CN216366215U

CN216366215U - Multifunctional portable oxyhydrogen machine

Info

Publication number: CN216366215U
Application number: CN202122032258.8U
Authority: CN
Inventors: 宿金栋; 姬正桥; 陈丹; 李晶
Original assignee: Shenzhen Yuanqi Technology Co ltd
Current assignee: Shenzhen Yuanqi Technology Co ltd
Priority date: 2021-08-26
Filing date: 2021-08-26
Publication date: 2022-04-26
Anticipated expiration: 2031-08-26

Abstract

The utility model discloses a multifunctional portable oxyhydrogen machine, which comprises a shell, a water storage unit, an electrolysis unit, a gas storage unit, a heating atomization unit and a control unit, wherein the water storage unit, the electrolysis unit, the gas storage unit, the heating atomization unit and the control unit are arranged in the shell; the gas storage unit comprises an oxygen chamber and a hydrogen chamber, the electrolysis unit is respectively communicated with the oxygen chamber and the hydrogen chamber, the oxygen chamber is provided with an oxygen outlet, the hydrogen chamber is provided with a hydrogen outlet, and the heating atomization unit is provided with an atomization outlet; the multifunctional portable oxyhydrogen machine provided by the utility model separates hydrogen and oxygen generated by the electrolysis unit, and is respectively provided with the independent oxygen chamber and the independent hydrogen chamber, so that the function of buffering air pressure is realized, and the flow change of output gas is reduced; the heating atomization unit can atomize the atomized liquid to form small molecular particles, and the respiratory tract diseases are conditioned by adjusting the components of the atomized liquid, so that the atomized liquid can be mixed and inhaled while oxygen inhalation and hydrogen inhalation are realized.

Description

Multifunctional portable oxyhydrogen machine

Technical Field

The utility model relates to the technical field of medical equipment, in particular to a multifunctional portable oxyhydrogen machine.

Background

Hydrogen is the least dense of known gases, has reducing properties, is very low in atmospheric air, is expensive to extract by direct air extraction, and is generally produced by electrolysis of water. As early as 2007, the journal published by nature medicine of mazezuelan, japan proves that hydrogen has the effect of neutralizing toxic and harmful radicals such as hydroxyl radicals and nitrite anions, and modern medicine has proved that almost all chronic diseases of the human body are related to oxidative damage of free radicals, and the hydroxyl radicals are active oxygen with the strongest oxidative activity and are key factors causing oxidative damage of cells. At present, the human body actively obtains hydrogen mainly by three ways of drinking hydrogen-containing water, injecting hydrogen-containing saline water and directly sucking mixed gas of hydrogen, but the solubility of the hydrogen is only about 0.5-0.8 ppm at normal temperature and normal pressure, and the solubility of the hydrogen is only a little higher in physiological saline water. The hydrogen is required to be taken up more quickly and conveniently and is only inhaled through the lung. Most of hydrogen machines on the market at present are large in size and high in price, and the hydrogen absorbing process is tedious due to the colorless and tasteless characteristics of hydrogen, so that the hydrogen machines are prevented from being widely popularized and applied.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that the defects of the prior art are overcome, the light convenient oxyhydrogen machine is small and portable, the use is reliable and safe, 2:1 hydrogen and oxygen are obtained through an electrolysis technology, independent air chambers are arranged respectively, the inhalation amount can be adjusted according to requirements, and meanwhile, by combining the existing electronic atomization technology, the hydrogen absorption and oxygen absorption can be realized, meanwhile, atomized liquid prepared from natural plant extracts such as Chinese herbal medicines is added, the hydrogen absorption experience of a user is improved, and the hydrogen absorption process is more interesting.

The technical scheme adopted by the utility model for solving the technical problems is as follows: a multifunctional portable oxyhydrogen machine comprises a shell, a water storage unit, an electrolysis unit, a gas storage unit, a heating atomization unit and a control unit, wherein the water storage unit, the electrolysis unit, the gas storage unit, the heating atomization unit and the control unit are arranged in the shell; the gas storage unit comprises an oxygen chamber and a hydrogen chamber, the electrolysis unit is respectively communicated with the oxygen chamber and the hydrogen chamber, the oxygen chamber is provided with an oxygen outlet, the hydrogen chamber is provided with a hydrogen outlet, and the heating atomization unit is provided with an atomization outlet.

Further, preferably, the electrolysis unit comprises an electrolysis unit shell, wherein the electrolysis unit shell comprises an oxygen generation area provided with an anode sheet, a hydrogen generation area provided with a cathode sheet and a selective proton permeable membrane, and the selective proton permeable membrane separates the oxygen generation area from the hydrogen generation area.

Further, preferably, an oxygen joint is arranged at the top of the oxygen generation area, and the oxygen joint is communicated with the oxygen chamber; and a hydrogen connector is arranged at the top of the hydrogen generation area and communicated with the hydrogen chamber.

Further, it is preferable that a first gas-liquid separator is provided between the oxygen gas connector and the oxygen chamber (and a second gas-liquid separator is provided between the hydrogen gas connector and the hydrogen chamber).

Further, it is preferable that a pressure release valve is provided in both the oxygen chamber and the hydrogen chamber.

Preferably, the housing is provided with an observation tank for observing the water level of the water storage unit, and the wall surface of the water storage unit corresponding to the observation tank is of a visible structure.

Preferably, the heating and atomizing unit comprises an atomizer shell, a ceramic atomizing core is arranged in the atomizer shell, a liquid storage cavity is arranged between the atomizer shell and the ceramic atomizing core, and a heating resistance wire is attached to the ceramic atomizing core.

Preferably, the heating and atomizing unit is provided with a gas guide tube at the center, one end of the gas guide tube is communicated with the ceramic atomizing core, the other end of the gas guide tube is communicated with the suction nozzle, the smoke atomized by the heating resistance wire is guided out of the gas guide tube to the suction nozzle, and the suction nozzle extends out of the shell.

Further, preferably, an upper cover is arranged above the shell, and the upper cover is provided with three independent gas pipelines which are respectively an oxygen gas channel communicated with the oxygen outlet, a hydrogen gas channel communicated with the hydrogen outlet and an atomization gas channel communicated with the atomization outlet.

Preferably, the shell is provided with an electrolysis unit switch button, a heating atomizer switch button and a gear switch button for adjusting the flow of oxygen, hydrogen and atomized gas on the outer side.

The utility model has the following beneficial effects: the utility model provides a multifunctional portable oxyhydrogen machine, which comprises a shell, a water storage unit, an electrolysis unit, a gas storage unit, a heating atomization unit and a control unit, wherein the water storage unit, the electrolysis unit, the gas storage unit, the heating atomization unit and the control unit are arranged in the shell; the gas storage unit comprises an oxygen chamber and a hydrogen chamber, the electrolysis unit is respectively communicated with the oxygen chamber and the hydrogen chamber, the oxygen chamber is provided with an oxygen outlet, the hydrogen chamber is provided with a hydrogen outlet, and the heating atomization unit is provided with an atomization outlet; the hydrogen generated by the electrolysis unit is separated from the oxygen, and the hydrogen chamber and the oxygen chamber are respectively provided with an independent oxygen chamber and an independent hydrogen chamber, and the independent gas chambers mainly play a role in buffering air pressure and reduce the flow change of output gas; various natural plant extracts can be prepared into atomized liquid, the atomized liquid is atomized by a heating atomization unit to form small molecular particles, and the atomized liquid can be further applied to atomization conditioning of respiratory diseases by adjusting the components of the atomized liquid. When oxygen absorption and hydrogen absorption are realized, atomized liquid with taste can be selected for mixed absorption, so that the hydrogen absorption process is more interesting, and the hydrogen absorption experience of a user is improved.

Drawings

The utility model will be further described with reference to the accompanying drawings and examples, in which:

FIG. 1 is an exploded view of the multi-functional oxyhydrogen machine according to the present invention;

FIG. 2 is a right side view of the multi-functional oxyhydrogen machine according to the present invention;

FIG. 3 is a left side view of the multi-functional oxyhydrogen machine according to the present invention;

fig. 4 is a cross-sectional view of a heated atomizing unit of the present invention.

Detailed Description

For a more clear understanding of the technical features, objects and effects of the present invention, embodiments of the present invention will now be described in detail with reference to the accompanying drawings.

An element is said to be "secured to" or "disposed on" another element, either directly or indirectly on the other element. When an element is referred to as being "connected to" another element, it can be directly or indirectly connected to the other element.

The terms "upper", "lower", "left", "right", "front", "rear", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positions based on the orientations or positions shown in the drawings, and are for convenience of description only and not to be construed as limiting the technical solution. The terms "first", "second", etc. are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features. The meaning of "plurality" is two or more unless specifically limited otherwise.

As shown in fig. 1-3, a multifunctional portable oxyhydrogen machine comprises a housing 1, a water storage unit 2, an electrolysis unit 3, a gas storage unit 4, a heating and atomization unit 5 and a control unit 10, wherein the water storage unit 2, the electrolysis unit 3, the gas storage unit 4, the heating and atomization unit 5 and the control unit 10 are arranged in the housing 1, the control unit 10 is respectively electrically connected with the electrolysis unit 3 and the heating and atomization unit 5, and the electrolysis unit 3 is communicated with the water storage unit 2; the gas storage unit 4 comprises an oxygen chamber 41 and a hydrogen chamber 42, the electrolysis unit 3 is respectively communicated with the oxygen chamber 41 and the hydrogen chamber 42, the oxygen chamber 41 is provided with an oxygen outlet 411, the hydrogen chamber 42 is provided with a hydrogen outlet 421, and the heating atomization unit 5 is provided with an atomization outlet 56. The water storage unit 2 is provided with a water outlet, water in the water storage unit 2 is guided to the electrolysis unit 3, a battery of the control unit 10 provides electric energy for the electrolysis unit 3, water is electrolyzed to generate oxygen and hydrogen, the oxygen is guided to the oxygen chamber 41, the hydrogen is guided to the hydrogen chamber 42, the oxygen chamber and the hydrogen chamber are respectively provided with an independent air chamber, the air chambers mainly play a role of buffering air pressure, the flow change of output air is reduced, the oxygen buffered by the oxygen chamber 41 is guided to the outside of the shell 1 to be sucked by a user, and the hydrogen buffered by the hydrogen chamber 42 is guided to the outside of the shell 1 to be sucked by the user; various natural plant extracts can be prepared into atomized liquid, the atomized liquid is atomized by the heating atomization unit 5 to form small molecular particles for inhalation, and the atomized liquid can be further applied to atomization conditioning of respiratory diseases by adjusting the components of the atomized liquid. By using the multifunctional portable oxyhydrogen machine, oxygen inhalation and hydrogen inhalation are realized, and meanwhile, atomized liquid with taste can be selected for mixing and inhalation, so that more choices are provided for the process of inhalation, and the experience of users is improved.

In some embodiments, the electrolysis unit 3 comprises an electrolysis unit 3 housing, the electrolysis unit 3 housing comprising an oxygen generation zone provided with an anode sheet, a hydrogen generation zone provided with a cathode sheet, and a selective proton permeable membrane separating the oxygen generation zone from the hydrogen generation zone; the top of the oxygen generation area is provided with an oxygen joint 31, and the oxygen joint 31 is communicated with the oxygen chamber 41; the top of the hydrogen generation area is provided with a hydrogen connector 32, and the hydrogen connector 32 is communicated with the hydrogen chamber 42; a first gas-liquid separator 6 is provided between the oxygen gas joint 31 and the oxygen chamber 41, and a second gas-liquid separator 7 is provided between the hydrogen gas joint 32 and the hydrogen chamber 42. When the oxygen and the hydrogen generated by the electrolysis of the electrolysis unit 3 are conveyed outwards, the oxygen and the hydrogen respectively pass through the first gas-liquid separator 6 and the second gas-liquid separator 7, the mixed moisture flows back to the electrolysis unit 3, and the dry hydrogen and the oxygen are obtained through gas-liquid separation, so that the experience of a user is improved.

In some embodiments, a pressure relief valve 8 is disposed in each of the oxygen chamber 41 and the hydrogen chamber 42. When the oxygen and hydrogen generated by the electrolysis unit 3 reach a certain degree, the pressure in the oxygen chamber 41 and the hydrogen chamber 42 is gradually increased, when the pressure in the oxygen chamber 41 and the hydrogen chamber 42 is too high, the pressure release valve 8 is automatically opened to release the pressure, and the redundant gas is discharged out of the oxyhydrogen machine through the pressure release valve 8.

In some embodiments, the casing 1 is provided with the observation tank 11 for observing the water level of the water storage unit 2, the wall surface of the water storage unit 2 corresponding to the observation tank 11 is of a visual structure, the water level condition in the water storage unit 2 is observed through the observation tank 11, when the water amount of the water storage unit 2 is consumed to a certain degree, the water can be timely supplemented to the water storage unit 2, and the phenomenon that the oxyhydrogen machine cannot normally work due to the fact that the water supply of the electrolysis unit 3 cannot be timely performed due to the fact that the water storage unit 2 is short of water is avoided.

In some embodiments, the heating and atomizing unit 5 includes an atomizer housing 51, a ceramic atomizing core 52 is disposed in the atomizer housing 51, a liquid storage cavity 53 is disposed between the atomizer housing 51 and the ceramic atomizing core 52, and a heating resistance wire 54 is attached to the ceramic atomizing core 52; when the heating atomizer works, atomized liquid is stored in the liquid storage cavity 53, the ceramic atomizing core 52 conducts the liquid, and the heating resistance wire 54 emits heat to atomize the atomized liquid in the ceramic atomizing core 52 to form atomized steam.

In some embodiments, as shown in fig. 4, the center of the heating and atomizing unit 5 is provided with an air duct 55, one end of the air duct 55 is communicated with the ceramic atomizing core 52, the other end of the air duct 55 is communicated with the suction nozzle, the smoke atomized by the heating resistance wire 54 is guided out of the air duct 55 to the suction nozzle, the smoke atomized by the heating resistance wire 54 extending out of the housing 1 enters the air duct 55, the smoke passes through the suction nozzle and is output to the oxyhydrogen machine, and the user can inhale atomized steam at the suction nozzle.

In some embodiments, the upper cover 12 is disposed above the housing 1, the upper cover 12 is provided with three independent gas pipelines, which are respectively an oxygen gas channel communicated with the oxygen outlet 411, a hydrogen gas channel communicated with the hydrogen outlet 421, and an atomization gas channel communicated with the atomization outlet 56, and the oxygen, the hydrogen, and the atomization steam all have independent gas pipelines, so that the user can select oxygen, or hydrogen, or atomization steam according to the needs of the user.

In some embodiments, the outer side of the shell 1 is provided with an electrolysis unit switch button 13, a heating atomization unit switch button 14 and a gear switch button 15 for regulating the flow of oxygen, hydrogen and atomization gas; the electrolysis unit 3 can be in an electrolysis state or the electrolysis unit 3 can be in a non-electrolysis state by pressing the switch button 13 of the electrolysis unit; the heating and atomizing unit 5 can enter an atomizing state or the heating and atomizing unit 5 can enter a non-atomizing state by pressing the heating and atomizing switch button; and gas flow regulating valves are arranged at the outlets of the hydrogen outlet 421, the oxygen outlet 411 and the atomization outlet 56, the gas flow regulating valves are connected with the gear switch button 15, and the gas flow of the oxygen, the hydrogen and the atomized steam can be regulated by pressing the gear switch button 15.

Claims

1. The multifunctional portable oxyhydrogen machine is characterized by comprising a shell (1), a water storage unit (2), an electrolysis unit (3), a gas storage unit (4), a heating atomization unit (5) and a control unit (10), wherein the water storage unit (2), the electrolysis unit (3), the gas storage unit (4), the heating atomization unit (5) and the control unit (10) are arranged in the shell (1), the control unit (10) is electrically connected with the electrolysis unit (3) and the heating atomization unit (5) respectively, and the electrolysis unit (3) is communicated with the water storage unit (2); the gas storage unit (4) includes oxygen chamber (41) and hydrogen chamber (42), electrolysis unit (3) respectively with oxygen chamber (41) hydrogen chamber (42) switch on, oxygen chamber (41) are provided with oxygen export (411), hydrogen chamber (42) set up hydrogen export (421), heating atomizing unit (5) are provided with atomizing export (56).

2. The portable multifunctional oxyhydrogen machine according to claim 1, characterized in that the electrolysis unit (3) comprises an electrolysis unit housing including therein an oxygen generation zone provided with an anode sheet, a hydrogen generation zone provided with a cathode sheet, and a selective proton permeable membrane separating the oxygen generation zone from the hydrogen generation zone.

3. The portable multifunctional oxyhydrogen machine according to claim 2, wherein an oxygen connector (31) is provided on top of the oxygen generation area, the oxygen connector (31) is communicated with the oxygen chamber (41); the top of the hydrogen generation area is provided with a hydrogen connector (32), and the hydrogen connector (32) is communicated with the hydrogen chamber (42).

4. The portable multifunctional oxyhydrogen machine according to claim 3, characterized in that a first gas-liquid separator (6) is provided between the oxygen connector (31) and the oxygen chamber (41), and a second gas-liquid separator (7) is provided between the hydrogen connector (32) and the hydrogen chamber (42).

5. The portable multifunctional oxyhydrogen machine according to claim 1, characterized in that a pressure relief valve (8) is provided in each of the oxygen chamber (41) and the hydrogen chamber (42).

6. The portable multifunctional oxyhydrogen machine according to claim 1, wherein the housing (1) is provided with an observation tank (11) for observing the water level of the water storage unit (2), and the wall surface of the water storage unit (2) corresponding to the observation tank (11) is of a visible structure.

7. The multifunctional portable oxyhydrogen machine according to claim 1, characterized in that the heating atomization unit (5) comprises an atomizer housing (51), a ceramic atomization core (52) is arranged in the atomizer housing (51), a liquid storage cavity (53) is arranged between the atomizer housing (51) and the ceramic atomization core (52), and a heating resistance wire (54) is attached on the ceramic atomization core (52).

8. The multifunctional portable oxyhydrogen machine according to claim 7, characterized in that a gas guide tube (55) is arranged in the center of the heating atomization unit (5), one end of the gas guide tube (55) is communicated with the ceramic atomization core (52), the other end is communicated with an atomization outlet (56), the smoke atomized by the heating resistance wire (54) is guided out of the gas guide tube (55) to the atomization outlet (56), and the atomization outlet (56) extends out of the housing (1).

9. The portable multifunctional oxyhydrogen machine according to claim 1, characterized in that an upper cover (12) is disposed above the housing (1), and the upper cover (12) is provided with three independent gas pipes, namely an oxygen gas pipe communicated with the oxygen outlet (411), a hydrogen gas pipe communicated with the hydrogen outlet (421), and an atomization gas pipe communicated with the atomization outlet (56).

10. The portable oxyhydrogen machine according to claim 1, characterized in that the electrolysis unit switch button (13), the heating atomizer switch button (14) and the shift switch button (15) for adjusting the flow of oxygen, hydrogen and atomizing gas are provided outside the housing (1).