, but it does not have to be transparent. Also, if you make a notch in the adhesive margin at the edge of the water pack, it will be easier to tear it through the notch and scatter the encapsulated water.
The stick-type water package shown in FIG. 7 is also an elongated one (the long side is longer than the short side) in which water is wrapped in a laminate film of polyethylene resin and aluminum foil. In this case as well, if a notch is made at one end, it will be easier to tear through the notch and disperse the enclosed water.
The sauce bottle type water container shown in FIG. 8 is a small container with a cap, and the cap can be removed to spray water.

The water container 5 should contain water corresponding to the amount of the hydrogen gas generator, and if the amount of the hydrogen gas generator is about 3g, 3 to 5cc of water is sufficient, so a paper cup can be used. It is possible to make the size so that it can be stored in 2.
If such a water container 5 is carried together with the nonwoven fabric package 4 containing the hydrogen gas generator in a bag or handbag, hydrogen gas can be inhaled conveniently regardless of the location, even in places where water is not available. It is.
In addition, the use of a water container can spray an amount of water commensurate with the amount of hydrogen gas generator, but the use of a water container can prevent 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 on a nonwoven fabric package 4 containing a hydrogen gas generator placed at the bottom of a paper cup 2, hydrogen gas is generated. At this time, water is sprayed directly onto the nonwoven fabric package 4 containing the hydrogen gas generator, so the water quickly penetrates into the hydrogen gas generator within the nonwoven fabric, ensuring a reaction occurs and stably. Hydrogen gas is generated. Moreover, the state in which water permeates into the nonwoven fabric package 4 containing the hydrogen gas generator in the paper cup 2 can be easily confirmed visually.
In this way, the suction person sprays water directly onto the nonwoven fabric package 4 containing the hydrogen gas generator in the paper cup 2, then attaches the lid 3 and immediately opens the nozzle portion 32 of the lid. Hydrogen gas can be sucked through the device, and hydrogen gas can be stably generated and sucked with a simple operation.

As already mentioned, approximately 150 ml of hydrogen gas can be generated per minute by spraying water onto a nonwoven package 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.

The reaction between magnesium, which is a hydrogen generator, and citric acid is an exothermic reaction, so when hydrogen is generated within the paper cup 2, the surface of the paper cup may reach a temperature of about 50°C, so the paper cup 2 has an insulating effect. For example, you can use an embossed cup or wrap a cardboard sleeve around a paper cup.

A hydrogen gas inhaler can inhale hydrogen gas from the nozzle part 32 of the lid body, but by placing a mouthpiece 6 with a hydrogen gas passage hole formed on the tip of the nozzle part 32, hydrogen gas can be inhaled through the mouthpiece 6. may be inhaled. A hole is formed in the center of the mouthpiece 6 through which hydrogen gas sucked through the nozzle portion 32 can pass. FIG. 9 shows a perspective view of a hydrogen gas suction tool in which the mouthpiece 6 is placed over the nozzle portion 32.

The suction hole of the nozzle part 32 and the hydrogen gas passage hole of the mouthpiece 6 are stuffed with sponge pieces, so that the generated hydrogen gas is directly connected to the outside air from the hydrogen gas suction hole and the passage hole of the nozzle part 32 and the mouthpiece 6. Prevent leakage in a state where the Even if it is stuffed with sponge pieces, hydrogen gas molecules are extremely small, so there is almost no problem in inhaling hydrogen gas.
Alternatively, the aromatic agent ball (flavor ball) may be sandwiched between, for example, two pieces of sponge and inserted into the suction hole of the nozzle portion or the passage hole of the mouthpiece. By doing this, you can inhale aromatic hydrogen gas, so you can actually feel that you are inhaling hydrogen gas.
The mouthpiece 6 can be easily cleaned by removing it from the nozzle portion 32. Moreover, when a sponge or an aromatic agent ball is placed in the mouthpiece 6, the mouthpiece 6 can be removed from the nozzle portion 32 and the sponge or aromatic agent ball can be easily replaced.

There is no particular restriction on the size of the hydrogen gas suction tool 1 as long as it can be held by a person, but if the hydrogen gas generator packaged in the non-woven fabric package 4 is about 3 g, the size of the paper cup 2 and the opening may vary. The diameter of the bottom part can be set to about 50 mm, the diameter of the bottom part can be set to about 40 mm, and the length of the nozzle part 32 of the lid can be set to about 40 mm. ) can be made approximately 90 mm.
In this case, the amount of water in the water container 5 may be about 3 to 5 cc, so any type of water container 5 can be stored in a paper cup 2 with a height of 50 mm, an opening diameter of 50 mm, and a bottom diameter of about 40 mm. It can be made as large as possible.

If you carry a hydrogen gas suction set that combines a nonwoven fabric package 4 containing a hydrogen gas generator, a water container 5, and a hydrogen gas suction tool 1, you can use hydrogen even in places where it is difficult to obtain water. It is convenient to be able to inhale gas. At that time, if the nonwoven fabric package 4 containing the hydrogen gas generator and the water container 5 are stored in the paper cup 2 of the hydrogen gas suction tool 1, and the hydrogen gas suction tool 1 is carried in a bag or handbag, It is even more convenient because everything you need to inhale hydrogen gas can be taken out as a set.

The paper cup 2 is disposable every time hydrogen gas is sucked, and the lid 3 can be used repeatedly.
Since the paper cups 2 can be stacked, it is also possible to carry a plurality of paper cups 2 by stacking them. In addition, paper cups 2 containing a nonwoven fabric package 4 containing a hydrogen gas generator, or paper cups 2 containing a nonwoven fabric package 4 containing a hydrogen gas generator and a water container 5, can be stacked to form a plurality of paper cups. It is also possible to carry a cup with you.

The present invention allows hydrogen gas to be inhaled with a simple operation, and the hydrogen gas inhaler is a relatively inexpensive device consisting of a disposable paper cup and a reusable lid, so hydrogen gas can be inhaled on a daily basis. It meets the expectations of people who wish to inhale gas.

1: Hydrogen gas suction tool 2: Paper cup 21: Curl 3: Lid body 31: Lid body 311: Step portion 32: Nozzle portion 33: Annular portion 34: Plate-like hanging portion 4: Nonwoven fabric containing hydrogen gas generator Package 5: Water container 6: Mouthpiece

Claims (5)

A hydrogen gas suction device consisting of a paper cup having an inverted truncated conical shape and a lid, which generates hydrogen gas by spraying water onto a nonwoven fabric package containing a hydrogen gas generator housed in the paper cup. ,
The lid body includes a lid body that fits into the upper end of the opening of the paper cup, a nozzle portion formed in the lid body that serves as a hydrogen gas suction port, an annular portion formed on the back surface of the lid body, and a plurality of plates. and a hanging part;
The annular portion has an inverted truncated conical shape, and when the lid body is fitted to the upper end of the opening of the paper cup, the outer circumferential surface of the annular portion contacts the inner circumferential surface of the opening of the paper cup,
The plate-shaped hanging part is formed by having a lower end extending below the lower edge of the annular part, and an upper part of one side surface being joined to the inner surface of the annular part, and the lid body is connected to the opening of the paper cup. A hydrogen gas suction device characterized in that a lower portion of one side of the plate-like hanging portion is close to or in contact with the inner surface of the paper cup when the device is fitted to the upper end of the paper cup. 2. The hydrogen gas suction device according to claim 1, wherein the tip of the nozzle portion is covered with a mouthpiece having a suction hole formed therein. The hydrogen gas suction device according to claim 1 or 2, wherein the suction hole of the nozzle portion or the mouthpiece is filled with a sponge. The hydrogen gas suction device according to any one of claims 1 to 3, wherein an aromatic agent ball is inserted into the suction hole of the nozzle portion or the mouthpiece. Hydrogen comprising a combination of the hydrogen gas suction tool according to any one of claims 1 to 4, a nonwoven fabric package containing a hydrogen gas generator, and a water container containing water to be sprayed onto the nonwoven fabric package. Gas suction set.