JP7105599B2 - portable hydrogen gas suction system - Google Patents

Description

TECHNICAL FIELD The present invention relates to a health system using hydrogen gas, and more particularly to a portable hydrogen gas suction system.

In recent years, hydrogen has been attracting attention as a fuel for hydrogen-powered automobiles, and it has been reported that hydrogen water, in which hydrogen is dissolved in water, is useful for promoting health. For example, if you drink hydrogen water on a daily basis, it not only has beauty effects such as aging care, such as cell rejuvenation, but also improvement effects for various diseases. is incorporated. (Patent Document 1) A system has also been proposed in which hydrogen gas is inhaled together with mist to improve health. (Patent Document 2)

In this system, as shown in FIG. 1, a hydrogen generating agent in a hydrogen generating agent holder 12 put into a hydrogen generator 11 reacts with water to generate hydrogen (H2). That is, FIG. 1 is a diagram showing a conventional hydrogen gas suction system 10. As shown in FIG. The upper surface of the hydrogen generator 11 is closed with a cap (lid) 13 , and hydrogen gas accumulates in the upper portion of the hydrogen generator 11 . Hydrogen gas is pushed out from the gas outlet 14, passes through the hydrogen inlet tube 15, and through the hydrogen inlet 18 (located in the lid 25 attached to the top surface of the hydrogen water container 17) connected to the hydrogen inlet tube 15, Further, it enters the hydrogen intake pipe 16 in the hydrogen water container 17 connected to the hydrogen inlet 18 . The hydrogen suction pipe 16 is submerged in the water of the hydrogen water container 17, and the hydrogen gas is discharged into the water of the hydrogen water container 17 from the outlet of the hydrogen suction pipe 16 submerged in water. The hydrogen discharged into the water of the hydrogen water container 17 gathers in the upper space of the hydrogen water container 17 and exits from the outlet 26 formed in the lid 25 of the hydrogen water container 17 . A second hydrogen introduction pipe 19 is connected to an outlet 26 of a lid 25 of the hydrogen water container 17, and an outlet 20 of the second hydrogen introduction pipe 19 is a connecting portion between a mist generator 22 and an inhalation mask 23. It is connected to the hydrogen inlet 21 of (connecting pipe) 27 .

Therefore, the hydrogen that has passed through the second hydrogen introduction pipe 19 enters the connecting portion 27 from the hydrogen inlet 21 of the connecting portion 27, mixes with the mist emitted from the mist generator 22, and is inhaled by the inhalation mask 23. It exits from the mouth 24. If the inlet 24 is open, a mixed gas of fog and hydrogen gas (more precisely, the fog is not a gas, so it can be called hydrogen mixed mist (fog) or steam hydrogen). good) enters. The mist moderately moistens the mucous membranes in the mouth and throat, and hydrogen enters the body through the moist mucous membranes, improving blood conditions. In addition, the hydrogen that reaches the organs in the back of the throat and the lungs also enters the body and revitalizes the blood vessels and cells. In particular, hydrogen is likely to bond with active oxygen, so it is thought that it can render active oxygen in the body harmless and suppress the aging phenomenon. Furthermore, a cancer preventive effect can also be expected. By attaching the nose to the suction port 24 and inhaling fog containing hydrogen (mixed gas of fog and hydrogen gas) through the nose, hydrogen can be efficiently absorbed through the mucous membrane of the nose.

JP 2009-22977 JP 2017-86857

Conventional hydrogen aspiration systems are stationary and too bulky to carry around. If you inhale hydrogen during or immediately after climbing or exercising, you can maximize the effects described above and recover from fatigue. It was impossible to perform hydrogen suction immediately during or after exercise. For example, the hydrogen generating agent holder 12 to be put into the hydrogen generator 11 as shown in FIG. It is difficult to wear and carry on the body. In addition, when the conventional hydrogen generator 11 is worn on the body while the body is moving during mountain climbing or exercising, the hydrogen generating agent holder 12 moves and the water shakes, which reduces the hydrogen generation efficiency. becomes worse. Furthermore, the movement of the hydrogen generating agent holder 12 may damage the hydrogen generating agent holder 12 or damage the hydrogen generator 11 .

DISCLOSURE OF THE INVENTION The present invention provides a portable hydrogen suction system and a hydrogen suction system that can suction hydrogen even during exercise. It aims to enhance the recovery effect, and specifically has the following features.

(1) The present invention is a portable hydrogen generator used for inhaling hydrogen gas, wherein the hydrogen generator is a water bottle container that is hollow inside and can hold water, and the hydrogen generating agent and water are combined. A device for generating hydrogen by a reaction, the opening of the hydrogen generator is attached with an openable/closable lid that can be freely removed or opened, and the hydrogen generating agent has an internal cavity penetrating from the upper surface to the lower surface. The hydrogen generating agent is stored in the inner cavity of the cylindrical holder, the cylindrical holder is arranged in the internal space of the hydrogen generator, and part or all of the cylindrical holder portion in which the hydrogen generating agent is stored is the hydrogen generating agent. It is immersed in the water contained in the inner space of the generator, the outer shell of the cylindrical holder is partially or wholly spirally cut, and one of the cut portions of the cylindrical holder part or all of it is immersed in the water contained in the hydrogen generator, and water enters the inner cavity of the cylindrical holder through the cut in the outer shell of the cylindrical holder and/or the bottom opening of the cylindrical holder. , the hydrogen generating agent contained in the inner cavity of the cylindrical holder contacts with water to generate hydrogen, and the hydrogen is discharged from a hydrogen discharge port provided in the opening and closing lid of the hydrogen generator. It is a hydrogen generator for

(2) In the present invention, in addition to (1), the hydrogen generating agent is stored in a case (hydrogen generating agent storage case) permeable with water, and the upper opening of the cylindrical holder is the hydrogen A lower opening of the cylindrical holder is located at or near the bottom surface of the hydrogen generator, and an upper opening of the cylindrical holder is provided at the top of the hydrogen generator. The bottom surface of the hydrogen generator is provided with a projection for positioning the cylindrical holder. It is characterized in that the holder can be positioned, and an anti-swaying stopper is installed inside the hydrogen generator to prevent the water surface from shaking.
(3) In the present invention, in addition to (1) or (2), the material of the cylindrical holder is a polymer material or a metal material, and the open/close lid of the hydrogen generator is provided with the inside of the hydrogen generator. A check valve is attached to allow venting of gas when the internal pressure increases, and the spirally cut cylindrical holder is a spirally wound elongated plate-like sheet. Further, the spirally cut cylindrical holder is obtained by spirally cutting part or all of the outer shell of an unbroken cylindrical holder to make a cut, and the spiral of the cylindrical holder The hydrogen generating agent storage case or the hydrogen generating agent stored in the inner space of the cylindrical holder is taken out from the gap formed by the spirally extending cut of the cylindrical holder. Alternatively, the hydrogen generating agent storage case or the hydrogen generating agent is stored in the inner space of the cylindrical holder through the gap formed by the spirally extending cut of the cylindrical holder.

(4) The present invention is a portable hydrogen generator used for inhaling hydrogen gas, wherein the hydrogen generator is a water bottle container which is hollow inside and can hold water, and a hydrogen generating agent and water are mixed. It is a device that generates hydrogen by reaction, and a lid (top lid) that can be freely removed or opened and closed is attached to the upper opening of the hydrogen generator, and the hydrogen generating agent penetrates from the top surface to the bottom surface It is housed in the inner cavity of a cylindrical holder having a cavity, the cylindrical holder is arranged in the internal space of the hydrogen generator, and part or all of the cylindrical holder portion in which the hydrogen generating agent is housed is immersed in the water contained in the inner space of the hydrogen generator, and the water enters the inner cavity of the cylindrical holder through the bottom opening of the cylindrical holder and/or the hole provided in the lower outer shell of the cylindrical holder. enters, and the hydrogen generating agent contained in the inner cavity of the cylindrical holder contacts with water to generate hydrogen, the hydrogen passes through the inner cavity of the cylindrical holder, and the hydrogen provided on the upper lid of the hydrogen generator This portable hydrogen generator is characterized in that hydrogen is discharged from an outlet.

(5) In the present invention, in addition to (4), the upper cavity of the hydrogen generator is narrower than the lower cavity, and part or all of the upper part of the cylindrical holder is the upper part of the hydrogen generator. The cylindrical holder is inserted into the internal space of the hydrogen generator from the upper opening of the hydrogen generator, and the cross section of the internal cavity at the bottom of the cylindrical holder The size is larger than the cross-sectional size of the internal cavity in the upper part of the cylindrical holder, and the hydrogen generating agent is housed in the internal cavity in the lower part of the cylindrical holder. The upper cylindrical holder and the lower cylindrical holder are connected, the cross-sectional size of the inner cavity of the lower cylindrical holder is larger than the cross-sectional size of the inner cavity of the upper cylindrical holder, and the hydrogen generator has an opening at the bottom ( A bottom opening is attached to the bottom opening, and a freely removable or openable lid (bottom lid) is attached to the bottom lid, and a removable sealing member is attached to the bottom lid to connect the bottom lid and the hydrogen generator. is arranged in a contact portion with the bottom opening of the
(6) In the present invention, in addition to (4) or (5), an anti-swaying stopper is attached inside the hydrogen generator to prevent the water surface from shaking, and the cylindrical holder is made of a polymer material. Alternatively, it is made of a metal material, and the open/close cover of the hydrogen generator is provided with a check valve capable of releasing gas when the internal pressure inside the hydrogen generator increases.
(7) According to the present invention, the portable hydrogen generator described in (1) to (6) is wearable and portable, and hydrogen is generated by the hydrogen generator by attaching an inhaler to the nose or mouth. A portable hydrogen gas inhalation system characterized by inhaling hydrogen gas into the body.

The hydrogen generator of the present invention can be miniaturized and can be worn on the body and carried. With the hydrogen suction (absorption) system using the hydrogen generator of the present invention, hydrogen gas can be taken into the body not only during rest but also during walking and exercise. That is, by using the portable hydrogen suction (absorption) system of the present invention, hydrogen can be inhaled anytime and anywhere. By inhaling hydrogen from the hydrogen generator of the present invention through the mouth or nose, hydrogen can be absorbed into the body through the mouth, throat, nose, organs, lungs, or the like. As a result, lowering of blood pressure, lowering of blood sugar level, etc., and reduction of fatigue can be expected. Furthermore, the effect of rejuvenation can be expected by activating blood flow in blood vessels such as capillaries.

FIG. 1 is a diagram showing a conventional hydrogen gas suction system. FIG. 2 is a diagram showing one embodiment of the hydrogen generating agent holder of the present invention. FIG. 3 is a diagram showing a hydrogen generation container (hydrogen generator) of the present invention. FIG. 4 is a diagram showing a modified embodiment of the hydrogen generation container of the present invention shown in FIG. FIG. 5 is a diagram showing another embodiment of the cylindrical hydrogen generating agent holder of the present invention. FIG. 6 is a diagram showing another embodiment of the tubular hydrogen generating agent holder of the present invention. FIG. 7 is a diagram showing another embodiment of the cylindrical hydrogen generating agent holder of the present invention. FIG. 8 is a diagram showing another embodiment of the hydrogen generator (hydrogen generator container) of the present invention. FIG. 9 is a diagram showing a portable hydrogen gas suction (inhalation) system of the present invention.

FIG. 2 is a diagram showing one embodiment of the hydrogen generating agent holder of the present invention. As shown in FIG. 2(a), an elongated plate-like sheet 30 is rolled into a cylinder or spiral shape (or spiral or spiral shape) as shown in FIG. A hollow cylindrical holder 31 is produced. That is, the cylindrical holder 31 is an elongated tubular tube and has an inner cavity penetrating from the upper surface to the lower surface. FIG. 2(a) also shows a plan view (30p), a side view (30s), and a bottom view (30b) of the elongated plate-like sheet 30. FIG. The elongated sheet 30 is wrapped around the outside (outer wall or outer shell) of this holder and a border 39 appears. At this boundary 39, the sheet 30 may be in contact with the upper and lower sides, or may overlap with the upper and lower sides. Alternatively, the boundary may have a small gap. As shown in FIG. 2(b), the cylindrical shape has an opening 38 and is hollow inside. Arbitrary curvilinear shapes, substantially triangular shapes, substantially rectangular shapes, substantially polygonal shapes, and combinations thereof. The size of each cross section does not necessarily have to be the same. Alternatively, the outer shell of a hollow cylinder without a boundary (cut) is cut in a spiral (spiral, spiral) shape to form a cylindrical shape having a spiral boundary (cut) as shown in FIG. 2(b). A holder can be made.

The sheet material of the present invention is a material that can be rolled into a cylindrical shape, and if it is a polymer material, it can be, for example, vinyl chloride, polypropylene, polyethylene, polyethylene terephthalate, polystyrene, polyurethane, polystyrene, or rubber. , metal materials such as iron, zinc, nickel, copper, titanium, various alloys, and stainless steel. The sheet material should be resilient when coiled (or spirally) wound. In the case of a cylindrical holder that is produced by cutting the outer shell of a hollow cylinder without a boundary (cut), the materials shown above can be used. When one side of the hydrogen generating agent holder 31 wound in a cylindrical spiral shape is pressed and one side is pulled (arrow direction 32), as shown in FIG. ) extends and the gap 33 widens. As shown in FIG. 2(d), a hydrogen generating agent bag (case) 34 is inserted through this widened gap 33. As shown in FIG. After that, as shown in FIG. 2(e), when the tensile force is removed, the stretched sheet 30 (31) returns to its original spirally wound state, so that the hydrogen generating agent bag 34 is a tubular hydrogen generating agent. It is housed in a cylindrical hole inside the holder 31 (a through hole penetrating from the upper surface hole to the lower surface hole). The width of the hydrogen generating agent bag 34 is about the same as the size of the cylindrical hole of the hydrogen generating agent holder 31 (the diameter if the shape of the cylindrical hole is circular) (same as the cylindrical hole size or slightly larger or smaller than the cylindrical hole size). It is desirable to prevent the hydrogen generating agent bag 34 housed in the cylindrical hole of the hydrogen generating agent holder 31 from falling outside from the cylindrical hole or moving within the cylindrical hole. That is, even if the cylindrical hydrogen generating agent holder 31 moves, it is desirable that the stored hydrogen generating agent bag (case) 34 does not move. A hydrogen generating agent bag (case) 34 contains a hydrogen generating agent that generates hydrogen gas when reacting with water.

FIG. 3 is a diagram showing a hydrogen generation container (also referred to as a hydrogen generator) of the present invention. A hydrogen generating container (hydrogen generator) 40 of the present invention includes a columnar container 41 with a hollow interior and a lid 42 on the open bottom surface (referred to as the top surface) of the columnar container 41 . This hydrogen generation container may be considered as a water bottle (container) with a lid for containing water. One bottom surface (referred to as the lower surface) of the columnar container 41 is closed, and the other bottom surface (upper surface) is open (opened), and the hydrogen generating agent bag 34 shown in FIG. 2 is accommodated from the opened upper surface side. The hydrogen generating agent holder 31 is put in. The bottom surface of the cylindrical hydrogen generating agent holder 31 containing the hydrogen generating agent bag 34 (referred to as the bottom surface) faces downward, and the bottom surface of the cylindrical hydrogen generating agent holder 31 is placed on the bottom surface of the columnar container 41. The hydrogen generating agent holder 31 is placed upright. (FIGS. 3(a) and 3(b)) Therefore, the hydrogen generating container 40 of the present invention may be considered as a water bottle in which water is put and a hydrogen generating agent holder is put therein to generate hydrogen gas. Since it is a water bottle, the hydrogen generation container 40 of the present invention can be carried and carried. The cross-sectional size (cross-sectional size of the cavity) of the upper opening side of the hydrogen generation container (hydrogen generator) 40 may be smaller than that of the lower side, that is, it may be narrowed.

After placing the cylindrical hydrogen generating agent holder 31 in the columnar container 41 , water is poured from the top surface of the cylindrical container 41 to immerse the hydrogen generating agent bag 34 in the cylindrical hydrogen generating agent holder 31 in the water 44 . After filling the columnar container 41 with water, the open upper surface of the columnar container 41 is covered with a lid (container lid) 42 . A hydrogen discharge port (exhaust port) 43 is attached to the container lid 42 , and when the upper surface of the columnar container 41 is covered with the container lid 42 , the upper surface of the cylindrical hydrogen generating agent holder 31 (the side facing the lower surface) is arranged to enter the hydrogen outlet 43 . The hydrogen discharge port 43 attached to the container lid 42 may be a simple hole opened in the container lid 42, or may be cylindrical as shown in FIG. Thus, the container lid 42 is an opening/closing lid that covers the opening of the columnar container 41 so that it can be freely removed or opened and closed. The length of the cylindrical hydrogen generating agent holder 31 is h1, the height (inside) of the columnar container 41 is h2, and the columnar container 41 is covered with the container lid 42 to close the lid surface 45 of the container lid 42 and the columnar container. When the upper surface of the cylindrical hydrogen generating agent holder 31 is almost aligned (state shown in FIG. 3D), the upper surface (opposite side of the lower surface) of the cylindrical hydrogen generating agent holder 31 is aligned with the hydrogen discharge port 43 if h2<h1. can be arranged to enter If the cylindrical hydrogen generating agent holder 31 is made of a somewhat flexible material, it can be inserted by bending it slightly, so that the bottom surface (lower surface) of the cylindrical hydrogen generating agent holder 31 is in contact with the bottom surface of the columnar container 41 of the hydrogen generator 40. Then, the bottom (top) opening 38 of the cylindrical hydrogen generating agent holder 31 enters the hydrogen discharge port 43 attached to the container lid 42 and the position is fixed, and even if the hydrogen generating device 40 moves, the cylindrical hydrogen generating agent holder 31 will no longer move.

When the cylindrical hydrogen generating agent holder 31 is placed in the columnar container 41 and the water 44 is added, the boundary 39 (the boundary 39 has a gap) of the spiral sheet 30 of the cylindrical hydrogen generating agent holder 31 immersed in the water 44 is formed. ) or the perforated lower surface (opening) of the cylindrical hydrogen generating agent holder 31, the water 44 enters the inner cavity of the cylindrical hydrogen generating agent holder 31, and enters the hydrogen generating agent bag 34 in the cylindrical hydrogen generating agent holder 31. is submerged in water. That is, when part or all of the cylindrical holder portion containing the hydrogen generating agent is immersed in water placed in the inner space of the hydrogen generating device, a helical cut or boundary of the outer shell of the cylindrical holder is formed. (Because there is a gap), water enters the inner cavity of the cylindrical holder from the bottom (lower surface) opening of the cylindrical holder (indicated by arrow 46) and is stored in the inner cavity of the cylindrical holder. A hydrogen generating agent and water contact. Since the hydrogen generating agent bag 34 contains a hydrogen generating agent that generates hydrogen (H2) when reacting with water, hydrogen (H2) is generated. Hydrogen (H 2 ) hardly dissolves in water and is considerably lighter than air. (Indicated by arrow 47.)

Hydrogen generating agents include, for example, those including calcium oxide agents (CaO) and aluminum (Al). When these come into contact with water, aluminum (Al) becomes a hydrogen generation reaction accelerator and hydrogen (H2) is generated. (Example of reaction formula: CaO + Al + 5H2O → Ca(OH)2 + Al(OH)4 + 2H2) For example, when 3 g of water is added to about 1 g of mixed powder of calcium oxide agent (CaO) and aluminum (Al), about 300 ml of hydrogen gas is generated. do. Further, examples of hydrogen generating agents include MgH2. (Example of reaction formula: MgH2+2H2O→Mg(OH)2+2H2) As the hydrogen generating agent of the present invention, various other hydrogen generating agents can be used as long as they react with water to generate hydrogen gas.
Although some hydrogen exits from the boundary (break) 39 of the spiral sheet 30 of the cylindrical hydrogen generating agent holder 31 toward the columnar container 41, most of the hydrogen passes through the inner cavity of the cylindrical hydrogen generating agent holder 31. Since there are relatively many, the discharge efficiency of hydrogen (H2) gas is good. Since there is also a gap between the hydrogen outlet 43 and the cylindrical hydrogen generating agent holder 31 , the hydrogen accumulated in the columnar container 41 is also discharged from the hydrogen outlet 43 . Hydrogen gas outlet 43 is connected to a tube (for example, vinyl, urethane, polypropylene, polyethylene, rubber) through which hydrogen gas passes. can be inhaled into the body.

If the cylindrical hydrogen generating agent holder 31 is arranged in the center of the columnar container 41 and the hydrogen discharge port 43 is attached to the center of the container lid 42, the columnar container 41 can be covered with the container lid (opening/closing lid) 42. The top side opening of the cylindrical hydrogen generating agent holder 31 can be arranged so as to naturally enter the hydrogen discharge port 43 when the holder 31 is closed. (It is also necessary to make the outer size of the cylindrical hydrogen generating agent holder 31 smaller than the inner size of the hydrogen discharge port 43.) If arranged so as to enter the outlet 43, even if the hydrogen generating container 40 shakes to some extent, the upper surface side opening of the cylindrical hydrogen generating agent holder 31 will not come off from the hydrogen discharge port 43, and hydrogen will flow into the cylindrical hydrogen generating agent holder. 31 into the hydrogen outlet 43 and the hydrogen is efficiently discharged from the hydrogen outlet 43 . Even if the cylindrical hydrogen generating agent holder 31 is shorter than the columnar container 41 (h1<h2) or the upper opening of the cylindrical hydrogen generating agent holder 31 is out of the hydrogen discharge port 43, the hydrogen gas will not flow into the hydrogen generating container. Since the hydrogen is accumulated in the upper part of 40 and discharged from the hydrogen discharge port 43, there is no particular problem in terms of hydrogen discharge. If the upper part of the columnar container 41 is narrowed, the upper part of the cylindrical hydrogen generating agent holder 31 is arranged above the narrowed columnar container 41, so that the cylindrical hydrogen generating agent holder 31 is less likely to fall down. Become.

FIG. 4 is a diagram showing a modified embodiment of the hydrogen generation container of the present invention shown in FIG. In the case of the hydrogen generating container 40 shown in FIG. 3, it was not clear where the cylindrical hydrogen generating agent holder 31 should be placed on the lower surface of the columnar container 41, and it was supposed to be placed near the center. Even in this case, the lower surface of the columnar container 41 is not so wide, so that the position does not deviate greatly. However, as shown in FIG. 51 is arranged, and if the cylindrical hydrogen generating agent holder 31 is arranged so that the projection 51 is inserted into the opening of the lower surface of the cylindrical hydrogen generating agent holder 31, the positioning of the cylindrical hydrogen generating agent holder 31 can be performed. I can do it for sure. If the cylindrical hydrogen generating agent holder 31 can be positioned, the upper surface side of the cylindrical hydrogen generating agent holder 31 will surely enter the hydrogen outlet 43 . If the protrusion 51 hits the hydrogen generating agent bag 34 and damages it (for example, it forms a scratch or a hole), the tip of the protrusion is rounded or flattened so that the hydrogen generating agent bag 34 is not damaged. It should be a shape.

Furthermore, if the support guide 53 for the cylindrical hydrogen generating agent holder 31 is arranged inside the columnar container 41, the positioning of the cylindrical hydrogen generating agent holder 31 can be further ensured. For example, if a support guide 53 for the cylindrical hydrogen generating agent holder 31 having a guide hole as shown in FIG. ), the cylindrical hydrogen generating agent holder 31 can be reliably positioned. (FIGS. 4(a) and 4(b)) If the size of this guide hole is approximately the same as or slightly larger than the size of the cylindrical hydrogen generating agent holder 31, the cylindrical hydrogen generating agent holder 31 can be fixed or semi-fixed. can also be Alternatively, the size of the guide hole may be somewhat larger than the size of the cylindrical hydrogen generating agent holder 31 , and may be of a size that determines the position of the cylindrical hydrogen generating agent holder 31 in the columnar container 41 to some extent. Also, as shown in FIGS. 4(a) and 4(b), a handle 52 is attached to the outer wall (outer case) of the columnar container 41, and a neck string 54 is attached to the handle 52, and the neck string is attached to the neck of the body. 54, the hydrogen generation container 40 can be carried. If the hydrogen generator 40 can be worn on the body and carried around, hydrogen can be inhaled anytime and anywhere.

FIG. 5 is a diagram showing another embodiment of the tubular hydrogen generating agent holder of the present invention. The tubular hydrogen generating agent holder 61 shown in FIG. 5 consists of a spirally wound portion 62 and a hollow tubular portion 63 without a spiral portion. (Fig. 5(b)) The length h3 of the spirally wound portion (the length from one lower surface to the spirally upper portion) is long enough to accommodate the generator bag, as will be described later. This part is also the part that is immersed in water.

A hollow tubular holder 61 having such a partially spiral portion 62 spirals the outer wall (outer shell) of a columnar tubular tube as shown in FIG. The cut line 39 may be formed by cutting in a shape (spiral shape) up to the length h3. Alternatively, it can be produced by connecting a spiral tube of length h3 to an unbroken columnar tubular tube. Alternatively, for the spiral tube shown in FIG. 2, a method of completely closing the boundary (cut) 39 of the portion other than the length h3 (for example, a method of applying an adhesive to the boundary 39 to close the boundary 39, or , a method of sealing the boundary 39 by heating and fusing the boundary 39). The hollow tubular holder 31 (shown in FIGS. 2 to 4), which is entirely spiral-shaped, also has a spiral-shaped outer wall (outer shell) of a columnar tubular tube as shown in FIG. 5(a). It can be cut in a (spiral) shape to form cuts. The material of the tubular holder is, for example, polymeric material or metal. Polymer materials include vinyl chloride, polypropylene, polyethylene, polyethylene terephthalate, polystyrene, polyurethane, polystyrene, and rubber. For example, metal materials include iron, zinc, nickel, copper, titanium, various alloys, and stainless steel. be. Since heat is generated when hydrogen is generated, a heat-resistant polymeric material can also be used.

When the end of the spiral portion 62 of the hollow tubular holder 61 having this partially spiral portion 62 is pulled (pulling force 65), a spiral shape is formed as shown in FIG. 5(c). Since the portion 62 is extended to form a gap 64, the hydrogen generating agent bag (case) 34 is inserted through the gap 64 (Fig. 5(d)) to eliminate the tensile force 65, and the spiral portion 62 of the cylindrical holder is opened. The hydrogen generating agent bag 34 is accommodated in the hollow portion of (Fig. 5(d)). Thus, even with the cylindrical hydrogen generating agent holder 61 partially formed with the spiral portion 62, the hydrogen generating agent bag 34 can be easily accommodated inside (hollow portion) of the cylindrical hydrogen generating agent holder 61.

FIG. 5 shows a state in which a hollow cylindrical holder 61 partially having a spiral portion 62 is placed in a columnar container 41, water 44 is poured into the columnar container 41, and the columnar container 41 is covered with a container lid 42. (f). When the spiral portion 62 of the tubular hydrogen generating agent holder 61 is immersed in at least the water 44 , the water flows through at least the spiral portion of the tubular holder 61 from the boundary (break) 39 of the spiral portion 62 and the lower surface of the tubular holder 61 . 62 is entered, the hydrogen generating agent bag 34 is immersed in water, and the hydrogen generating agent in the hydrogen generating agent bag 34 reacts with water to generate hydrogen. That is, the hydrogen generating agent bag (case) that stores (puts) the hydrogen generating agent is made of a material that easily permeates water (such as cloth, mesh fiber, mesh plastic, metal mesh, paper). , permeable plastic). The generated hydrogen passes through the hollow portion of the tubular holder 61 and exits from the hydrogen outlet 43 . (Arrow 47 ) At this time, since there is no gap 69 in the cylindrical holder 61 other than the spiral portion 62 , hydrogen does not enter the columnar container 41 very much. , and the hydrogen is efficiently discharged from the hydrogen discharge port 43 .

In this embodiment, a check valve 48 is attached to the lid surface 45 of the container lid 42 so that hydrogen does not come out too much from the hydrogen outlet 43 (for example, the hydrogen outlet 43 or the hollow portion of the cylindrical holder 61 is clogging), and when hydrogen accumulates inside the columnar container 41 and the pressure increases, the gas can be vented. The check valve 48 may be attached to a portion (for example, a side surface) other than the lid surface 45 of the container lid 42, or may be attached to the columnar container. Also, the check valve 48 can of course be installed in other embodiments.

FIG. 6 is a diagram showing another embodiment of the tubular hydrogen generating agent holder of the present invention. The tubular hydrogen generating agent holder 81 is made of a flexible material, and its outer wall (outer shell) is formed in a spiral shape. The portion is stretched to form a gap through which the stored hydrogen generating agent bag 34 can be easily taken out and the hydrogen generating agent bag 34 can be easily inserted. Flexible materials are for example vinyl (eg vinyl chloride), polystyrene, polypropylene. Polyethylene, ABS resin, polyurethane, soft plastics such as tubes, and rubbers are used, but metal materials may also be used. A flexible heat-resistant polymeric material can also be used. The opening on the bottom side of the cylindrical hydrogen generating agent holder may be closed. Water comes into contact with the generator.

Such a flexible tubular hydrogen generating agent holder 81 can be bent and used within the columnar container as shown in FIG. The cylindrical hydrogen generating agent holder 81 has a penetrating cavity, and the generated hydrogen can pass through the penetrating cavity and be discharged to the outside from the hydrogen outlet 43 (arrow 47). For example, even if the columnar container is small, a relatively long flexible cylindrical hydrogen generating agent holder 81 can be used. FIG. 6 shows a cylindrical hydrogen generating agent holder that is entirely spiral, but it is naturally applicable to a partially spiral cylindrical hydrogen generating agent holder as shown in FIG. In other words, not only the spiral portion but also the flexible material may be used.

In this embodiment, a water surface stopper 82 is attached so that the water contained in the columnar container 41 does not shake. This water surface stopper (water surface anti-vibration material) 82 is made by making a hole in a fiber sheet such as a plastic plate, a metal plate, paper, or cloth so that the cylindrical hydrogen generating agent holder 81 can pass through the hole. The agent holder 81 may be placed so as to cover the surface of the water. If the outside size of the water surface stopper 82 is formed to be approximately the same as the inside size of the columnar container 41 , it can be placed at any desired location in the columnar container 41 . A flexible material such as rubber or sponge is attached around the water surface stopper 82 (in contact with the inner surface of the columnar container 41) and around the hole through which the cylindrical hydrogen generating agent holder 81 passes (in contact with the outer surface of the cylindrical hydrogen generating agent holder 81). With this arrangement, the amount of water flowing out to the top of the columnar container is reduced. Alternatively, the entire surface stopper 82 may be made of cotton, cloth, sponge, or the like. Since the hydrogen generating container (40, 80) of the present invention is worn and carried on the body, the hydrogen generating container moves, and the water in the columnar container also moves. There are times when water does not come into contact with the hydrogen generating agent bag, and the hydrogen generation efficiency drops. However, by placing the water surface stopper on, the water hardly shakes, and as a result, the hydrogen generating agent bag is always in contact with the water, and as long as the hydrogen generating agent exists in the hydrogen generating agent bag, hydrogen is always efficient. occurs in

FIG. 7 is a diagram showing another embodiment of the tubular hydrogen generating agent holder of the present invention. The diagram of FIG. 7 shows an embodiment using an improved hydrogen generating agent holder in the conventional hydrogen gas suction system 10 shown in FIG. In FIG. 7, instead of the hydrogen generating agent holder 12 shown in FIG. 1, a cylindrical hydrogen generating agent holder (cylindrical tube) 85 of the present invention is used. The hydrogen generating agent holder 85 is a short cylindrical hydrogen generating agent holder as shown in FIGS. It is rolled. Alternatively, it is a tube in which a slit 86 is formed by spirally cutting the outer shell of a hollow cylindrical tube. In FIG. 7, the hydrogen generating agent holder 85 is enlarged and shown downward through the outer shell of the tube.

A hydrogen generating agent bag 87 is accommodated in the cavity of the cylindrical tube. Since the cylindrical tube 85 has spiral cuts 87, when one end or both ends are pulled as shown in FIG. The agent bag 87 can be put therein, and when the tensile force is removed, it becomes a cylindrical tube 85 , and the hydrogen generating agent bag 87 is accommodated in the hollow portion of the cylindrical tube 85 . The hydrogen generating agent holder 85 is large enough to accommodate the hydrogen generating agent bag in its inner cavity. For example, if the size of the hydrogen generating agent bag 87 is 10 mm in width, 20 mm in length and 5 mm in thickness, the internal cavity size of the cylindrical tube 85 may be about 10 mm in inner diameter and about 20 to 30 mm in length. The cylindrical tube 85 may have a columnar shape or a curved columnar shape. If the hydrogen generating agent bag 87 is too small compared to the internal cavity size of the cylindrical tube 85, the hydrogen generating agent bag 87 stored in the internal cavity of the cylindrical tube 85 may slip out of the internal cavity of the cylindrical tube 85. Therefore, a size that can be accommodated in the inner cavity of the tubular tube 85 and does not come off from the inner cavity of the tubular tube 85 is preferable. That is, the size of the tubular tube 85 may be selected according to the size of the hydrogen generating agent bag 87 .

When this small cylindrical tube 85 is put into the hydrogen generator 11 containing water, hydrogen gas comes out from both ends of the cylindrical tube 85 and the slit 86 and accumulates in the upper part of the hydrogen generator 11, and the gas outlet 14 The hydrogen gas can be discharged from the mouth and the hydrogen gas can be sucked through the mouth or nose in the same manner as in the case shown in FIG. Moreover, if hydrogen gas is passed through the hydrogen water container 17, hydrogen water can also be drunk. If the hydrogen generator 11 is made small, it can be portable. Even if the water and the hydrogen generating agent holder 85 move while carrying, the hydrogen generating agent holder 85 is small, so there is little possibility that the water in the hydrogen generating agent holder 85 will run out. be done. Thus, by using the hydrogen generating agent holder, which is a cylindrical tube with spiral cuts, the hydrogen generating agent bag can be easily replaced, so that it can be carried easily and hydrogen can be easily sucked. In addition, if the mist (fog) generator 22 is also carried, the mixed gas of the mist and hydrogen (called hydrogen mixed mist) can be inhaled through the mouth and/or nose using the inhalation mask 23 anytime and anywhere. .

FIG. 8 is a diagram showing another embodiment of the hydrogen generator of the present invention.
In FIG. 8(a), the cylindrical hydrogen generating agent holder 100 for storing the hydrogen generating agent of the present invention has a columnar cylindrical shape with a hollow inside, and a columnar shape with a small cavity size (cross-sectional size of the cavity). It has a shape in which a tubular holder (upper tubular holder) 102 and a columnar tubular holder (lower tubular holder) 101 having a large cavity size (cross-sectional size of the cavity) are connected. The upper cylindrical holder 102 has an open upper surface 104 and an open lower surface, and has a cavity penetrating from the upper opening 104 to the lower surface. The lower cylindrical holder 101 has an open bottom surface 103 and an open top surface, and has a cavity penetrating from the top opening 104 to the bottom opening 103 . (The open state is indicated by diagonal lines in FIG. 8.) For example, when the cavity of the cylindrical holder is circular, the cavity (cross-sectional) diameter R2 of the upper cylindrical holder 102 is equal to the cavity (cross-sectional) diameter R2 of the lower cylindrical holder 101 ( Cross section) smaller than diameter R1. The lower surface of the upper tubular holder 102 is connected to the upper surface of the lower tubular holder 101 to form the tubular hydrogen generating agent holder 100 . The lower surface of the cylindrical hydrogen generating agent holder 100 (same as the lower surface 103 of the lower cylindrical holder 101) is open, and the upper surface of the cylindrical hydrogen generating agent holder 100 (same as the upper surface 104 of the upper cylindrical holder 102) is open. Therefore, the cylindrical hydrogen generating agent holder 100 has a cavity penetrating from the upper surface to the lower surface. The connecting portion 109 between the lower tubular holder 101 and the upper tubular holder 102 is closed.

When the lower cylindrical holder 101 and the upper cylindrical holder 102 are cylindrical, and the outer diameter (outer shell diameter) R3 of the upper cylindrical holder 102 and the cavity diameter R1 of the lower cylindrical holder 101 are substantially equal, the lower cylindrical holder It can be manufactured by fitting the upper tubular holder 102 into the cavity of the tubular holder 101 . If the cylindrical holder is made of plastic, it can be fixed by thermocompression bonding or adhesive. The cylindrical holder may have a triangular, quadrangular, polygonal, elliptical, or arbitrary curved cross section, and the upper cylindrical holder 101 and the lower cylindrical holder 102 may have different shapes. Moreover, the shape of the internal cavity of the cylindrical holder may be triangular, square, polygonal, elliptical, or any curved shape in cross section. can be The material of the holder is preferably a polymer material such as plastic or a metal material. Since the hydrogen generating agent is stored in the lower holder, when the hydrogen generating agent reacts with water, the temperature rises to about 100°C to 130°C. Heat resistant polymeric materials such as plastics are preferred. For example, thermosetting resin {e.g. UF (urea resin), PF (phenol resin), MF (melamine resin), SI (silicon resin), EP (epoxy resin)}, super engineering plastic material {e.g. PES (polyether sulfone), PEI (polyetherimide), PAI (polyamideimide), PEEK (polyetheretherketone), PTFE (polytetrafluoroethylene), PPS (polyphenylene sulfide)}, engineering plastic materials {for example, PC (polycarbonate) Bonate), PA (polyamide), PET (polyethylene terephthalate), PBT (polybutylene terephthalate), POM (polyacetal), PVDF (polyvinylidene fluoride), PP (polypropylene), PS (polysulfone),} can be used. The materials of the upper tubular holder 101 and the lower tubular holder 102 may be different. Similar materials can be used for the cylindrical holders shown in FIGS.

As shown in FIG. 8(b), a hydrogen generating agent bag (case) 105 is housed in the hollow portion of the lower cylindrical holder 102 of the cylindrical hydrogen generating agent holder 100. As shown in FIG. The size of the hydrogen generating agent bag (case) 105 is set so that it can be inserted into the hollow portion of the lower cylindrical holder 102 . For example, if the size (e.g., width) of the hydrogen generating agent bag (case) 105 is made equal to, slightly smaller, or slightly larger than the size (e.g., diameter) of the hollow portion of the lower cylindrical holder 102, the hydrogen generating agent bag The (case) 105 can be put into the cavity of the lower cylindrical holder 102 from the opening 103 of the lower cylindrical holder 102 and stored in the cavity of the lower cylindrical holder 102 . If the hydrogen generating agent bag (case) 105 is flexible even if it is slightly larger, the hydrogen generating agent bag (case) 105 can be deformed and put into the cavity of the lower cylindrical holder 102 . In addition, if it is made slightly larger, the hydrogen generating agent bag (case) 105 will not move within the cavity of the lower cylindrical holder 102 . In the case of a cylindrical hydrogen generating agent holder 100 consisting of two stages of cylindrical holders as shown in FIG. If it is made large, the hydrogen generating agent bag (case) 105 will not move toward the upper portion of the cylindrical hydrogen generating agent holder 100 , that is, toward the upper cylindrical holder 101 .

8(c) to (e) are diagrams showing a hydrogen generator (container) 140 of the present invention. The hydrogen generator (container) 140 includes a hydrogen generator (container) main body 110, a hydrogen generator (container) ) It consists of an upper lid 120, a hydrogen generator (container) lower (bottom) lid 130, and a cylindrical hydrogen generating agent holder 100 containing a hydrogen generating agent bag (case) 105. The hydrogen generator (container) main body 110 is a columnar container with a hollow interior. ) penetrates. In addition, since the outer wall (outer shell) shape of the hydrogen generator (container) main body 110 is a shape that narrows on the upper side, and the thickness of the outer wall (outer shell) is almost the same in the hydrogen generator (container) main body 110, The cavity also corresponds to the narrowing, and the cavity on the upper side of the hydrogen generator (container) main body 110 is narrower than the cavity on the lower side. That is, a columnar body 111 having a cavity inside (in the case of a cylindrical body, the diameter of the cavity cross section {cavity size (cross-sectional size)} is R5) and the inside being hollow (in the case of a cylinder, the diameter of the cavity cross section {cavity A columnar body 113 having a size (cross-sectional size)} is R6) is integrated at a connecting portion 112, where R6<R5. Incidentally, in these columnar bodies, R5 and R6 may not be constant in the depth direction. The columnar body 111 may be called the body portion of the hydrogen generator (container) main body 110, the columnar body 113 may be called the neck portion or mouth portion of the hydrogen generator (container) main body 110, and the connection portion 112 may be called the shoulder portion. The material of the hydrogen generator (container) main body 110 is, for example, a polymer material such as plastic or a metal material. As polymeric materials, for example, the materials mentioned above can be used. A transparent body is desirable so that the inside of the hydrogen generator (container) main body 110 can be seen.

The hydrogen generator (container) upper lid 120 is a lid that fits over the neck portion 113 of the hydrogen generator (container) main body 110 to close the opening (opening surface) 115 . A hydrogen generator (container) upper lid 120 is composed of a columnar portion (side surface) 121 and a hydrogen discharge (exhaust) port 122 attached to a ceiling (upper) surface 125 of the columnar portion (side surface) 121 . Since the lower surface 123 of the columnar portion (side surface) 121 is open, the columnar portion (side surface) 121 can be fitted into the neck portion 113 of the hydrogen generator (container) main body 110 . For example, the inner size (diameter if the cross section is circular) of the columnar portion (side surface) 121 is slightly larger than the outer size ((diameter if the cross section is circular) of the neck portion 113 of the hydrogen generator (container) body 110. If a spiral screw thread/thread groove that fits each other is prepared on both sides, the hydrogen generator (container) upper lid 120 can be fitted to the neck portion 113 of the hydrogen generator (container) main body 110 and turned. If you optimize their size, you can maintain airtightness.If you put a sealing material in the contact area, you can get perfect airtightness, and hydrogen gas and The hydrogen discharge (exhaust) port 122 is also a hollow columnar body, and the upper surface 124 of the hydrogen discharge (exhaust) port 122 is open. It penetrates from the opening 124 of the port 122 to the opening 123 on the lower surface of the columnar portion (side surface) 121. The connecting portion between the columnar portion (side surface) 121 and the hydrogen discharge (exhaust) port 122 prevents leakage of hydrogen and water. The material of the columnar portion (side surface) 121 and the hydrogen discharge (exhaust) port 122 is, for example, a polymer material such as plastic or a metal material. When the columnar portion (side surface) 121 and the hydrogen discharge (exhaust) port 122 are made of the same material, airtightness can be ensured by manufacturing them as a single unit. If the (exhaust) port 122 is made of different materials, they can be attached by adhesive or fusion, and can be removed if the threads/grooves are made to fit together. , Sealing material (for example, O-ring) can also be used to ensure complete airtightness.Sealing materials include, for example, nitrile rubber, fluororubber, silicon rubber, ethylene propylene rubber, chloroprene rubber, urethane rubber, hydrogenated Examples thereof include nitrile rubber, perfluoroelastomer, and fluorosilicone rubber, and can be appropriately selected in consideration of heat resistance. It is placed on the upper edge of the neck portion 113 of the container) main body 110 and the contact surface, or the outer wall (surrounding) of the columnar portion (side surface) 121 and/or the inner wall (surrounding) of the neck portion 113 of the hydrogen generator (container) main body 110 . ), the outer wall (wall) of the columnar portion (side surface) 121 and the neck of the hydrogen generator (container) main body 110 It can be arranged at a contact portion with the inner wall (frame) of the portion 113 .

The hydrogen generator (container) lower (bottom) lid 130 has an open upper surface 133 and a closed lower (bottom) surface 132, and has a cylindrical shape with a hollow interior. The lower opening 114 of the hydrogen generator (container) body 110 is covered with the lower lid 130 of the hydrogen generator (container) to cover the lower opening 114 . For example, the size of the cavity inside the hydrogen generator (container) lower lid 130 is set to be the same or slightly larger than the outer (outer wall (outer shell)) size of the lower side of the hydrogen generator (container) main body 110, and the hydrogen generator is (Container) The lower lid 130 is fitted over the lower outer wall (outer wall (outer shell)) of the hydrogen generator (container) main body 110. The inside of the side surface 131 of the hydrogen generator (container) lower lid 130 and the ) If threads and grooves are formed on the outer surface of the lower side of the main body 110 to fit each other, the hydrogen generator (container) lower lid 130 is rotated, and hydrogen is generated by the hydrogen generator (container) lower lid 130 . The bottom opening 114 of the generator (container) main body 110 can be covered with a sealing material (for example, a , O-ring) 134 can be arranged to ensure airtightness.The sealing material 134 arranged on the lower surface 132 of the hydrogen generator (container) lower lid 130 is provided at the bottom (lower surface opening) of the hydrogen generator (container) main body 110 114) and the lower surface 132 of the hydrogen generator (container) lower lid 130. The sealing material can be placed at the bottom of the hydrogen generator (container) main body 110 (edge of the lower surface opening 114). The sealing material can also be placed on the inner surface of the side surface 131 of the hydrogen generator (container) lower lid 130 and/or the lower outer surface of the hydrogen generator (container) main body 110 .

After closing the lower surface opening 114 of the hydrogen generator (container) main body 110 with the hydrogen generator (container) lower lid 130, the cylindrical hydrogen generating agent holder 100 containing the hydrogen generating agent bag (case) 105 is placed into the hydrogen generator. The tubular holder (lower tubular holder) 101 is inserted into the cavity (space) of the hydrogen generator (container) main body 110 from the top opening 115 of the (container) main body 110 . The lower surface opening 103 of the cylindrical hydrogen generating agent holder 100 is placed in contact with the lower (bottom) surface 132 of the hydrogen generator (container) lower lid 130 .
Assuming that the length (height) of the lower cylindrical holder 101 is h5 and the length (height) of the upper cylindrical holder 102 is h4, the length (height) h6 of the cylindrical hydrogen generating agent holder is equal to h6 =h4+h5. The height (length) of the body portion of the hydrogen generator (container) main body 110 is h7, the height (length) of the shoulder portion is h8, and the height of the neck portion 113 of the hydrogen generator (container) main body 110 is h9. Then, the height h10 of the hydrogen generator (container) body 110 is h10=h7+h8+h9. The lower surface opening 114 of the hydrogen generator (container) main body 110 substantially coincides with the lower (bottom) surface 132 of the hydrogen generator (container) lower (bottom) lid 130, so that the hydrogen generator (container) lower (bottom) The height from the lower (bottom) surface 132 of the hydrogen generator (container) lower (bottom) lid 130 of the hydrogen generator (container) 140 covered with the lid 130 to the upper surface opening 115 of the hydrogen generator (container) main body 110 The height is almost the same as h10 or slightly larger. (When the lower surface opening 114 of the hydrogen generator (container) main body 110 does not match the lower (bottom) surface 132 of the hydrogen generator (container) lower (bottom) lid 130, it becomes larger than h10.) Since the top opening 115 of the generator (container) main body 110 substantially coincides with the ceiling (upper) surface 125 of the hydrogen generator (container) upper lid 120, the hydrogen generator (container) lid 120 can be used to cover the hydrogen generator (container). The height from the lower (bottom) surface 132 of the hydrogen generator (container) lower (bottom) lid 130 of the generator (container) 140 to the ceiling (top) surface 125 of the hydrogen generator (container) upper lid 120 is h10. about the same or slightly larger. (When the top opening 115 of the hydrogen generator (container) main body 110 does not substantially coincide with the ceiling (upper) surface 125 of the hydrogen generator (container) upper lid 120, it becomes larger than h10.)

8(d) and (e) show that a cylindrical hydrogen generating agent holder 100 containing a hydrogen generating agent bag (case) 105 is provided with a hydrogen generator (container) lower (bottom) lid 130 and a hydrogen generator (container) upper lid. FIG. 8D is a diagram showing the state of the hydrogen generator (container) 140 with the lid 120, and FIG. FIG. 8(e) shows a case where the lower (bottom) lid 130 and the upper lid 120 are transparent or skeleton (transparent) (filled with water). As can be seen from these figures, the cylindrical hydrogen generating agent holder 100 is contained in the hydrogen generator (container) 140, so the height (length) h6 of the cylindrical hydrogen generating agent holder 100 is smaller than h10. . Since the cavity (cross section) size (R6) of the neck portion 113 of the hydrogen generator (container) 140 is smaller than the cavity (cross section) size (R5) of the body portion 111 of the hydrogen generator (container) 140, cylindrical hydrogen generation is possible. If part (or all) of the upper portion of the agent holder 100 (upper cylindrical holder 102) is accommodated in the cavity of the neck portion 113 of the hydrogen generator (container) 140, the hydrogen generator (container) 140 will not move. However, since the cylindrical hydrogen generating agent holder 100 only moves within the cavity of the neck portion 113 , the cylindrical hydrogen generating agent holder 100 does not move much within the hydrogen generator (container) 140 . That is, since the cylindrical hydrogen generating agent holder 100 hardly contacts the inner surface of the outer wall (outer shell) of the hydrogen generator (container) 140 (particularly, the body 111), the hydrogen generator (container) 140 is not damaged. Therefore, it is desirable that h6>h8+h7. Examples of h4-h10 and R1, R2, R5, R6 are h4 = 4-15 cm, h5 = 2-10 cm, h6 = 6-25 cm, h7 + h8 = 5-20 cm, h9 = 1-5 cm, h10 = 6 ~25 cm. R1=1.5-4 cm, R2=1-3 cm, R5=4-10 cm, R6=2-5 cm. Of course, other sizes are also available.

A hole (water hole) 107 through which water passes is opened in the outer wall (outer shell) on the lower side of the lower cylindrical holder 101, and as shown in FIG. When 135 is inserted, water enters the tubular hydrogen generating agent holder 100 through the water passage hole 107 . Of course, water also enters from the lower surface opening 103 of the cylindrical hydrogen generating agent holder 100, but if the lower surface opening 103 is in complete contact with the lower (bottom) surface 132 of the lower (bottom) lid 130, the water will Since it is difficult to enter, in that case, water mainly enters the cavity of the cylindrical hydrogen generating agent holder 100 through the water passage hole 107 . The amount of water to be put into the hydrogen generator (container) 140 is preferably such that at least the hydrogen generating agent bag 105 is completely submerged in water. For example, the upper limit position 136 of water is above the connecting portion 109 between the lower tubular holder 101 and the upper tubular holder 102 . That is, the portion of the lower tubular holder 101 in which the hydrogen generating agent bag 105 is accommodated is completely submerged in water. Moreover, it is preferable that the amount of water is larger than the amount at which the hydrogen generating agent completely reacts and becomes hydrogen. The size of the hydrogen generating agent bag is made equal to or less than the height (length) h5 of the lower cylindrical holder so that the hydrogen generating agent bag can be completely accommodated in the lower cylindrical holder. Conversely, the size of the hydrogen generating agent bag may be selected so that the height (length) of the lower cylindrical holder is h5 or less.

As shown in FIG. 8(e), the water in the cylindrical hydrogen generating agent holder 100 reacts with the hydrogen generating agent to generate hydrogen (H2) gas, and the generated hydrogen is stored in the cylindrical hydrogen generating agent holder 100. The upper wall (outer shell ), hydrogen also flows out from the hole (hydrogen vent) 108 in the ) and accumulates in the cavity of the neck portion 113 of the hydrogen generator (container) 140, and the hydrogen is further discharged (exhaust) port of the upper lid 120. Hydrogen gas comes out from 124. (Indicated by a dashed arrow 137.) In the hydrogen generation system of the present invention, if a hydrogen introduction tube is attached to the hydrogen discharge (exhaust) port 124 and the hydrogen introduction tube is led to a hydrogen inhalation mask or a nasal cannula, hydrogen can be delivered to the body. Can inhale and absorb gas. If the hydrogen generator (container) 140 is provided with an ear 116, for example, by attaching a string to the ear and putting it around the neck, the hydrogen generator (container) 140 can be carried while walking or running. , hydrogen can be inhaled and absorbed by the body.

In addition, the lower surface 114 of the hydrogen generation container main body 111 may be closed without being opened. In this case, the bottom (lower) lid is not required and the number of parts is reduced. When the lower surface 114 of the hydrogen generating container main body 111 is open and a bottom (lower) lid 130 is required, the cylindrical holder 100 can be inserted from the lower surface opening 114 of the hydrogen generating container main body 111. Since it can be inserted from the lower surface opening 114 of 111, the degree of freedom is increased. The hydrogen generator (container), which is the hydrogen generation system of the present invention shown in FIG. shape) is also acceptable. Two stages of cylindrical hydrogen generating agent holders with different cavity sizes are put into this water bottle-shaped hydrogen generating device (container), and the hydrogen generating agent bag (case) stored in the lower cylindrical hydrogen generating agent holder is entered. Hydrogen is generated by the reaction between the hydrogen generating agent and water placed in the hydrogen generator (container). The hydrogen ascends through the cavity of the cylindrical hydrogen generating agent holder, gathers above the hydrogen generator (container), and exits from the hydrogen outlet attached to the top lid of the hydrogen generator (container). In addition, since the upper part of the cylindrical hydrogen generating agent holder is arranged in the narrow mouth (neck part) of the hydrogen generator (container), the upper part of the cylindrical hydrogen generating agent holder does not move much, but the cylindrical hydrogen generating agent Since it is easy to move under the hydrogen generator (container) where the lower part of the holder is placed (especially at the bottom), there is a risk of contact with the outer wall (outer shell) of the hydrogen generator (container). ) may cause damage. Therefore, by arranging a soft material on the bottom of the hydrogen generator (container) (or on the bottom of the lower lid when there is a lower lid), the damage can be mitigated. When the sealing material 134 is arranged, it can also be used as the sealing material 134 .

FIG. 9 is a diagram showing a portable hydrogen gas suction (inhalation) system of the present invention. The portable hydrogen gas suction system shown in FIG. It includes a hydrogen introduction tube 93 that introduces hydrogen (gas) to the vessel). Hydrogen generator 91 is the hydrogen generator of the present invention as shown in FIGS. A portable neck strap 94 for hanging the hydrogen generator 91 around the neck is attached so that the hydrogen generator 91 can be carried around the neck. When necessary, the hydrogen generating agent holder of the present invention containing a hydrogen generating agent bag as shown in FIGS. 2 to 8 is set in the hydrogen generator 91, and water is added. You can inhale hydrogen gas by placing a hydrogen inhalation mask (hydrogen inhaler) on your nose and mouth. The hydrogen generator 91 is of a portable size as shown in FIGS. 1-8. For example, it has a cylindrical shape with an inner diameter of 2 cm to 10 cm and a length of 10 cm to 30 cm. If the internal volume of the hydrogen generator (hydrogen generator) 91 is, for example, 200 cc to 1000 cc, and 50 cc to 800 cc of water is added, and 3 to 10 g of the hydrogen generating agent is used, approximately 500 cc to 3000 cc of hydrogen is generated. Hydrogen introduction tube 93 is, for example, a flexible plastic tube, a fluorine tube, a rubber tube, or a metal tube. Although water may be put in another water bottle or the like and carried, water may be put in the hydrogen generator 91 . Hydrogen inhalation masks (hydrogen inhalers) include all devices (such as jigs) for inhaling hydrogen through the nose and mouth. For example, it includes a mask that fits over the nose and mouth and a nasal cannula that inhales through the nose, as shown in the figure.

Since the hydrogen generating agent bag is small and light, it can be carried separately from water. When it is necessary to inhale hydrogen gas, it can be stored in the hydrogen generating agent holder (cylindrical tube (holder)) of the present invention and easily set in the hydrogen generator 91 . Therefore, hydrogen gas can be inhaled (inhaled) using the portable hydrogen gas inhalation (inhalation) system of the present invention anytime, anywhere, even while walking or exercising. The top side opening of the hydrogen generator (hydrogen generator) 91 may be narrower than other portions, narrow in the center for portability, or any appropriate shape. Alternatively, a deformable hydrogen generator (hydrogen generator) made of a flexible material may be used. The material of the hydrogen generator is polymer material or metal material. Polymer materials include vinyl chloride, polypropylene, polyethylene, polyethylene terephthalate, polystyrene, polyurethane, polystyrene, and rubber. For example, metal materials include iron, zinc, nickel, copper, titanium, various alloys, and stainless steel. be. Also, for example, the materials listed so far (including heat-resistant polymeric materials) can also be used.

The portable hydrogen gas suction (inhalation) system of the present invention can also be applied to the one described in Patent Document 2. That is, the content described in Patent Document 2 can also be cited and applied to the present invention. For example, goggles, hair caps, boxes, skirts, or even saunas. When a hair cap is used, the hydrogen gas has a small molecular size, so the pressurized hydrogen gas penetrates into the head through the softened scalp. As a result, the blood flow improves, the condition of the head is relaxed, there is an effect against damaged hair and prevention of hair loss and cuts, and hair growth and beauty effects are also expected. By providing a mechanism for heating the hydrogen-mixed mist (steam hydrogen), the head can be appropriately warmed, and the above effect can be enhanced. It also relaxes the head, improves the rotation of the head, and improves the memory. Furthermore, it is also a countermeasure against dementia and can reduce social security expenses such as medical expenses.

Also, by supplying hydrogen gas to the eyes through goggles or the like, eye fatigue can be easily recovered. Mixing with mist increases the effect. The legs 133 in contact with the hydrogen-mixed mist are relieved of their fatigue and feel moisturized. In addition, the blood flow in the legs and feet improves, and it is possible to improve coldness and hypertension. In particular, it is expected that hydrogen will enter the legs through the skin of the legs and improve the condition of the legs. In this way, by absorbing hydrogen into the body using the portable hydrogen gas suction (inhalation) system of the present invention, it is possible to promote health by reducing blood pressure, stabilizing blood pressure, reducing blood sugar levels, relieving stress, and the like. be able to. Using the portable hydrogen gas suction (inhalation) system of the present invention before, during, and after sports will increase the training effect. If the elderly use the portable hydrogen gas suction (inhalation) system of the present invention, it is effective in preventing aging and improving dementia.

INDUSTRIAL APPLICABILITY As described above in detail, the present invention is a portable hydrogen gas inhalation system capable of inhaling hydrogen gas into the body anytime and anywhere. The portable hydrogen gas inhalation system of the present invention includes at least a portable hydrogen generation system, a portable hydrogen generation system and an inhalation mask (including a nasal cannula, etc.), and a hydrogen introduction tube (tube) connecting them. A portable hydrogen generating system is a system in which a cylindrical holder capable of storing a hydrogen generating agent is put in a hydrogen generator (container) and hydrogen gas is discharged. ADVANTAGE OF THE INVENTION This invention attaches the cylindrical holder which can accommodate a hydrogen-producing agent inside to a hydrogen generator, and can generate hydrogen efficiently by reaction of a hydrogen-producing agent and water. In this specification, it is needless to say that the contents described and explained in a certain part of the specification can be applied to other parts without contradiction, and the contents can be applied to the other parts. Further, the above-described embodiment is merely an example, and can be implemented with various modifications within the scope of the invention, and the scope of rights of the present invention is not limited to the above-described embodiment.

Since hydrogen is a small molecule and penetrates through the skin and cells of the body, the present invention can enhance health promotion by supplying it to all parts of the body.

10 hydrogen atomization system, 11 hydrogen generator, 12 hydrogen generator holder, 13 cap,
14 gas outlet, 15 (first) hydrogen introduction pipe, 16 hydrogen intake pipe, 17 hydrogen water container,
18 hydrogen inlet, 19 (second) hydrogen inlet pipe, 20 outlet, 21 hydrogen inlet,
22 mist (fog) generator, 23 inhalation mask, 24 inhalation port, 25 lid, 26 outlet,
27 connection part, 30 plate-shaped (spiral) sheet, 31 cylindrical hydrogen generating agent holder,
32 tensile force, 33 gap, 34 hydrogen generating agent bag (case), 38 opening,
39 boundary (break), 40 hydrogen generation container (hydrogen generator), 41 columnar container, 42 container lid,
43 hydrogen discharge port (hydrogen exhaust port), 44 water, 45 container cover surface, 46 water intrusion, 47 hydrogen flow path, 48 check valve, 51 cylindrical hydrogen generating agent holder positioning projection, 52 handle,
53 cylindrical hydrogen generating agent holder support guide, 54 string, 61 cylindrical holder,
62 spiral (spiral) portion, 63 hollow cylindrical portion without helical (spiral) portion, 64 gap,
65 tensile force, 80 hydrogen generating container (hydrogen generator), 81 cylindrical hydrogen generating agent holder,
82 water surface stopper, 85 hydrogen generating agent holder (cylindrical tube), 86 cut (border),
87 hydrogen generating agent bag (case), 91 hydrogen generator (hydrogen generator), 92 hydrogen inhalation mask,
93 hydrogen introduction tube,
100 cylindrical hydrogen generating agent holder, 101 lower cylindrical holder, 102 upper cylindrical holder,
103 upper surface opening, 104 upper surface opening, 105 hydrogen generating agent bag (case), 107 water passage hole,
108 hydrogen vent, 109 connection part, 110 hydrogen generator (container) body,
111 hydrogen generator (container) body,
112 hydrogen generator (container) main body shoulder,
113 hydrogen generator (container) neck portion, 114 lower opening, 115 upper opening,
116 ear, 117 arrow, 120 hydrogen generator (container) upper lid, 121 upper lid columnar part (side),
122 upper lid hydrogen discharge (exhaust) port, 123 upper lid lower surface opening,
124 hydrogen discharge (exhaust) port opening, 125 top lid ceiling surface,
130 hydrogen generator (container) lower (bottom) lid, 131 hydrogen generator (container) lower lid side,
132 hydrogen generator (container) lower (bottom) surface of the lower lid, 133 upper surface opening of the lower lid,
134 sealing material, 135 water, 136 water upper limit position, 137 hydrogen exhaust direction

Claims (23)

A portable hydrogen generator used for inhaling hydrogen gas,
The hydrogen generating device is a water bottle container that is hollow inside and can store water, and is a device that generates hydrogen by reacting a hydrogen generating agent and water,
A lid (upper lid) that can be freely removed or opened and closed is attached to the upper opening of the hydrogen generator,
The hydrogen generating agent is housed in the inner cavity of a cylindrical holder having an inner cavity penetrating from the upper surface to the lower surface,
The cylindrical holder is arranged in the internal space of the hydrogen generator,
Part or all of the cylindrical holder part containing the hydrogen generating agent is immersed in water placed in the internal space of the hydrogen generator,
The hydrogen generating agent accommodated in the inner cavity of the cylindrical holder by water entering the inner cavity of the cylindrical holder through the bottom opening of the cylindrical holder and/or the hole provided in the lower outer shell of the cylindrical holder. and water come into contact with each other to generate hydrogen,
Hydrogen passes through the inner cavity of the cylindrical holder and is discharged from a hydrogen discharge port provided in the upper lid of the hydrogen generator,
Furthermore, an anti-swaying stopper is attached to the inside of the hydrogen generator to prevent the water surface from shaking, and the anti-swaying stopper is a member that covers the water surface.
Portable hydrogen generator. 2. The portable hydrogen generator according to claim 1, wherein the anti-swaying stopper has a hole through which the cylindrical holder passes.
The upper cavity of the hydrogen generator is narrower than the lower cavity, and part or all of the upper part of the cylindrical holder is located in the upper cavity of the hydrogen generator. Item 3. The portable hydrogen generator according to Item 1 or 2. The portable hydrogen generator according to any one of claims 1 to 3, wherein the cylindrical holder is inserted into the internal space of the hydrogen generator from an upper opening of the hydrogen generator. . The cross-sectional size of the internal cavity at the bottom of the cylindrical holder is larger than the cross-sectional size of the internal cavity at the top of the cylindrical holder, and the hydrogen generating agent is accommodated in the internal cavity at the bottom of the cylindrical holder. The portable hydrogen generator according to any one of claims 1 to 4, characterized in that: The cylindrical holder is formed by connecting an upper cylindrical holder and a lower cylindrical holder, and the cross-sectional size of the inner cavity of the lower cylindrical holder is larger than the cross-sectional size of the inner cavity of the upper cylindrical holder. A portable hydrogen generator according to claim 5. The hydrogen generator has an opening at the bottom (bottom opening), and a lid (bottom lid) that can be freely removed or opened and closed is attached to the bottom opening. 7. Portable hydrogen generator according to any one of items 6. 8. The portable hydrogen generator according to claim 7, wherein a removable sealing member is arranged on the bottom lid at the contact portion between the bottom lid and the bottom opening of the hydrogen generator. The portable hydrogen generator according to any one of claims 1 to 8, wherein the tubular holder is made of a polymer material or a metal material. 10. The open/close lid of the hydrogen generator is provided with a check valve capable of releasing gas when the internal pressure inside the hydrogen generator increases. A portable hydrogen generator according to any one of the preceding paragraphs. A portable hydrogen generator used for inhaling hydrogen gas,
The hydrogen generating device is a water bottle container that is hollow inside and can store water, and is a device that generates hydrogen by reacting a hydrogen generating agent and water,
The opening of the hydrogen generator is attached with an opening/closing lid that can be freely removed or opened,
The hydrogen generating agent is housed in the inner cavity of a cylindrical holder having an inner cavity penetrating from the upper surface to the lower surface,
The cylindrical holder is arranged in the internal space of the hydrogen generator,
Part or all of the cylindrical holder part containing the hydrogen generating agent is immersed in water placed in the internal space of the hydrogen generator,
The outer shell of the cylindrical holder is partially or entirely spirally cut,
Part or all of the cut portion of the cylindrical holder is immersed in water in the hydrogen generator,
Water enters the inner cavity of the cylindrical holder through the cut in the outer shell of the cylindrical holder and/or the bottom opening of the cylindrical holder, and the water contacts the hydrogen generating agent stored in the inner cavity of the cylindrical holder. and hydrogen is generated,
A portable hydrogen generator, wherein hydrogen is discharged from a hydrogen outlet provided in an opening/closing lid of the hydrogen generator. 12. The portable hydrogen generator according to claim 11, wherein the hydrogen generating agent is housed in a water permeable case (hydrogen generating agent storage case). The upper opening of the cylindrical holder is arranged at the upper part of the hydrogen generator,
13. The portable hydrogen generator of claim 11 or 12, wherein the lower opening of the cylindrical holder is located at or near the bottom of the hydrogen generator. 14. The apparatus according to any one of claims 11 to 13, characterized in that the upper opening of said cylindrical holder is arranged near or in close contact with a hydrogen discharge port provided in the upper part of said hydrogen generator. Portable hydrogen generator. A projection for positioning the cylindrical holder is provided on the bottom surface of the hydrogen generator, and the projection is inserted into an opening on the lower surface side of the cylindrical holder to position the cylindrical holder. 5. The portable hydrogen generator according to any one of 1 to 4. The portable hydrogen generator according to any one of claims 11 to 15, characterized in that a positioning support guide for determining the position of said cylindrical holder is attached inside said hydrogen generator. 17. The portable hydrogen generator according to any one of claims 11 to 16, characterized in that an anti-vibration stopper for preventing vibration of the water surface is attached inside said hydrogen generator. The portable hydrogen generator according to any one of claims 11 to 17, wherein the cylindrical holder is made of a polymeric material or a metallic material. Any one of claims 11 to 18, characterized in that the open/close cover of the hydrogen generator is provided with a check valve capable of releasing gas when the internal pressure inside the hydrogen generator increases. A portable hydrogen generator according to any one of the preceding paragraphs. The portable hydrogen generator according to any one of claims 11 to 19, wherein the spirally cut cylindrical holder is formed by spirally winding an elongated plate-like sheet. . 11. The spirally cut cylindrical holder is obtained by spirally cutting part or all of an outer shell of an uncut cylindrical holder to form a cut. 21. Portable hydrogen generator according to any one of items 20. Extending the spirally cut portion of the cylindrical holder,
The hydrogen generating agent storage case or hydrogen generating agent stored in the inner space of the cylindrical holder is taken out from the gap formed by the spiral cut of the cylindrical holder, or the spiral cut of the cylindrical holder is taken out. The portable hydrogen generator according to any one of claims 11 to 21, characterized in that the hydrogen generating agent storage case or the hydrogen generating agent is stored in the inner space of the cylindrical holder through the gap formed by stretching. Device. The portable hydrogen generator according to any one of claims 1 to 22 can be carried by wearing it on the body, and an inhaler can be attached to the nose or mouth to inhale the hydrogen gas generated by the hydrogen generator into the body. A portable hydrogen gas inhalation system characterized by:

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