CN213048783U - Portable oxyhydrogen breathing machine - Google Patents

Abstract

The utility model discloses a portable oxyhydrogen breathing machine, which comprises a shell, wherein a water storage container, a hydrogen generator and a gas-water separator for separating hydrogen from water are arranged in the shell; the shell is provided with a water inlet joint and a gas outlet joint; the water storage container is provided with a water inlet and a water outlet; the water inlet of the water storage container is communicated with the water inlet joint; the hydrogen generator is provided with an electrolyzed water input port, an oxygen output port and a hydrogen output port; the electrolyzed water inlet is communicated with the water outlet of the water storage container through a pipeline; the gas-water separator is arranged in the water storage container and comprises a hydrogen inlet and a hydrogen outlet; the hydrogen inlet of the gas-water separator is communicated with the hydrogen outlet of the hydrogen generator, and the hydrogen outlet of the gas-water separator is communicated with the gas outlet joint through a hydrogen output pipe. The utility model has the characteristics of convenient to carry, compact structure, rationally distributed, output hydrogen purity is high, furtherly, it can also export hydrogen-containing water or oxyhydrogen mist.

Description

Portable oxyhydrogen breathing machine

Technical Field

The utility model relates to a oxyhydrogen machine, concretely relates to portable oxyhydrogen breathing machine.

Background

Scientific research shows that almost all chronic diseases of a human body are closely related to free radical oxidative damage, hydrogen-rich water and hydrogen are indispensable molecules in the life process of people, the permeability of hydrogen molecules is high, and the hydrogen molecules can permeate into each cell of the human body to play the roles of resisting oxidation, eliminating fatigue and reducing diseases.

The utility model discloses a patent application number is 201920208596.2's utility model discloses an automatic balance water level, automatically regulated temperature's oxyhydrogen generator, including the generator casing, inside front one side of generator casing is fixed with main water tank and cylinder water tank respectively, the top of main water tank is provided with temperature sensor and water tank gas vent respectively, the side middle part of main water tank is provided with oxygen backward flow mouth and water level balance mouth one respectively, the side bottom of main water tank is provided with the water tank outlet, the top of cylinder water tank is provided with the hydrogen delivery outlet, the side of cylinder water tank is provided with hydrogen backward flow mouth and water level balance mouth two respectively, inside back one side of generator casing is fixed with the hydrogen generator power respectively, main power supply and hydrogen generator body, the below of hydrogen generator power is provided with the cooling cycle body. The device solves the problem that the traditional hydrogen machine can not run for a long time due to high temperature by arranging the main water tank, the cylindrical water tank, the temperature sensor and the high-temperature exhaust fan; however, the problem of water content in hydrogen is not solved, the defect of low hydrogen purity exists, and a main water tank and a cylindrical water tank are required to be adopted, so that the structure is complex.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defects of the prior art, the utility model aims to provide a portable oxyhydrogen breathing machine, which has the characteristics of convenient carrying, compact structure, reasonable layout and high purity of output hydrogen, and further can output hydrogen-containing water or oxyhydrogen mixed gas.

The purpose of the utility model is realized by adopting the following technical scheme:

a portable oxyhydrogen breathing machine comprises a shell, and is characterized in that a water storage container, a hydrogen generator and a gas-water separator for separating hydrogen from water are arranged in the shell;

the shell is provided with a water inlet joint and a gas outlet joint;

the water storage container is provided with a water inlet and a water outlet; the water inlet of the water storage container is communicated with the water inlet joint;

the hydrogen generator is provided with an electrolyzed water input port, an oxygen output port and a hydrogen output port; the electrolyzed water inlet is communicated with the water outlet of the water storage container through a pipeline;

the gas-water separator is arranged in the water storage container and comprises a hydrogen inlet and a hydrogen outlet; the hydrogen inlet of the gas-water separator is communicated with the hydrogen outlet of the hydrogen generator, and the hydrogen outlet of the gas-water separator is communicated with the gas outlet joint through a hydrogen output pipe.

In an optional implementation manner, the hydrogen-containing water supply device further comprises a water inlet pipe, a water pump, a first water outlet pipe, a second water outlet pipe, an electromagnetic valve B and an electromagnetic valve C which are respectively arranged in the shell, and a hydrogen-containing water output connector arranged on the shell; the electromagnetic valve B is a two-position three-way electromagnetic valve and comprises an input end, a first output end and a second output end; the electromagnetic valve C is a two-position three-way electromagnetic valve and comprises an input end, a first output end and a second output end;

the input end of the electromagnetic valve B is communicated with the hydrogen outlet of the gas-water separator through the hydrogen output pipe, the first output end of the electromagnetic valve B is communicated with the gas outlet joint through a pipeline, and the second output end of the electromagnetic valve B is communicated with the water inlet pipe;

the water inlet connector is connected with the water inlet end of the water pump through the water inlet pipe, the water outlet end of the water pump is communicated with the input end of the electromagnetic valve C through the first water outlet pipe, the first output end of the electromagnetic valve C is communicated with the water inlet of the water storage container through the second water outlet pipe, and the second output end of the electromagnetic valve C is communicated with the hydrogen-containing water output connector through a pipeline.

In an optional embodiment, the oxygen supply device further comprises a first oxygen delivery pipe, a second oxygen delivery pipe, a third oxygen delivery pipe and a solenoid valve a which are respectively arranged in the shell, and an oxygen output joint arranged on the shell; the electromagnetic valve A is a two-position three-way electromagnetic valve and comprises an input end, a first output end and a second output end;

the inlet end of the first oxygen conveying pipe is communicated with the oxygen outlet of the hydrogen generator, the outlet end of the first oxygen conveying pipe is communicated with the input end of the electromagnetic valve A, the first output end of the electromagnetic valve A is communicated with the hydrogen output pipe through the second oxygen conveying pipe, and the second output end of the electromagnetic valve A is communicated with the oxygen output joint through the third oxygen conveying pipe.

In an optional embodiment, the hydrogen generator is further provided with an electrolyzed water output port, and the water storage container is further provided with a water return port; the electrolyzed water output port is communicated with the water return port of the water storage container through an electrolyzed water output pipe, and the electrolyzed water input port is communicated with the water outlet of the water storage container through an electrolyzed water input pipe.

In an alternative embodiment, the hydrogen generator comprises an anode plate and a cathode plate, wherein the anode plate and the cathode plate are enclosed to form an electrolytic chamber, an anode power supply body, a cathode power supply body and an ionic membrane are arranged in the electrolytic chamber, and the ionic membrane is arranged between the anode power supply body and the cathode power supply body and is used for dividing the electrolytic chamber into an anode chamber and a cathode chamber; the electrolytic water input port, the electrolytic water output port and the oxygen output port are respectively arranged on the anode chamber, and the hydrogen output port is arranged on the cathode chamber.

In an optional embodiment, the device further comprises a first water pressure balance pipe communicated with the water storage container and a second water pressure balance pipe communicated with a water outlet of the gas-water separator; the first water pressure balancing pipe is communicated with the second water pressure balancing pipe through a pipeline.

In an optional embodiment, the water storage container is a water tank, the water tank comprises a water tank body with an accommodating cavity and a water tank cover, and the water tank body and the water tank cover are fixedly connected in a detachable mode; and a sealing ring is also arranged between the water tank body and the water tank cover. The sealing ring plays a sealing role so as to prevent the water tank from leaking water and air.

In an alternative embodiment, the hydrogen generator is disposed below the water tank.

In an optional implementation manner, the side wall of the housing is further provided with a plurality of heat dissipation holes, and a fan is further installed on the inner side wall of the housing at a position corresponding to the heat dissipation holes, and the fan is located on one side of the hydrogen generator.

In an optional embodiment, a water level sensor is further disposed in the water storage container.

Compared with the prior art, the beneficial effects of the utility model reside in that:

1. the utility model discloses a portable oxyhydrogen breathing machine includes the casing, is equipped with water container, hydrogen generator in the casing to and be used for the deareator with hydrogen and separation of water, the deareator sets up in water container. When the hydrogen-water separator is used, when hydrogen comes out of the hydrogen generator, a small amount of moisture is separated by the gas-water separator, and the hydrogen with the moisture removed is discharged from a hydrogen outlet of the gas-water separator, a hydrogen output pipe and an air outlet joint. Therefore, the utility model has the characteristics of convenient to carry, compact structure, rationally distributed, output hydrogen purity is high.

2. The utility model also comprises a water inlet pipe, a water pump, a first water outlet pipe, a second water outlet pipe, a solenoid valve B and a solenoid valve C which are respectively arranged in the shell, and a hydrogen-containing water output joint arranged on the shell; through switching over water pump, solenoid valve B and solenoid valve C, can select output hydrogen or hydrogen-containing water, both can carry out cosmetic moisturizing with hydrogen water, also can inhale hydrogen, and the function is various.

3. The utility model also comprises a first oxygen conveying pipe, a second oxygen conveying pipe, a third oxygen conveying pipe and a solenoid valve A which are respectively arranged in the shell; hydrogen, hydrogen-containing water or hydrogen-oxygen mixed gas can be selectively output by switching the water pump, the electromagnetic valve A, the electromagnetic valve B and the electromagnetic valve C; in addition, through control solenoid valve A, can also select output oxygen, the function is more various.

4. The hydrogen generator of the utility model is also provided with an electrolyzed water outlet, and the water storage container is also provided with a water return port; the electrolyzed water output port is communicated with the water return port of the water storage container through the electrolyzed water output pipe, and the electrolyzed water input port is communicated with the water outlet of the water storage container through the electrolyzed water input pipe, so that the design can recycle water resources and save energy.

5. The utility model also comprises a first water pressure balance pipe communicated with the water storage container and a second water pressure balance pipe communicated with the water outlet of the gas-water separator; the first water pressure balance pipe is communicated with the second water pressure balance pipe through a pipeline; the design can keep the pressure balance of the water tank and the gas-water separator.

Drawings

FIG. 1 is a perspective view of a portable oxyhydrogen breathing apparatus according to an embodiment;

FIG. 2 is a perspective view of the portable oxyhydrogen breathing apparatus with the housing removed according to the embodiment;

FIG. 3 is a schematic structural view of a water tank of the embodiment;

FIG. 4 is a block diagram of the piping connections of the embodiment.

In the figure: 10. a housing; 11. a water inlet joint; 12. an air outlet joint; 13. a hydrogen-containing water output connector; 14. an oxygen output connector; 15. heat dissipation holes; 20. a water storage container; 21. a water inlet; 22. a water outlet; 23. a water return port; 30. a hydrogen generator; 31. an electrolyzed water inlet; 311. an electrolyzed water input pipe; 32. an oxygen outlet; 33. a hydrogen gas outlet; 34. an electrolyzed water outlet; 341. an electrolyzed water output pipe; 40. a gas-water separator; 41. a hydrogen inlet; 42. a hydrogen outlet; 51. a water inlet pipe; 52. a water pump; 53. a first water outlet pipe; 54. a second water outlet pipe; 55. a solenoid valve B; 56. a solenoid valve C; 57. a hydrogen gas output pipe; 61. a first oxygen delivery pipe; 62. a second oxygen delivery pipe; 63. a third oxygen delivery tube; 64. an electromagnetic valve A; 71. a first hydraulic balance pipe; 72. a second hydraulic balance pipe; 80. a fan.

Detailed description of the preferred embodiments

The present invention will be further described with reference to the accompanying drawings and specific embodiments, and it should be noted that the embodiments or technical features described below can be arbitrarily combined to form a new embodiment without conflict. Except as specifically noted, the materials and equipment used in this example are commercially available. Examples of embodiments are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary only for the purpose of explaining the present application and are not to be construed as limiting the present application.

In the description of the present application, it is to be understood that the terms "upper", "lower", "front", "back", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present application and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present application. In the description of the present application, "a plurality" means two or more unless specifically stated otherwise.

In the description of the present application, it should be noted that unless otherwise specifically stated or limited, the terms "connected," "communicating," and "connected" are to be construed broadly, e.g., as meaning a fixed connection, a connection through an intervening medium, a connection between two elements, or an interaction between two elements. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art as appropriate.

The terms "first," "second," and the like in the description and in the claims of the present application and in the above-described drawings are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. Furthermore, the terms "comprises," "comprising," and "having," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed, but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

Example (b):

referring to fig. 1-4, a portable oxyhydrogen breathing machine comprises a housing 10, a water storage container 20, a hydrogen generator 30, and a gas-water separator 40 for separating hydrogen from water are arranged in the housing 10;

the shell 10 is provided with a water inlet joint 11 and an air outlet joint 12;

the water storage container 20 is provided with a water inlet 21 and a water outlet 22; the water inlet 21 of the water storage container 20 is communicated with the water inlet joint 11;

the hydrogen generator 30 is provided with an electrolyzed water inlet 31, an oxygen outlet 32 and a hydrogen outlet 33; the electrolyzed water inlet 31 is communicated with the water outlet 22 of the water storage container 20 through a pipeline;

the gas-water separator 40 is arranged in the water storage container 20, and the gas-water separator 40 comprises a hydrogen inlet 41 and a hydrogen outlet 42; the hydrogen inlet 41 of the gas-water separator 40 is communicated with the hydrogen outlet 33 of the hydrogen generator 30, and the hydrogen outlet 42 of the gas-water separator 40 is communicated with the gas outlet joint 12 through the hydrogen outlet pipe 57.

In the above embodiment, when the hydrogen gas is discharged from the hydrogen generator 30, a small amount of moisture is separated by the gas-water separator 40, and the hydrogen gas with moisture removed is discharged from the hydrogen outlet 42 of the gas-water separator 40, the hydrogen gas output pipe, and finally the outlet joint 12, so as to obtain high-purity hydrogen gas.

In the preferred embodiment of the present invention, the portable oxyhydrogen breathing apparatus further includes a water inlet pipe 51, a water pump 52, a first water outlet pipe 53, a second water outlet pipe 54, a solenoid valve B55 and a solenoid valve C56 respectively disposed in the housing 10, and a hydrogen-containing water output connector 13 disposed on the housing 10; the electromagnetic valve B is a two-position three-way electromagnetic valve and comprises an input end, a first output end and a second output end; the electromagnetic valve C is a two-position three-way electromagnetic valve and comprises an input end, a first output end and a second output end; the input end of the electromagnetic valve B is communicated with the hydrogen outlet 42 of the gas-water separator 40 through a hydrogen output pipe 57, the first output end of the electromagnetic valve B is communicated with the gas outlet joint 12 through a pipeline, and the second output end of the electromagnetic valve B is communicated with the water inlet pipe 51; the water inlet joint 11 is connected with the water inlet end of the water pump 52 through the water inlet pipe 51, the water outlet end of the water pump 52 is communicated with the input end of the electromagnetic valve C through the first water outlet pipe 53, the first output end of the electromagnetic valve C is communicated with the water inlet 21 of the water storage container 20 through the second water outlet pipe 54, and the second output end of the electromagnetic valve C is communicated with the hydrogen-containing water output joint 13 through a pipeline.

When water needs to be pumped into the water tank, the electromagnetic valve C is switched to the following states: the second output end of the electromagnetic valve C is closed, and the first output end of the electromagnetic valve C is opened, so that the first output end of the electromagnetic valve C is communicated with the water tank; the water pump 52 is blocked, and water enters the water storage container 20 through the water inlet pipe 51, the water pump 52, the first water outlet pipe 53, the electromagnetic valve C and the second water outlet pipe 54 in sequence;

when it is necessary to output hydrogen, the water pump 52 is turned off, while the solenoid valve B is switched to the following state: the second output end of the electromagnetic valve B is closed, and the first output end of the electromagnetic valve B is opened, so that the first output end of the electromagnetic valve B is communicated with the air outlet joint 12; when the hydrogen comes out of the hydrogen generator 30, a small amount of moisture is separated by the gas-water separator 40, and the hydrogen with moisture removed is discharged from the hydrogen outlet 42 of the gas-water separator 40, the hydrogen output pipe and the gas outlet joint 12 to obtain high-purity hydrogen;

when the hydrogen-containing water needs to be output, the water pump 52 is turned on, and the solenoid valve B is switched to the following states: the first output end of the electromagnetic valve B is closed, and the second output end of the electromagnetic valve B is opened, so that the second output end of the electromagnetic valve B is communicated with the water inlet pipe 51; at the same time, solenoid valve C is switched to the following state: the first output end of the electromagnetic valve C is closed, and the second output end of the electromagnetic valve C is opened, so that the second output end of the electromagnetic valve C is communicated with the hydrogen-containing water output joint 13; when the hydrogen comes out from the hydrogen generator 30, a small amount of moisture is separated by the gas-water separator 40, the hydrogen with the moisture removed enters the water inlet pipe 51 from the hydrogen outlet 42 of the gas-water separator 40 and the hydrogen output pipe to form hydrogen-containing water, the hydrogen-containing water passes through the water pump 52, the first water outlet pipe 53 and the electromagnetic valve C in sequence, and is finally discharged from the hydrogen-containing water output connector 13 to obtain the hydrogen-containing water.

In the preferred embodiment of the present invention, the portable oxyhydrogen breathing apparatus further comprises a first oxygen delivery pipe 61, a second oxygen delivery pipe 62, a third oxygen delivery pipe 63, a solenoid valve a64, and an oxygen output joint 14 disposed on the housing 10, respectively disposed in the housing 10; the electromagnetic valve A is a two-position three-way electromagnetic valve and comprises an input end, a first output end and a second output end; the first oxygen delivery pipe 61 has an air inlet end communicated with the oxygen outlet 32 of the hydrogen generator 30, an air outlet end communicated with the input end of the solenoid valve a, a first output end communicated with the hydrogen output pipe through the second oxygen delivery pipe 62, and a second output end communicated with the oxygen output joint 14 through the third oxygen delivery pipe 63.

When the mixed gas of hydrogen and oxygen is required to be output, the water pump 52 is closed, and the electromagnetic valve B is switched to the following states: the second output end of the electromagnetic valve B is closed, and the first output end of the electromagnetic valve B is opened, so that the first output end of the electromagnetic valve B is communicated with the air outlet joint 12; at the same time, solenoid valve a is switched to the following state: the second output end of the electromagnetic valve A is closed, and the first output end of the electromagnetic valve A is opened, so that the first output end of the electromagnetic valve A is communicated with the hydrogen output pipe through a second oxygen conveying pipe 62; when the hydrogen comes out from the hydrogen generator 30, a small amount of moisture is separated by the gas-water separator 40, the hydrogen with the moisture removed enters the hydrogen output pipe from the hydrogen outlet 42 of the gas-water separator 40, the oxygen passes through the first oxygen conveying pipe 61, the electromagnetic valve A and the second oxygen conveying pipe 62 after coming out from the hydrogen generator 30, enters the hydrogen output pipe to be mixed with the hydrogen to form hydrogen-oxygen mixed gas, and finally the hydrogen-oxygen mixed gas is discharged from the gas outlet joint 12 to obtain hydrogen-oxygen mixed gas.

When oxygen output is required, the water pump 52 is turned off, and the solenoid valve a is switched to the following state: the first output end of the electromagnetic valve A is closed, and the second output end of the electromagnetic valve A is opened, so that the second output end of the electromagnetic valve A is communicated with the oxygen output joint 14 through a third oxygen conveying pipe 63; after the oxygen comes out from the hydrogen generator 30, the oxygen passes through the first oxygen delivery pipe 61, the electromagnetic valve a and the third oxygen delivery pipe 63 in sequence, and finally is discharged from the oxygen output joint 14 to obtain the oxygen.

In this embodiment, when obtaining hydrogen and hydrogen-containing water, it is only necessary to switch the electromagnetic valve a to the state of outputting oxygen from the oxygen output connector 14, and other modes are the same as the above modes, and are not described herein again.

In the preferred embodiment of the present invention, the hydrogen generator 30 is further provided with an electrolyzed water outlet 34, and the water storage container 20 is further provided with a water return port 23; the electrolyzed water output port 34 is communicated with the water return port 23 of the water storage container 20 through an electrolyzed water output pipe 341, and the electrolyzed water input port 31 is communicated with the water outlet port 22 of the water storage container 20 through an electrolyzed water input pipe 311. The design can cyclic utilization water resource, the energy saving.

In the preferred embodiment of the present invention, the hydrogen generator 30 comprises an anode plate and a cathode plate, the anode plate and the cathode plate form an electrolysis chamber, the electrolysis chamber is provided with an anode power supply, a cathode power supply, and an ionic membrane disposed between the anode power supply and the cathode power supply, the ionic membrane is used for separating the electrolysis chamber into an anode chamber and a cathode chamber; an electrolyzed water inlet 31, an electrolyzed water outlet 34, and an oxygen outlet 32 are provided in the anode chamber, and a hydrogen outlet 33 is provided in the cathode chamber. The gas-water separator 40 is of conventional construction in the art for separating hydrogen from water.

In the preferred embodiment of the present invention, the present invention further comprises a first water pressure balance pipe 71 communicated with the water storage container 20 and a second water pressure balance pipe 72 communicated with the water inlet and outlet of the gas-water separator 40; the first water pressure balancing pipe 71 and the second water pressure balancing pipe 72 are communicated through a pipeline. This design can maintain the pressure balance between the water tank and the gas-water separator 40.

In the preferred embodiment of the present invention, the water storage container 20 is a water tank, the water tank includes a water tank body having a containing cavity and a water tank cover, and the water tank body and the water tank cover are fixedly connected in a detachable manner, specifically, they can be connected by a buckle or a screw; a sealing ring is arranged between the water tank body and the water tank cover. The sealing ring plays a sealing role so as to prevent the water tank from leaking water and air. The hydrogen generator 30 is disposed below the water tank.

In order to make the heat after the atomization give off to the environment fast, in the preferred embodiment of the present invention, the sidewall of the casing 10 is further provided with a plurality of heat dissipation holes 15, the inner sidewall of the casing 10 is further provided with a fan 80 at a position corresponding to the heat dissipation holes 15, and the fan 80 is located at one side of the hydrogen generator 30.

In this embodiment, the electric vehicle further includes a power supply, the power supply may be implemented by a battery, the battery may be a common battery or a rechargeable battery, and of course, the electric vehicle may also be charged by an external charging circuit, which is similar to an electric vehicle. The power supply can adopt a 12V direct current power supply, and when the hydrogen generator 30, the water pump 52 or the fan 80 is powered, the required voltage of the hydrogen generator 30, the water pump 52 or the fan 80 can be met through a voltage conversion circuit such as a voltage boosting circuit or a voltage reducing circuit, so as to supply power for the hydrogen generator 30, the water pump 52 or the fan 80.

In the preferred embodiment of the present invention, a water level sensor is further disposed in the water storage container 20. The shell 10 is further provided with a control panel, the control panel comprises a controller, and the controller is electrically connected with the water pump 52, the electromagnetic valve A, the electromagnetic valve B, the electromagnetic valve C and the water level sensor respectively; when the controller receives that the liquid level information collected by the water level sensor is smaller than the preset liquid level threshold value, a high level signal is sent to the water pump 52, and the water pump 52 is opened, so that water is injected into the water tank.

Other examples are as follows:

the gas-water separator may be a gravity separator or a circulation separator, or a separator having a hydrophobic and gas-permeable membrane may be used. The specific materials and the sizes of the shell, the water tank, the hydrogen generator and the gas-water separator can be correspondingly adjusted according to the actual situation. While only certain features and embodiments of the application have been illustrated and described, many modifications and changes may occur to those skilled in the art (e.g., variations in sizes, dimensions, structures, shapes and proportions of the various elements, mounting arrangements, use of materials, colors, orientations, etc.) without materially departing from the scope and spirit of the invention in the claims.

Finally, it should be noted that: the above embodiments are only preferred embodiments of the present invention, and the protection scope of the present invention cannot be limited thereby, and any insubstantial changes and substitutions made by those skilled in the art based on the present invention are all within the protection scope of the present invention.

Claims (10)

1. A portable oxyhydrogen breathing machine comprises a shell, and is characterized in that a water storage container, a hydrogen generator and a gas-water separator for separating hydrogen from water are arranged in the shell;

the shell is provided with a water inlet joint and a gas outlet joint;

the water storage container is provided with a water inlet and a water outlet; the water inlet of the water storage container is communicated with the water inlet joint;

the hydrogen generator is provided with an electrolyzed water input port, an oxygen output port and a hydrogen output port; the electrolyzed water inlet is communicated with the water outlet of the water storage container through a pipeline;

the gas-water separator is arranged in the water storage container and comprises a hydrogen inlet and a hydrogen outlet; the hydrogen inlet of the gas-water separator is communicated with the hydrogen outlet of the hydrogen generator, and the hydrogen outlet of the gas-water separator is communicated with the gas outlet joint through a hydrogen output pipe.

2. The portable oxyhydrogen breathing machine according to claim 1, further comprising a water inlet pipe, a water pump, a first water outlet pipe, a second water outlet pipe, an electromagnetic valve B and an electromagnetic valve C which are respectively arranged in the shell, and a hydrogen-containing water output connector arranged on the shell; the electromagnetic valve B is a two-position three-way electromagnetic valve and comprises an input end, a first output end and a second output end; the electromagnetic valve C is a two-position three-way electromagnetic valve and comprises an input end, a first output end and a second output end;

the input end of the electromagnetic valve B is communicated with the hydrogen outlet of the gas-water separator through the hydrogen output pipe, the first output end of the electromagnetic valve B is communicated with the gas outlet joint through a pipeline, and the second output end of the electromagnetic valve B is communicated with the water inlet pipe;

the water inlet connector is connected with the water inlet end of the water pump through the water inlet pipe, the water outlet end of the water pump is communicated with the input end of the electromagnetic valve C through the first water outlet pipe, the first output end of the electromagnetic valve C is communicated with the water inlet of the water storage container through the second water outlet pipe, and the second output end of the electromagnetic valve C is communicated with the hydrogen-containing water output connector through a pipeline.

3. The portable oxyhydrogen breathing machine according to claim 2, further comprising a first oxygen delivery pipe, a second oxygen delivery pipe, a third oxygen delivery pipe, a solenoid valve A and an oxygen output joint arranged on the housing, which are respectively arranged in the housing; the electromagnetic valve A is a two-position three-way electromagnetic valve and comprises an input end, a first output end and a second output end;

the inlet end of the first oxygen conveying pipe is communicated with the oxygen outlet of the hydrogen generator, the outlet end of the first oxygen conveying pipe is communicated with the input end of the electromagnetic valve A, the first output end of the electromagnetic valve A is communicated with the hydrogen output pipe through the second oxygen conveying pipe, and the second output end of the electromagnetic valve A is communicated with the oxygen output joint through the third oxygen conveying pipe.

4. The portable oxyhydrogen breathing machine according to claim 1, wherein the hydrogen generator is further provided with an electrolyzed water outlet, and the water storage container is further provided with a water return port; the electrolyzed water output port is communicated with the water return port of the water storage container through an electrolyzed water output pipe, and the electrolyzed water input port is communicated with the water outlet of the water storage container through an electrolyzed water input pipe.

5. The portable oxyhydrogen breathing machine according to claim 4, wherein the hydrogen generator comprises an anode plate and a cathode plate, the anode plate and the cathode plate are enclosed to form an electrolysis chamber, an anode power supply, a cathode power supply and an ionic membrane arranged between the anode power supply and the cathode power supply are arranged in the electrolysis chamber, and the ionic membrane is used for dividing the electrolysis chamber into an anode chamber and a cathode chamber; the electrolytic water input port, the electrolytic water output port and the oxygen output port are respectively arranged on the anode chamber, and the hydrogen output port is arranged on the cathode chamber.

6. The portable oxyhydrogen breathing machine according to claim 1, further comprising a first water pressure balance pipe communicated with the water storage container and a second water pressure balance pipe communicated with the water outlet of the gas-water separator; the first water pressure balancing pipe is communicated with the second water pressure balancing pipe through a pipeline.

7. The portable oxyhydrogen breathing machine according to claim 1, wherein the water storage container is a water tank, the water tank comprises a water tank body with a containing cavity and a water tank cover, and the water tank body and the water tank cover are fixedly connected in a detachable manner; and a sealing ring is also arranged between the water tank body and the water tank cover.

8. The portable oxyhydrogen breathing machine according to claim 7, wherein the hydrogen generator is disposed below the water tank.

9. The portable oxyhydrogen breathing machine according to claim 1, wherein a plurality of heat dissipation holes are further formed on the side wall of the housing, and a fan is further installed on the inner side wall of the housing at a position corresponding to the heat dissipation holes and located at one side of the hydrogen generator.

10. The portable oxyhydrogen breathing machine according to claim 1, wherein a water level sensor is further arranged in the water storage container.

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