The present invention relates to an electrolytic hydrogen and oxygen gas suction tool which is portable and can easily supply predetermined amounts of hydrogen gas or oxygen gas selectively.
Active oxygen has extremely strong oxidizability and plays a role of removing bacteria and viruses having entered the human body, but a research says that it attacks and even damages normal cells of a human. Presence of excessive active oxygen increases a possibility of damaging the normal cells and incurs risks of deterioration and mutation of cells or aging of the skin with that.
Recently, a research has discovered that hydrogen removes active oxygen, and it has attracted an attention since it is effective for health and beauty. In a reaction between hydrogen and active oxygen, only water is generated as a reactant and thus, a bad influence on the human body is extremely small. Therefore, intake of hydrogen into the body is recommended particularly for preventing aging or for promoting beauty/health in various states during physical exercises, eating and drinking, smoking, stay under ultraviolet/contaminated environments, and under a high stress such as lack of sleep and long-hour work, in which active oxygen tends to be generated easily in the body.
Moreover, oxygen is used for generating energy of a cell and is an indispensable element for metabolism of the human body. Attention has been paid to activation of the cells in the body by oxygen, and studies have been made in recent years that conscious intake of oxygen into the body is effective in promotion of natural healing of disease conditions such as fatigue recovery and fracture, improvement of hematogenous disorder, beauty, stress reduction and the like. Actually, it is known that athletes use oxygen capsules for body shaping or treatment of injuries, and oxygen masks are used for patients with weakened physical strength.
In addition to the attention to the intake of hydrogen and oxygen into the body as described above, moreover, in view of pseudo electronic cigarettes in the recent non-smoking boom or an expansion of the market for cigarettes not emitting sidestream smoke, hidden needs for smoking hydrogen or oxygen leading to health promotion is considered to be large.
As a method of generating hydrogen and oxygen, a method of electrolyzing water is generally known. This is a method of breaking down water (H2O) into hydrogen (H2) and oxygen (O2) by immersing an electrode in an aqueous solution and electrically conducting it, and only hydrogen and oxygen can be obtained without generating other harmful substances and the like by using tap water which can be easily obtained and handled. For example, Patent Literature 1 discloses a desktop hydrogen generating device which can generate hydrogen and oxygen without mixing by putting water in an electrolysis tank including an electrolytic plate in which a pair of electrode plates are brought into close contact on both surfaces of an ion exchange membrane and by electrically conducting it. Since this hydrogen generating device can be used by being arbitrarily moved by a user, convenience in handling is improved as compared with the hydrogen generating device which can be used only in an installed form.
However, though a size of the aforementioned desktop hydrogen generating device was reduced to some degree, it has not achieved such size that is suitable to be carried by the user in a bag or the like, and a power supply from an outlet needs to be ensured for use, and its moving range was limited for utilizing it as a hydrogen and oxygen gas suction tool for suctioning into the body by the user. Moreover, it was the device for obtaining only hydrogen, which does not assume intake of oxygen by the user, and the need for intake of only hydrogen, only oxygen or selectively both in accordance with the health state or use purpose of the user has not been responded.
Moreover, assuming an instrument of a portable size, disposition of an ion exchange membrane which is a separate member and a separate material in a small-sized instrument requires precise work and design, and a request for cost reduction for general use could not be satisfied, either.
[Patent Literature 1] Japanese Patent Laid-Open No. 2014-019640
The present invention was made in view of the aforementioned circumstances and has an object to provide an electrolytic hydrogen and oxygen gas suction tool which is of a charging type, small-sized and inexpensive so that a user can freely carry it and moreover, capable of selectively generating hydrogen and oxygen.
In order to solve the aforementioned problem, an electrolytic hydrogen and oxygen gas suction tool of the present invention includes:
an electrolysis tank capable of storing water and constituted by an upper part and a lower part which are fluidically connected to each other therein and integrally molded;
a pair of electrodes disposed in the lower part in the electrolysis tank, standing substantially in parallel with a vertical direction of the electrolysis tank, and faced with each other in a lateral direction;
a battery; and
a control substrate which supplies power from the battery, in which
the electrode is supplied with or shut off from power supply from the battery by the control substrate;
a partition member extending downward from a boundary between the upper part and the lower part of the electrolysis tank passing between the pair of electrodes is integrally molded and provided in the lower part of the electrolysis tank;
the pair of electrodes are fluidically connected to each other in the lower part of the electrolysis tank; and
opening/closing means which enables switching of gaseous connection between one and/or the other of the pair of electrodes separated by the partition member and the upper part of the electrolysis tank is provided.
According to the aforementioned electrolytic hydrogen and oxygen gas suction tool, first, the pair of electrodes disposed in the electrolysis tank are electrically conducted by the control substrate, hydrogen is generated by electrolysis of the water in the vicinity of one of the electrodes (negative electrode) in the electrolysis tank, and oxygen is generated in the vicinity of the other electrode (positive electrode). And mixing of air bubbles of hydrogen and oxygen is inhibited by the partition member extending between the pair of electrodes, and moreover, movement of the hydrogen or oxygen to the upper part in the electrolysis tank is controlled by the opening/closing means so that the gas can be discharged to an outside of the device through the upper part of the electrolysis tank in an “open” state, while the gas can be stored in the lower part of the electrolysis tank in a “closed” state. By means of this opening/closing means, the hydrogen or oxygen generated in the electrode can be selectively obtained. Moreover, since the present invention has simple configuration of the integrally molded electrolysis tank, electrodes, battery and control plate and the like, the hydrogen and oxygen gas suction tool can be made inexpensive and in a portable size.
Moreover, in the electrolytic hydrogen and oxygen gas suction tool of the present invention, in the lower part of the electrolysis tank and above the pair of electrodes, it is preferable that the partition member is formed by a plate member, and passage of a fluid and the gas is shut off between a one surface side and the other surface side of the partition member.
According to the aforementioned electrolytic hydrogen and oxygen gas suction tool, in the hydrogen and oxygen generated in the vicinity of the electrodes, by considering the air bubbles moving upward in the aqueous solution, mixing of the air bubbles of the hydrogen and oxygen through the aqueous solution above the electrodes can be further prevented.
The opening/closing means is a member provided on the boundary between the upper part and the lower part of the electrolysis tank and having a closed and substantially flat area and may be characterized by that the substantially flat area moves on a substantial plane in parallel with the boundary between the upper part and the lower part of the electrolysis tank in accordance with an operation by the user.
According to the aforementioned electrolytic hydrogen and oxygen gas suction tool, by parallel movement of the opening/closing means on the plane, an opening formed on the boundary between the upper part and the lower part of the electrolysis tank is selectively opened/closed. That is, with a simple mechanism in which the member is moved on the plane, resistance of the water hardly affects, easy opening/closing by a manual force which is easy for the user in the manual case, and a dynamic load on the instruments is small and thus, durability of the members can be improved, and costs of the members can be kept low.
Moreover, in the electrolytic hydrogen and oxygen gas suction tool of the present invention, the battery is disposed in parallel in the vertical direction of the electrolysis tank, and above the battery, an aromatic gas generating member in which on/off control of the aromatic gas generation is conducted by the control plate is disposed, and a channel in which the aromatic gas is merged with the gas emitted from the electrolysis tank may be provided.
According to the aforementioned electrolytic hydrogen and oxygen gas suction tool, by disposing the battery and the aromatic gas generating member in parallel with the electrolysis tank, portability is improved by a shape which is small-sized and easy to be carried, and the user can selectively intake hydrogen and oxygen. Moreover, since hydrogen or oxygen with aroma can be enjoyed in accordance with preference of the user, a product can be provided to which a user who uses an existing electronic cigarette with aroma can change without a sense of discomfort and further as a product having a health enhancing function.
Moreover, in the electrolytic hydrogen and oxygen gas suction tool of the present invention, the opening/closing means may be controlled by the control plate.
According to the aforementioned electrolytic hydrogen and oxygen gas suction tool, the opening/closing means can be operated by sending an operation signal to the control plate not with a manual cumbersome operation but with a simple operation such as touching, and hydrogen and oxygen can be selectively generated easily.
Moreover, another electrolytic hydrogen and oxygen gas suction tool of the present invention includes:
an electrolysis tank capable of storing water and constituted by an upper part and a lower part which are fluidically connected to each other therein and integrally molded;
a pair of electrodes disposed in the lower part in the electrolysis tank, standing substantially in parallel with a vertical direction of the electrolysis tank, and faced with each other in a lateral direction;
a battery; and
a control substrate which supplies power from the battery, in which
the electrode is supplied with or shut off from power supply from the battery by the control substrate;
a partition member extending downward from a boundary between the upper part and the lower part of the electrolysis tank passing between the pair of electrodes is integrally molded and provided in the lower part of the electrolysis tank; the pair of electrodes are fluidically connected to each other in the lower part of the electrolysis tank; gaseous connection between the one side of the pair of electrodes separated by the partition member and the upper part of the electrolysis tank is shut off, and the gaseous connection between the other side of the electrode and the upper part of the electrolysis tank is opened; and polarity inverting means which inverts polarity of power supplied to each of the pair of electrodes is provided.
In this electrolytic hydrogen and oxygen gas suction tool, in the aforementioned electrolytic hydrogen and oxygen gas suction tool of the present invention, it is configured such that the hydrogen or oxygen generated in the electrode by the opening/closing means can be selectively obtained, but in the aforementioned another electrolytic hydrogen and oxygen gas suction tool, hydrogen or oxygen can be selectively obtained by inverting the polarity of power to each of the electrodes as a method of selective obtainment and by closing an upper part on one electrode side so that the gas emitted to above the electrolysis tank is either hydrogen or oxygen. According to this method, hydrogen or oxygen can be selectively obtained electrically only by providing a polarity inversion circuit (polarity inverting means) on the control substrate or a separate power supply circuit.
Moreover, such a case can be considered specifically that the polarity inverting means has a polarity circuit which switches the polarity of power supplied from the battery each time an alternate-type switch is turned ON.
The “alternate” type switch is a type in which even the hand leaves a button after pressing it, the ON state is kept, and in this case, once the button is pressed to get ON, hydrogen or oxygen is continuously emitted as it is, and by pressing the button again, oxygen can be made to emit.
As another example of the polarity inverting means, provision of a polarity circuit which switches the polarity of power supplied from the battery by turning ON-OFF-ON the switch can be considered.
In the case of this polarity inverting means, there is no need to provide a separate power OFF switch, and emission of hydrogen at the first ON, oxygen at the second ON, and hydrogen again at the third ON, for example, can be performed. In the case of this example, the switch may be a momentary type, and hydrogen or oxygen can be emitted only while the button is pressed.
The polarity inverting means which inverts the polarity of the power supplied to each of the pair of electrodes can be also utilized for the present invention which can selectively obtain hydrogen or oxygen by using the closing means.
That is because, when emission/stop of hydrogen/oxygen is to be performed in a short time, stop is realized at once by operating the polarity inversion circuit. Therefore, it is advantageous when intake amounts or intake time of hydrogen/oxygen are to be controlled precisely.
According to the present invention, the electrolytic hydrogen and oxygen gas suction tool which can be carried freely by the user and capable of selectively obtaining hydrogen or oxygen can be provided. According to this electrolytic hydrogen and oxygen gas suction tool, the user can easily select hydrogen and oxygen (or both at the same time) in accordance with a health state and a use purpose of the user and take into the body regardless of the place.
Hereinafter, typical examples of embodiments of the electrolytic hydrogen and oxygen gas suction tool of the present invention will be described in detail by referring to
As described above, the electrolytic hydrogen and oxygen gas suction tool of the present invention is characterized by including a partition member and opening/closing means which are main configurations for separating generated hydrogen and oxygen.
In describing the present invention, for simple understanding, first, the configuration “except the partition member and the opening/closing means” will be described in detail by using
Moreover,
Hereinafter, the electrolytic hydrogen and oxygen gas suction tool 100 will be described referring mainly to the assembling/disassembling diagram in
As described above,
The body cover 1 has a shape which is longer on the battery receiving portion 43 side, and the electrolysis tank receiving portion 44 side is cut out so that the upper part is inclined to the side. A bottom portion of the body cover 1 can open/close the bottom portion of the battery receiving portion 43 with a body bottom cover 6 as a lid member and closes the bottom portion of the battery receiving portion 43 with the body bottom cover 6 after the battery 36 is inserted from the bottom portion during assembling. The body bottom cover 6 is closed by cross recessed screws 38. Moreover, in the body cover 1, spaces in which two control substrates (electronic substrates) 33 and 42 are disposed so as to sandwich the battery 36 in the vertical direction on the both side portion sides of the battery receiving portion 43 are provided, and the control substrate 33 on the side surface side of the body cover 1 is a main control substrate and controls power supply from the battery 36 with the control substrate 42 on the electrolysis tank 10 side performing power supply to a suctioning portion 32 (aroma generating device) and a mesh electrode 17 (electrode plate).
A decorative laminated sheet 9 is attached to the side surface of the body cover 1 along the longitudinal side surface, and a button hole 9a through which an operation button 35 to the control substrate 33 is seen, a hole 9b for LED for light irradiation from an LED substrate 30, and a hole 9c for charging connector for connecting a connector for charging the battery 36 from an external power source are provided.
By pressing on the operation button 35 three times, a power supply signal is transmitted in the control substrate 33 to the control substrate 42, and power of the battery 36 is supplied from the control substrate 42 for a predetermined time to a pair of the mesh electrodes (electrode plates) 17 through a housing 31 for substrate connector and a crimping substrate 28. When the power is supplied to the mesh electrode 17, the power supply signal is transmitted in the control substrate 33 to the LED substrate 30, and the LED substrate 30 causes the LED to emit light. As a result, the user can visually recognize a hydrogen and oxygen gas generation state by the hole 9b for LED. Pressing on the operation button 35 three times was made a condition for the power supply to the mesh electrode 17 as a safety condition to avoid unintentional button operation and power supply when the user moves with this hydrogen and oxygen gas suction tool 100 put in a pocket or the like.
The mesh electrodes 17 are disposed upward in a pair of two electrodes in parallel longitudinally, each forming positive/negative electrodes and corresponding to power from the positive/negative poles of the battery 36. Moreover, an upper end of the mesh electrode 17 has a shape cut out diagonally so as to correspond to a boundary line between the reduced diameter portion 45 and a water storage body portion 46 of the electrolysis tank 10. To a lower end of the mesh electrode 17, a rod-shaped titanium electrode 16 is connected so as to stand upright on a terminal substrate 28 and can be electrically connected thereto. In order to shield the mesh electrode 17 and the terminal substrate 28 from water in a state where the mesh electrode 17 stands upright, a packing 13 (made of a resin such as silicone) to be attached on the terminal substrate 28 and an O-ring (made of resin such as silicone: hereinafter the same applies to the O-ring) attached around the titanium electrode 16 are provided.
The electrolysis tank 10 is a container for storing water, the reduced diameter portion 45 and the water storage body portion 46 are integrally formed in order from below, and they are fluidically connected to each other therein. The water storage body portion 46 is opened upward so that water can be poured in and is half-closed by attaching an electrolysis tank lid 12. The electrolysis tank lid 12 penetrates vertically, and a penetrating opening 12a for receiving an umbrella valve 23, a screw cap 14 and the like is provided. In the water storage body portion 46, an outer side portion 46a forms a side wall substantially flat in the lateral direction from an upper end to a lower end as illustrated in
Moreover, the reduced diameter portion 45 is thinner than the water storage body portion 46 as described above, and the upper end of the outer side portion 46a on the side wall side is continuously connected as it is to the lower end of the outer side portion 46a of the water storage body portion 46 and extends to the lower end as illustrated in
Moreover, at a connection position between the lower end of the outer side portion 46a of the water storage body portion 46 and the upper end of the outer side portion 46a of the reduced diameter portion 45, a water shielding plate 45d inclined substantially the same as the bottom portion 46c of the water storage body portion 46 and extending to an opening 45c is provided. This water shielding plate 45d extends inside the whole region in a perpendicular direction on the drawing in
Moreover, when the water storage amount decreases to some degree, too, the air layer can be generated in the reduced diameter portion 45 if this hydrogen and oxygen gas suction tool 100 is inclined or placed horizontally, but in the case of this electrolysis tank 10, water is fully filled in the reduced diameter portion 45 even in this case. More specifically, in the case of inclination in the left direction on the drawing in
An upper end edge of the mesh electrode 17 is formed by being cut out diagonally so that the electrode is immersed in water in the reduced diameter portion 45 without a gap by following the shapes of the reduced diameter portion 45 and the opening 45c. Returning to
The umbrella valve 23 and the like attached to the penetrating opening 12a of the electrolysis tank lid 12 on the upper end of the electrolysis tank 10 will be described. To the penetrating opening 12a, the screw cap 14 having an opening on an upper part and penetrating vertically is attached, and at that time, a vent filter 18 is interposed between a hole in the bottom portion of the screw cap 14 and the bottom portion of the penetrating opening 12a, and the O-ring 21 is inserted into the periphery on a lower part of the screw cap 14. The vent filter 18 is a micro hole and has a function of preventing water/dusts while adjusting an internal pressure in the opening of the screw cap 14. Moreover, the O-ring 21 shields a space between an outer peripheral wall of the opening in the screw cap 14 and an inner peripheral wall of the penetrating opening 12a from water.
Moreover, the umbrella valve 23 (made of a material having flexibility such as silicone) operating in the up-and-down direction is attached in the opening of the screw cap 14, and when the user suctions through the nozzle 5 (which will be described later), and a negative pressure acts upward, the umbrella valve 23 is raised/operated and is fluidically connected to the inside of the electrolysis tank 10 through a through hole in the bottom portion of the screw cap 14 and the penetrating opening 12a of the electrolysis tank lid 12. Therefore, when the user suctions through the nozzle 5, the hydrogen or oxygen gas raised and collecting in the electrolysis tank 10 is emitted to an outside. On the contrary, if the user stops suctioning, and a state in which the negative pressure does not act is brought about, the umbrella valve 23 is lowered/operated, the through hole in the bottom portion of the screw cap 14 is closed, and the emission of the hydrogen or oxygen gas in the electrolysis tank 10 is closed.
To the electrolysis tank lid 12 to which the screw cap 14 and the umbrella valve 23 are attached, a mixer 2 is attached from above. The mixer 2 has a cylindrical member 2a extending downward as illustrated in
Fixation of the mixer 2 and the electrolysis tank lid 12 is accomplished by attaching lock buttons 3 and 4. The lock buttons 3 and 4 are sandwiched and snap-fastened in a front-and-rear direction (the perpendicular direction on the drawing in
Subsequently, an aromatic heater portion 32 for generating an aromatic air will be described.
First, a contact terminal 37 of the battery 36 is inserted into the upper-end opening of the battery receiving portion 43 of the body cover 1. The contact terminal 37 is formed by connecting a bottom portion of a large-diameter cylinder and an upper part of a small-diameter cylinder, the bottom portion is inserted into the opening in the upper end of the battery receiving portion 43, and power from the battery 36 is supplied to the aromatic heater portion 32. The contact terminal 37 is fastened to a joint 8 from above by cross recessed flat head screws 39. The joint 8 is formed by connecting the bottom portion and the upper part having a large diameter and a substantially disk shape of the small-diameter cylinder, and the upper part of the contact terminal 37 and the bottom portion of the joint 8 are fitted in a nested state.
The aromatic heater member 32 is placed on an upper surface of the joint 8, and when the mixer 2 described above is to be attached, it is sandwiched by the joint 8 and the mixer 2 and is fixed to the body cover 1. The aromatic heater member 32 is a general-purpose device, and when power is supplied, an air with aroma is generated therein and is emitted upward. Moreover, a cylindrical member 2c extending downward in parallel with the cylindrical member 2a described above is provided on the mixer 2, and an upper end of the aromatic heater portion 32 is connected to this cylindrical member 2c. Therefore, the air with aroma emitted from the aromatic heater portion 32 passes through the cylindrical member 2c as indicated by the arrow in
The nozzle 5 has a structure in which a large diameter and substantially disk-shaped member on the bottom portion and the cylindrical member on the upper part are integrally connected, and the bottom portion is attached onto the opening in the top surface fluidically connected to the cylindrical member 2c of the heater portion 32 in the mixer 2. As a result, the hydrogen or oxygen gas from the channel 2b and/or the air with aroma from the cylindrical member 2c are emitted from inside the nozzle 5 to the outside of the upper end. The O-ring 22 is disposed on the connection portion between the bottom portion of the nozzle 5 and the mixer 2 and sealed.
Moreover, the aromatic heater portion 32 controls power supply from the battery 36 by the control substrate 33. As described above, the power to the mesh electrode 17 is supplied for the predetermined time by pressing on the button 35 attached to the body cover 1 three times. On the other hand, by holding down the button, the contact terminal 37 is connected under a condition that the power supply signal to the mesh electrode 17 is not transmitted in the control substrate 33, and the power from the battery 36 is supplied to the aromatic heater portion 32 for the predetermined time.
Therefore, by pressing on the button 35 three times, when the user suctions through the nozzle 5, the hydrogen or oxygen gas is emitted from the nozzle 5, and hydrogen or oxygen gas suctioning can be enjoyed for the predetermined time (while the LED substrate 30 emits light), and by holding down the button 35 while the hydrogen or oxygen gas is emitted, the hydrogen or oxygen gas with aroma can be enjoyed.
The “configuration excluding the partition member and the opening/closing means” has been described above. Subsequently, the “configuration of the partition member and the opening/closing means” in the electrolysis tank 10 of the electrolytic hydrogen and oxygen gas suction tool of the present invention will be described by using
The partition member 50 is integrated with and connected to the reduced diameter portion 45 on an inner side surface in a longitudinal direction (front side and depth side in the drawing) and is a plate-shaped member extending downward from the upper part of the reduced diameter portion 45 without being connected to the bottom surface so as to divide the opening 45c. The partition member 50 is configured by the material similar to the reduced diameter portion 45 not transmitting a liquid or a gas. The opening 45c is divided into two openings, that is, an opening 45c1 and an opening 45c2 by the partition member 50, through which only hydrogen or oxygen generated from the electrodes below, respectively, passes, and moreover, it is selectively opened/closed by the opening/closing means which will be described later, whereby passage of either one of hydrogen and oxygen or both is made possible as the entire opening 45c.
In the partition member, shapes of the upper part of the reduced diameter portion 45 and the openings 45c1 and 45c2 can be configured arbitrarily, and an upper end of the partition member and the upper part of the reduced diameter portion 45 may be integrated and form a surface including two opening holes (45c1, 45c2).
Subsequently, movement of hydrogen and oxygen in
Subsequently, the opening/closing means 52 for selectively obtaining hydrogen and oxygen will be described by using
The distance d′1 of the opening/closing means 52 satisfies d′1<d1+d2+d3, d′1>d1+d3, and d′1>d2+d3, and the distance d′2 satisfies d′2<d5 and d′2>d4. By means of this configuration, selection of hydrogen and oxygen is made possible as illustrated in
Assuming the use situation of the electrolytic hydrogen and oxygen gas suction tool of the present invention, setting that the opening 45c1 (45c2) on the oxygen side is closed (state in which the operation switch 56 is slid to the left in the case of
Subsequently, by using
As described above, the opening/closing means 52, the upper part of the reduced diameter portion 45, and the opening 45 have been described, but it is only necessary that the two openings 45c1 and 45c2 can be selectively opened/closed other than the examples illustrated in the figures and description, and shapes and locations of the opening of 58 in the opening/closing means 52, the shape and mechanism of the operation switch 56, the shape of the upper part of the reduced diameter portion 45, and the shape and location of the opening 45 can be widely generalized and employed.
Moreover, the operation switch 56 protrudes toward the outside (side surface of the body) of the reduced diameter portion 45 in the examples in
Moreover, for the hydrogen and oxygen gas suction tool of the second invention, configuration having the polarity inverting means (polarity inversion circuit) by which hydrogen or oxygen can be taken in without using the opening/closing means can be considered. Exemplification/description will be made below.
More specifically, an embodiment of the hydrogen and oxygen gas suction tool of the second invention is illustrated as a variation in
As illustrated in
Moreover,
As described above, when the polarities of the electrodes 17a and 17b are inverted by the polarity inversion circuit, hydrogen and oxygen generated from each of the electrodes 17a and 17b are switched, and by keeping on closing either of the openings 45c1 and 45c2, the gas emitted to above the electrolysis tank 10 is also either one of hydrogen or oxygen.
The change from
Subsequently, the polarity inversion circuit will be described.
The polarity inversion circuit in
More specifically, in the state in
Moreover,
The switch of the polarity inversion circuit in
The embodiments of the hydrogen and oxygen gas suction tool of the present invention have been exemplified/described, but the present invention is not limited to them, and those skilled in the art can understand that other modifications and improvement examples can be obtained within a range not departing from the sprit or teaching described in the appended claims and description and the like.
According to the electrolytic hydrogen and oxygen gas suction tool of the present invention, in a charging type so that the user can freely carry, though the battery is small-sized and inexpensive, a space for incorporating the battery is ensured, water shielding between the electrolysis tank and the battery is ensured, and moreover, a sufficient amount of hydrogen gas generated can be ensured even if it is inclined in a state where a moisture in the electrolysis tank is decreased.
100 electrolytic hydrogen and oxygen gas suction tool
1 body cover
2 mixer
13 hydrogen passing member
13
a film material (breathable impermeable material)
14 ample portion
15 lid member
16 metal material
17 container body portion
18 aqueous solution
19 closing member
20 hydrogen
22 non-reaction portion
24 metal particle layer
40 projecting shaped portion
41 thin portion
50 partition member
52 opening/closing means
53 closing plate
54 shielding portion
56 operation switch
58 opening
60 rotating shaft
100, 200 hydrogen and oxygen gas suction tool
102 suction tool body portion
104 suctioning sheath portion
105 cap member
106, 206 connection portion
108, 208 mouth member
110, 210 film packing
112 control valve
113, 213 window
114 adjustment port
116 cartridge
117, 217 gap
118 O-ring
Number | Date | Country | Kind |
---|---|---|---|
2017-029446 | Feb 2017 | JP | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2018/005632 | 2/19/2018 | WO | 00 |