HK1240568B - Hydrogen injection device - Google Patents

Description

Hydrogen injection device

Technical Field

The present invention relates to a hydrogen injection device capable of additionally injecting hydrogen into a general-purpose water dispenser, a gallon drum, or the like.

Background

With the recent expansion of the drinking water market, water dispensers capable of supplying purified water or natural water are gradually spreading to enterprises, sports facilities, and even homes. Therefore, the quality of drinking water required by users also varies. Among these, so-called hydrogen-rich water containing a large amount of hydrogen has attracted attention in recent years, and it is possible to effectively eliminate active oxygen that causes various diseases such as cancer, and there is a growing demand for encouraging the intake of hydrogen-rich water in the sports industry, the medical community, and the like. As a generator of this hydrogen-rich water, a generator that performs a chemical reaction using magnesium particles and water is known. Specifically, for example, a hydrogen-rich water generator may be put in or carried by a drinking water machine, and hydrogen may be added to water stored in the water generator to generate hydrogen-rich water.

However, the above-mentioned water dispenser type hydrogen-rich water generator is configured to react predetermined magnesium particles with water to generate hydrogen (Mg + 2H)₂O→Mg(OH)₂+H₂) And the production of hydrogen is limited, so that maintenance work such as replacement must be performed at every life span. The maintenance operation is to remove the hydrogen-rich water generator in the drinking water storage tank of the water dispenser and then put in a new hydrogen-rich water generator, so the operation is complicated, and the sanitation aspect is also inconvenient. Further, since the amount of hydrogen evolution is in accordance with the above chemical reaction formula, it is difficult to adjust the amount of hydrogen to be injected stepwise, and for example, it is impossible to inject a large amount of hydrogen into the drinking water to be added to the water dispenser and to generate hydrogen-rich water in a short time, and it is impossible to adjust or increase the hydrogen content in each hydrogen-rich water. Although there are also apparatuses in which a hydrogen tank is directly connected to a water dispenser to generate hydrogen-rich water in a short time, much attention is required to be paid to methods of handling and storing the hydrogen tank, and there is a serious risk of ignition explosion and the like.

Documents of the prior art

Patent document

Patent document 1: japanese patent laid-open No. 2007-167696

Patent document 2: japanese patent laid-open No. 2004-41949

Disclosure of Invention

Problems to be solved by the invention

The present invention has been made in view of the above problems, and an object of the present invention is to provide a hydrogen injector that is excellent in work efficiency and hygiene during maintenance and can generate hydrogen-rich water whose hydrogen content can be flexibly adjusted.

Means for solving the problems

The present invention provides a hydrogen injection device for additionally injecting hydrogen (hereinafter, simply referred to as "hydrogen gas" as described above) into drinking water. The hydrogen injection device is provided with: a reference container for storing water for hydrogen evolution reaction while carrying particulate matter having a substance on the surface thereof, the substance being capable of hydrogen evolution reaction with water, on the bottom thereof; a communication unit fluidly connecting an upper interior of the reference container and the drinking storage water in a sealed state; and an auxiliary means for enhancing the hydrogen injection from the reference container into the drinking water storage through the communication means.

The hydrogen injection device of the present invention is provided with a hydrogen separation device (the reference container) and an auxiliary strengthening container for promoting the amount of hydrogen separated by the hydrogen separation device, in addition to a container for storing drinking water. The hydrogen injection device can inject or enhance hydrogen into the existing water dispenser or hydrogen-rich water dispenser by adding an additional ' device, and the operation can be completed only by replacing each ' additional ' device or replacing the reaction substance in the ' additional ' device during maintenance, so that the operability is improved, and further, the hydrogen injection device has an advantage in terms of sanitation during operation. The "separate" device is constituted by two devices, i.e., a hydrogen generator (the reference container) in a normal state and an auxiliary enhancing container for promoting the hydrogen generation amount, and the hydrogen content in the drinking water machine can be flexibly changed by injecting hydrogen by either device.

Further, the communication means of this hydrogen injection device is a pipe that branches a hydrogen injection path for injecting hydrogen from the reference container to the drinking storage water into a normal path and an auxiliary reinforcement path, and the auxiliary means may include: an auxiliary reinforcement container that stores an auxiliary material that causes a more vigorous hydrogen evolution reaction than the particulate matter carried in the reference container; a dropping device dropping from the auxiliary reinforcement container into the water in the reference container; and a switching valve which switches the normal path of the pipeline to the auxiliary reinforcing path and injects hydrogen into the drinking water in conjunction with the operation of the dispenser.

In addition, the auxiliary substance stored in the auxiliary reinforcement container may be a plurality of particles each having a surface covered with magnesium, or a plurality of particles that undergo a hydrogen evolution reaction by an aluminum hydride component on the surface.

The reactions that generate hydrogen are diverse. In the past, the above-mentioned hydrogen evolution apparatus using magnesium has typically been used in view of the stability of the reaction, the length of the reaction time, and the like. On the other hand, it has been recently found that the hydrogen evolution reaction (described below) using the powdery aluminum not only ensures the amount of hydrogen evolution but also is efficient and stable. In addition, it is possible to provide a hydrogen evolution reaction suitable for drinking water in the future. However, in general, a reaction which generates a large amount of hydrogen inevitably involves problems such as an excessively large amount of reaction heat and a short reaction time with respect to the amount of a reactant (the aluminum reaction also involves the same problem).

On the other hand, the initial value of the hydrogen content in the water containing hydrogen water varies. For example, the hydrogen concentration varies depending on the material of the container, the standing time, the new amount of water to be injected, and the like, and the amount of hydrogen before reaching a predetermined hydrogen concentration varies gradually. In addition, the amount of hydrogen required varies depending on the use application of the hydrogen-containing water. The hydrogen injection device is manufactured as a device capable of flexibly coping with such a problem, and can appropriately switch between a path in a normal state in which a long-term reaction can be performed with a predetermined amount of hydrogen and an auxiliary path when it is desired to rapidly increase the amount of hydrogen, and provide drinking storage water. Further, since the operation of transporting hydrogen through the auxiliary route is a temporary option, the entire hydrogen injector is advantageous in that it takes priority over the normal route and there is no problem of hydrogen evolution reaction (as described above). In other words, the hydrogen injection device is characterized in that the hydrogen content can be flexibly adjusted to the hydrogen content required in the drinking water, so that the hydrogen content can be changed, and the profit and loss in various hydrogen evolution reactions can be mutually offset.

Further, the communication unit may have: a pipe constituting a hydrogen injection path for injecting hydrogen from the reference container to the drinking storage water and capable of being coupled to a gallon bucket for storing drinking water; and a spray member coupled to the pipe and extending below the gallon drum, capable of spraying hydrogen to the drinking water. The auxiliary unit may have: an auxiliary reinforcement container that stores an auxiliary material that causes a more vigorous hydrogen evolution reaction than the particulate matter carried in the reference container; and a throwing device which is thrown from the auxiliary reinforcing container into the water in the reference container.

Conventionally, many hydrogen-rich water generators are dedicated machines, and a user who needs hydrogen-rich water must install a separate hydrogen-rich water generator, which makes the operation complicated and causes problems in terms of cost and installation space. These problems are stumbling stones in order to extend the hydrogen rich water market to the existing water dispenser market. In this regard, this hydrogen injection device can be handled by attaching to a water dispenser having a general gallon bucket in the existing water dispenser market, and therefore, it is not necessary to newly introduce a special machine for generating hydrogen-rich water, and it is possible to satisfy the user's demand for expecting a convenient and inexpensive hydrogen-rich water.

Further, the drinking storage water is injected from a fluidly connected gallon drum through a water injection port at an upper portion of the storage container thereof, and the communication unit is constituted by a pipe forming a path for injecting hydrogen directly into the drinking storage water from the reference container and the water injection port. Further, the auxiliary unit preferably has:

an auxiliary reinforcement container that stores an auxiliary material that causes a more vigorous hydrogen evolution reaction than the particulate matter carried in the reference container; and a throwing device which is thrown from the auxiliary reinforcing container into the water of the reference container. In addition, the auxiliary substance stored in the auxiliary reinforcement container is preferably a plurality of particles each having a surface covered with magnesium or aluminum hydride (AlH)₃)。

As described above, this apparatus is configured to be able to directly inject hydrogen into the drinking water from the reference container, and also to be able to inject hydrogen that is not contained in (surplus) the drinking water into the replenishing gallon drum provided in the upper part. As a result, the water in the gallon drum for replenishment can be changed into hydrogen-rich water at the same time, and the initial hydrogen content of the replenishment water in the gallon drum can be increased to be ready for use. Thus, after replenishing the water to the container storing the drinking water, the necessity of injecting a large amount of hydrogen can be reduced, and a large amount of hydrogen-rich water can be supplied at a time.

Further, the hydrogen filling device is a hydrogen filling device for additionally filling hydrogen into a gallon drum to which drinking water is replenished, and is characterized by comprising: a sealed container part which carries particulate matter having a substance that reacts with water to generate hydrogen on the surface thereof on the bottom thereof and stores water for generating hydrogen reaction; a hollow cylinder member vertically extending from the upper portion to the bottom portion of the container portion, the cylinder member being provided with a hole capable of sucking gas in the container portion in the vicinity of the upper end thereof; a piston member vertically slidable in the hollow cylindrical member; a pressing unit for sliding the piston member downward; an elastic member that restores the piston member slid downward to slide upward; a hydrogen injection member fluidly connected to the cylinder member and extending into the potable storage water in the gallon bucket; and a securing unit located at the bottom of the container portion to an upper portion of the gallon bucket. In this device, after the pressing unit is pressed, the piston member is slid downward, and the lifted-up cylinder member is conveyed to the hydrogen injection member. And the particulate matter is composed of a plurality of particles, each of which is covered with magnesium.

The hydrogen injection device can greatly reduce the volume compared with a general placement type water dispenser by directly connecting the container part for generating hydrogen and a gallon barrel for supplementing drinking storage water. Further, this apparatus is advantageous in that the drinking water stored in the gallon drum can be directly changed to hydrogen-containing water, and for example, the drinking water stored in the gallon drum to be stored can be changed to hydrogen-rich water and stored, so that the hydrogen-rich water can be immediately and quickly supplied when the gallon drum is replaced.

Drawings

Fig. 1 is a schematic view showing a water dispenser type hydrogen-rich water generator according to the present invention.

Fig. 2 is a schematic view showing another hydrogen-rich water generation vessel according to the present invention.

Fig. 3 is a schematic view showing another hydrogen-rich water generating container according to the present invention, wherein (a) is an assembly view and (B) is an exploded view.

Fig. 4 is a schematic view showing another hydrogen-rich water generation vessel according to the present invention.

Detailed Description

One embodiment of the hydrogen injection device of the present invention will be described.

Fig. 1 is a schematic view showing an example of the hydrogen injector according to the present embodiment (a wavy line in the drawing indicates a boundary line between an external appearance and a cross section of a member, and the same applies to other drawings below). The hydrogen injection device shown in fig. 1 is substantially composed of: a hydrogen evolution barrel 1, wherein the hydrogen evolution barrel 1 is used for generating hydrogen; a water dispenser built-in tub 3, the water dispenser built-in tub 3 storing drinking storage water (hereinafter, also referred to simply as "drinking water" in this specification); and an aluminum powder reserve layer 5, the aluminum powder reserve layer 5 serving to promote the generation of hydrogen.

The hydrogen-evolving tank 1 includes a container 13 opened upward in a contained state. Reaction water 15 and spherical magnesium particles 17 are charged into the vessel 13, and the magnesium particles 17 are coated with magnesium on the surface and react with the reaction water 15 to generate hydrogen. A drain pipe 24 is provided on the lowermost side surface of the container 13, and the drain pipe 24 penetrates the hydrogen separation drum 1 from the container 13 and is led to the outside, and can discharge the reaction water 15 after use. Further, a space 19 capable of temporarily storing hydrogen gas generated from the reaction water 15 and the magnesium particles 17 is provided above the container 13. A reaction tap water inlet 21 penetrating the hydrogen separation tank 1 is provided on the side surface side of the space 19, and water 15 can be supplied into the hydrogen separation tank 1 from the outside through the reaction tap water inlet 21.

Hydrogen gas (reaction formula Mg + 2H) generated in the container 13 inside the hydrogen evolution tank 1₂O→Mg(OH)₂+H₂) Rises to the space 19 and from the space 19 through the top surface of the hydrogen-evolving tank 1. Then, the hydrogen gas flows into the inside of the water dispenser built-in tub 3 through a general pipe 9 connected to the side of the water dispenser built-in tub 3. The fitting portion of the normal pipe 9 and the water dispenser built-in tub 3 is provided with a fluorine film 22 having a diameter of 50mm, which ensures that only hydrogen gas is delivered from the normal pipe 9 into the water dispenser built-in tub 3, while preventing the drinking water 7 in the water dispenser built-in tub 3 from flowing backward into the normal pipe 9. Further, a check valve is provided at the fitting portion between the water fountain tank 3 and the normal pipe 9, and the check valve causes the hydrogen gas to flow only in the direction toward the inside of the water fountain tank 3, similarly to the fluorine film 22, thereby suppressing the water 7 in the water fountain tank 3 from flowing backward toward the normal pipe 9. The drinking water 7 injected from the drinking water injection port 25 arranged on the top surface of the drinking water machine built-in barrel 3 is stored in the drinking water machine built-in barrel 3, and the hydrogen entering the drinking water machine built-in barrel 3 is mixed with the drinking water 7.

Further, an openable lid 27 is provided on the top surface of the aluminum powder reserve layer 5, and the aluminum powder 23 (AlH) is poured into the aluminum powder reserve layer 5 by opening the lid 27₃). The aluminum powder 23 promotes the generation of hydrogen gas in the hydrogen evolution tank 1. The bottom surface of the aluminum powder reserve layer 5 is communicated with an aluminum powder replenishing device 31 for controlling the replenishing amount of the aluminum powder 23 through a charging pipe 29, and the aluminum powder 23 is transported to the inside of the aluminum powder replenishing device 31 through the charging pipe 29. The aluminum powder 23 whose amount is designated by the aluminum powder replenishing device 31 enters the inside of the container 13 from the bottom surface of the aluminum powder replenishing device 31 through the aluminum powder guide duct 33 connected to the side surface of the hydrogen evolution barrel 1, and promotes the generation of hydrogen gas (2 AlH) by reacting with the reaction water 15₃+3H₂O→Al₂O₃+6H₂)。

When the generation of hydrogen gas is promoted by using the aluminum powder 23, the hydrogen gas is sent to the water dispenser built-in tub 3 through a path using the turbo-charging pipe 35 (hereinafter, referred to as a "turbo-charging path"), unlike the path sent from the normal pipe 9 to the water dispenser built-in tub 3 (hereinafter, referred to as a "normal path"). The turbo-charging duct 35 is branched by a switching valve 37 provided in the normal duct 9, and is switched between the normal path and the turbo-charging path by the operation of the switching valve 37. The switching valve 37 is operated in synchronization with the powdery aluminum replenishing device 31 when the powdery aluminum 23 is charged into the container 13. In addition, a check valve is also provided at the connection part between the turbo charging pipe 35 and the water dispenser built-in tub 3, and the check valve allows hydrogen gas to flow only in the direction toward the inside of the water dispenser built-in tub 3, thereby preventing the water 7 in the water dispenser built-in tub 3 from flowing backward toward the turbo charging pipe 35.

The fitting portion of the turbo-charging duct 35 and the water fountain built-in tub 3 is different from the fitting portion of the normal duct 9 and the water fountain built-in tub 3, and the former is provided with a hydrogen evolution bubbling port 39. The hydrogen gas flowing into the water fountain internal tank 3 through the turbo-charging pipe 35 is converted into fine bubbles by the hydrogen-evolving bubble-forming port 39, and can be more effectively mixed with the drinking water 7 than in the normal case where the hydrogen gas passes through the normal pipe 9.

Next, referring to fig. 2, another hydrogen injection device of the present invention is shown. Fig. 2 is a schematic diagram showing a case where a conventional water dispenser is used in place of the water dispenser built-in tub 3 described in detail in the hydrogen injection device of the present embodiment. A water dispenser having a gallon bucket 43 in the upper portion and having a generally basic configuration is preferably used. The tip of the connection pipe 41 connected to the space 19 in the hydrogen separation tank 1 is inserted from the top of the drinking water tank of the conventional water dispenser to the inside, and is connected to the fitting portion between the connection pipe 41 and the gallon tank 43 by using the connector 45. The connection hydrogen evolution bubble 47 is also provided at the distal end of the connection pipe 41, and both the connection hydrogen evolution bubble 47 and the hydrogen evolution bubble 39 act on the hydrogen gas in the same manner and convert the hydrogen gas into fine bubbles.

Next, schematic diagrams of other water dispenser type hydrogen-rich water generators of the present invention are also shown in fig. 3(a), (b). The simplified small hydrogen-evolving tank 51 can be combined with a gallon tank 49 having a substantially gallon tank shape for use. A fixing holder 52 is attached to the outer periphery of the lower part of the small hydrogen evolution tank 51, and the bottom surface of the small hydrogen evolution tank 51 to which the fixing holder 52 is attached is covered with the top surface of the gallon drum 49. The small hydrogen-evolving tank 51 has a hollow interior, and a pump 53 is attached to the tank from the center of the top surface to the center of the bottom surface, and the lower end of the pump 53 is connected to a hydrogen gas guide pipe 55. Reaction water 57 and spherical magnesium particles 59 are added to the inside of the small hydrogen-evolving tank 51, and the magnesium particles 59 react with the reaction water 57 to generate hydrogen gas. Further, a tap water inlet 61 for reaction communicating with the outside is provided on the top surface of the small hydrogen evolution tank 51, and the reaction water 57 can be replenished into the small hydrogen evolution tank 51 from the outside.

The step of injecting hydrogen gas into the drinking water 69 by the pump 53 will be further described. A piston 64 is disposed below the push-in portion 63 of the elastic resin member protruding in an upward arc shape in the pump 53, and the piston 64 slides in a cylinder 66 disposed vertically in the bellows portion 65. Accordingly, when the pushing portion 63 is pushed downward by hand pressure, the piston 64 slides downward, and the hydrogen gas 58 in the cylinder 66 is pushed downward and transported into the hydrogen gas guide pipe 55. Further, the upper end portion of the bellows portion 65 is coupled to the outer periphery of the piston 64 (reference numeral 68), and thus moves up and down in conjunction with the piston 64. When the hand pressure to the press-in portion 63 is released after the hydrogen gas in the cylinder 66 is fed downward, the bellows portion 65 is expanded upward by the elastic restoring force thereof, and the piston 64 is also moved upward. At this time, the pressure in the cylinder 66 becomes negative, and the hydrogen gas 58 needs to be replenished in the tub 51.

Here, observing the piston 64 and the bellows portion 65 again, first, the bellows portion 65 is not sealed from the outside, and therefore the hydrogen gas 58 is replenished into the bellows portion 65. Further, a plurality of holes 64a are disposed near the center of the piston 64, penetrate the cylinder 64, and communicate with the bottom surface 64 b. Accordingly, the cylinder 66 is slid upward, and the hole 64a is opened in the direction of the space in the bellows portion 65 beyond the upper end position of the cylinder 66, so that the hydrogen gas can flow in. As a result, when the hand pressure is released, the pressure in the cylinder 66 becomes negative, and the hydrogen gas is replenished. By repeating the series of operations of applying and releasing the hand pressure in this manner, the hydrogen gas can be sent downward by moving the piston 64 upward and downward.

Further, a check valve is provided to overlap a fitting portion between the pump 53 and the hydrogen gas guide pipe 55. The check valve only allows hydrogen gas to flow in a direction toward the interior of the gallon drum 49, restricting the drinking water 69 in the gallon drum 49 from flowing back into the pump 53. A hole 71 for inserting the hydrogen guide pipe 55 is provided in the top surface of the gallon barrel 49, and the drinking water 69 inside the gallon barrel 49 is mixed with hydrogen gas through the hole 71.

Next, fig. 4 shows a schematic view of another hydrogen injection device of the present invention. In this device, a processing-type water dispenser built-in tank 73 and a large tank 75 on the upper part of the processing-type water dispenser built-in tank 73 are connected to be used in place of the water dispenser built-in tank 3 of the hydrogen injection device of the present embodiment described in detail. By combining the built-in bucket 73 and the large bucket 75 of the processing type water dispenser, when a large amount of hydrogen-rich water is needed, the drinking water can be supplied without frequently supplementing the drinking water.

The front end of the connecting pipe 77 connected to the space 19 in the hydrogen separation tank 1 is inserted into the tank from a top cover 79 on the top of the tank 73. The fitting portion between the top cover 79 and the processed water fountain tank 73 sandwiches the gasket a85, and prevents the drinking water 81 and the hydrogen gas in the processed water fountain tank 73 from leaking to the outside. The front end of the processed connecting pipe 77 also has a processed hydrogen evolution vent 83 which exerts the same effect as the hydrogen evolution vent 39 described in detail above on hydrogen to efficiently mix the hydrogen gas entering the processed water dispenser internal tank 73 with the drinking water 81 in the processed water dispenser internal tank 73.

The top cover 79 positioned on the top surface of the built-in tank 73 of the drinking fountain is connected to the large tank 75, and the gasket B87 is sandwiched by the fitting portions. The hydrogen gas stored in the upper part of the interior of the processing-type water dispenser built-in tub 73 is transferred into the large tub 75 through the fitting part of the processing-type water dispenser built-in tub 73 and the large tub 75 so as to exchange with the drinking water 89 in the large tub 75. The drinking water 89 in the large tank 75 is mixed with hydrogen gas each time the hydrogen gas is delivered into the large tank 75, and moves into the lower processing-type water dispenser built-in tank 73. Therefore, every time the drinking water 81 is consumed, the drinking water 89 mixed with the hydrogen gas is replenished into the processing-type water dispenser built-in tank 73.

While the embodiments of the present invention have been described with reference to the drawings, it will be understood by those skilled in the art that the present invention is not limited to the embodiments, and other modifications and variations may be made without departing from the spirit and scope of the claims.

Industrial applicability of the invention

The hydrogen injection device of the invention has good operation efficiency and sanitation in maintenance, and can generate hydrogen-rich water with flexibly adjustable hydrogen content. In particular, it can be used for all water or solutions intended to contain hydrogen. And can be used for hydrogen-rich water generators and general containers. For example, the present invention can be used not only for various drinking water applications such as a hydrogen-rich water dispenser, a gallon drum, and a plastic bottle, but also for cosmetic water, facial cleanser, and cosmetic liquid storage containers installed in beauty salons, beauty parlors, and the like. Drinking water in the present specification means water with low biohazard, and is naturally also suitable for use in cosmetic applications and the like according to this definition.

Description of the reference numerals

1 Hydrogen evolution barrel

3 built-in bucket of drinking machine

5 aluminum powder reserve layer

7 Drinking water

9 general pipeline

13 Container

15 water for reaction

17 magnesium particles

19 space (a)

21 tap water injection port for reaction

22 fluorine film

23 aluminum powder

24 drainage pipe

25 drinking water inlet

27 cover

29 delivery pipeline

31 aluminum powder supplementing device

33 aluminum powder guide pipeline

35 turbocharging pipeline

37 switching valve

39 hydrogen evolution bubble

41 connecting pipe

43 gallon bucket

45 connector

47 hydrogen bubbling port for connection

49 gallon bucket

51 small-sized hydrogen evolution barrel

52 fixing holder

53 pump

55 hydrogen guide pipe

Water for 57 reaction

58 hydrogen gas

59 magnesium particles

61 tap water filling nozzle for reaction

63 push-in part

64 piston

64a hole

64b bottom surface

65 corrugated pipe

66 air cylinder

69 Drinking water

71 hole

73 built-in barrel of processing type water dispenser

75 large barrel

77 processing type connecting pipe

79 Top cover

81 Drinking water

83 processing type hydrogen evolution bubbling mouth

85 shim A

87 shim B

89 Drinking water

Claims (7)

1. A hydrogen injection device for additionally injecting hydrogen into drinking water, comprising:

a reference container for storing water for hydrogen evolution reaction while carrying particulate matter having a substance on the surface thereof, the substance being capable of hydrogen evolution reaction with water, on the bottom thereof; a communication unit fluidly connecting an upper interior of the reference container and the drinking storage water in a sealed state; an auxiliary unit that enhances hydrogen injection from the reference container to the drinking storage water via the communication unit;

the communication means is a pipe that branches a hydrogen injection path for injecting hydrogen from the reference container into the drinking storage water into a normal path and an auxiliary reinforcement path;

the auxiliary unit has: an auxiliary reinforcement container that stores an auxiliary material that causes a more vigorous hydrogen evolution reaction than the particulate matter carried in the reference container; a dropping device dropping from the auxiliary reinforcement container into the water in the reference container; and a switching valve which switches the normal path of the pipeline to the auxiliary reinforcing path and injects hydrogen into the drinking water in conjunction with the operation of the dispenser.

2. A hydrogen injection device for additionally injecting hydrogen into drinking water, comprising:

a reference container for storing water for hydrogen evolution reaction while carrying particulate matter having a substance on the surface thereof, the substance being capable of hydrogen evolution reaction with water, on the bottom thereof; a communication unit fluidly connecting an upper interior of the reference container and the drinking storage water in a sealed state; an auxiliary unit that enhances hydrogen injection from the reference container to the drinking storage water via the communication unit;

the communication unit has: a pipe constituting a hydrogen injection path for injecting hydrogen from the reference container to the drinking storage water and capable of being coupled to a gallon bucket for storing drinking water; and a spray member coupled to the pipe and extending below the gallon drum, the spray member being capable of spraying hydrogen to the potable water;

the auxiliary unit has: an auxiliary reinforcement container that stores an auxiliary material that causes a more vigorous hydrogen evolution reaction than the particulate matter carried in the reference container; and a throwing device which is thrown from the auxiliary reinforcing container into the water in the reference container.

3. A hydrogen injection device for additionally injecting hydrogen into drinking water, comprising:

a reference container for storing water for hydrogen evolution reaction while carrying particulate matter having a substance on the surface thereof, the substance being capable of hydrogen evolution reaction with water, on the bottom thereof; a communication unit fluidly connecting an upper interior of the reference container and the drinking storage water in a sealed state; an auxiliary unit that enhances hydrogen injection from the reference container to the drinking storage water via the communication unit;

the drinking storage water is injected from a fluidly connected gallon drum through a water injection port in an upper portion of the storage container thereof, and the communication unit is constituted by a pipe forming a path for injecting hydrogen directly into the drinking storage water from the reference container and the water injection port;

the auxiliary unit has: an auxiliary reinforcement container that stores an auxiliary material that causes a more vigorous hydrogen evolution reaction than the particulate matter carried in the reference container; and a throwing device which is thrown from the auxiliary reinforcing container into the water in the reference container.

4. The hydrogen injection apparatus of claim 3,

the auxiliary substance stored in the auxiliary boost container is a plurality of particles that undergo a hydrogen evolution reaction by the aluminum hydride component on the surface.

5. A hydrogen injection device for additionally injecting hydrogen into a gallon drum supplemented with potable storage water, characterized in that,

the hydrogen injection device is provided with:

a sealed container part which carries particulate matter having a substance that reacts with water to generate hydrogen on the surface thereof on the bottom thereof and stores water for generating hydrogen reaction;

a hollow cylinder member vertically extending from the upper portion to the bottom portion of the container portion, the cylinder member being provided with a hole capable of sucking gas in the container portion in the vicinity of the upper end thereof;

a piston member vertically slidable in the hollow cylindrical member;

a pressing unit for sliding the piston member downward;

an elastic member that restores the piston member slid downward to slide upward;

a hydrogen injection member fluidly connected to the cylinder member and extending into the potable storage water in the gallon bucket; and

a securing unit at the bottom of the container portion, positioned to an upper portion of a gallon bucket;

after the pressing unit is pressed, the piston member is slid downward, and the gas inside the cylinder member is transported to the hydrogen injection member.

6. The hydrogen injection apparatus of claim 5,

the particulate matter is composed of a plurality of particles, and the surfaces are respectively covered with magnesium.

7. The hydrogen injection apparatus of claim 5,

the particulate matter is composed of a plurality of particles, and hydrogen evolution reaction is performed by the aluminum hydride component on the surface.