CN215103585U - Oxyhydrogen gas and hydrogen-rich water all-in-one - Google Patents

Abstract

The utility model provides an integrated machine of oxyhydrogen gas and hydrogen-rich water, which comprises a main water tank, an auxiliary water tank, a water-gas separator, an electrolytic tank, a control module and a power module; the main water tank is communicated with the auxiliary water tank, the water-gas separator and the water outlet through a three-way joint; the auxiliary water tank is communicated with a water inlet, a water outlet and a water-oxygen mixing outlet of the electrolytic bath; a first electromagnetic valve is arranged on a communication pipe between a hydrogen outlet of the electrolytic cell and the water-gas separator, a second electromagnetic valve is arranged on a communication pipe between the hydrogen outlet of the electrolytic cell and the main water tank, a third electromagnetic valve is arranged on a communication pipe between the auxiliary water tank and the oxygen outlet, a fourth electromagnetic valve is arranged on a communication pipe between a top outlet of the auxiliary water tank and the hydrogen outlet, a fifth electromagnetic valve is arranged on a communication pipe between the auxiliary water tank and the tee joint, and the first electromagnetic valve, the second electromagnetic valve, the third electromagnetic valve, the fourth electromagnetic valve and the fifth electromagnetic valve are all connected with the control module. The utility model discloses convenient operation, the function is various.

Description

Oxyhydrogen gas and hydrogen-rich water all-in-one

Technical Field

The utility model relates to a hydrogen preparation field especially relates to a oxyhydrogen gas and hydrogen-rich water all-in-one.

Background

With the rapid development of social economy, health problems are more and more emphasized by people. From a biological point of view, the human body is composed of cells, various diseases of the human body can be finally attributed to the damage of the cells, and the aging of the human body is also caused by the oxidative aging or necrosis of the cells. The primary cause of cellular morbidity or aging in humans is excess oxygen free radicals. It has been confirmed by the research of japanese medical experts that hydrogen gas helps human body to keep healthy because hydrogen has an ideal antioxidant ability to neutralize and carry away malignant radicals in human body. Meanwhile, active hydrogen can catalyze the in vivo production of more enzymes, stimulate the self-repair mechanism of the body, repair some gene proteins, improve metabolism, even restore the due functions of organs, and improve the health state of the human body. The hydrogen taken by human body has various modes such as directly breathing hydrogen or drinking hydrogen-rich water. The existing machines on the market are hydrogen absorbers or hydrogen-rich water machines, the existing hydrogen absorbers are often provided with water circulating pumps, and the water circulating pumps have the defects of high noise, short service life and the like; the existing hydrogen-rich water machine can only be used for preparing hydrogen-rich water and cannot be used for breathing hydrogen, the function is single, and the selectivity of a user is not large.

SUMMERY OF THE UTILITY MODEL

In view of the above prior art's shortcoming, the utility model aims to provide an oxyhydrogen gas and hydrogen-rich water all-in-one for there is the noise big, the life-span is low, the function singleness scheduling problem in hydrogen absorption machine or the hydrogen-rich water machine of solving among the prior art.

In order to achieve the above objects and other related objects, the utility model provides an integrated machine of oxyhydrogen gas and hydrogen-rich water, which comprises a main water tank, an auxiliary water tank, a water-gas separator, an electrolytic bath, a control module and a power module; the integrated oxyhydrogen gas and hydrogen-rich water machine is provided with an oxygen outlet, a hydrogen outlet and a hydrogen-rich water outlet; the main water tank is communicated with the auxiliary water tank, the water-gas separator and the water outlet through a three-way joint, and is also communicated with a hydrogen-rich water outlet and a water supplementing source; the auxiliary water tank is communicated with a water inlet, a water outlet and a water-oxygen mixing outlet of the electrolytic bath, and an outlet at the top of the auxiliary water tank is communicated with the oxygen outlet and the hydrogen outlet; the hydrogen outlet of the electrolytic cell is communicated with the water-gas separator and the main water tank; a first electromagnetic valve is arranged on a communication pipeline between a hydrogen outlet of the electrolytic cell and the water-gas separator, a second electromagnetic valve is arranged on a communication pipeline between the hydrogen outlet of the electrolytic cell and the main water tank, a third electromagnetic valve is arranged on a communication pipeline between the auxiliary water tank and the oxygen outlet, a fourth electromagnetic valve is arranged on a communication pipeline between a top outlet of the auxiliary water tank and the hydrogen outlet, a fifth electromagnetic valve is arranged on a communication pipeline between the auxiliary water tank and the tee joint, the first electromagnetic valve, the second electromagnetic valve, the third electromagnetic valve, the fourth electromagnetic valve and the fifth electromagnetic valve are all connected with the control module, and the control module and the positive and negative poles of the electrolytic cell are connected with the power module.

Oxyhydrogen gas and hydrogen-rich water all-in-one still include the air bubble stone, is located in the main water tank, the hydrogen outlet of electrolysis trough with the air bubble stone is linked together, the second solenoid valve set up in the hydrogen outlet of electrolysis trough with communicating pipe between the air bubble stone is on the way.

The main water tank comprises a water tank cover, a filter and a water adding pump, the water tank cover, the water adding pump and the filter are of an integrated structure, water supplemented by a water supplementing source enters the main water tank through the water adding pump and the filter, and the water adding pump is connected with the control module.

And liquid level sensors are arranged in the main water tank and/or the auxiliary water tank and are connected with the control module.

The lowest liquid level of the auxiliary water tank is lower than that of the main water tank.

The auxiliary water tank is positioned above the electrolytic bath.

Still be provided with hydrogen content sensor and/or TDS sensor in the main water tank, hydrogen content sensor and/or TDS sensor with control module is connected.

The oxyhydrogen gas and hydrogen-rich water all-in-one still includes button and display module, the button with display module with control module is connected.

The oxyhydrogen gas and hydrogen-rich water all-in-one still includes pressure sensor, pressure sensor set up with the pipeline that the hydrogen outlet of electrolysis trough and/or water oxygen mix export and be linked together, just pressure sensor with control module is connected.

Still be provided with the slope sensor on oxyhydrogen gas and the hydrogen-rich water all-in-one, the slope sensor with control module is connected.

As above, the utility model discloses an on oxyhydrogen gas and hydrogen-rich water all-in-one, have following beneficial effect: the utility model discloses a structure design of the gaseous and hydrogen-rich water all-in-one of oxyhydrogen through the improvement, the function is abundanter for the user can select oxygen, hydrogen, oxyhydrogen mist and hydrogen-rich water according to self needs, can fully satisfy user's variety demand, and the sense is experienced in the reinforcing. And the whole device has simple structure and very convenient operation.

Drawings

Fig. 1 is a schematic structural diagram of an integrated oxyhydrogen gas and hydrogen-rich water machine according to an embodiment of the present invention.

FIG. 2 shows a schematic view of the cell of FIG. 1 in an exemplary embodiment.

Fig. 3 shows an exemplary work flow chart of the oxyhydrogen gas and hydrogen-rich water all-in-one machine provided by the present invention.

Description of the element reference numerals

1 Main Water tank

2 auxiliary water tank

3 moisture separator

4 electrolytic cell

401 water inlet

402 hydrogen outlet

403 water and oxygen mixing outlet

404 positive pole ear

405 negative pole utmost point ear

5 Power supply module

6 control module

7 air bubble stone

8 TDS sensor

Liquid level sensor under 9

10 first solenoid valve

11 second solenoid valve

12 power interface and switch module

13 oxygen outlet

14 hydrogen outlet

15 hydrogen-rich water outlet

16 key and display module

17,18 three-way joint

19,20 water discharge outlet

21 water adding pump

22 upper liquid level sensor

23 third solenoid valve

24 fourth solenoid valve

25,26 pressure sensor

27 Filter

28 water tank cover

29 hydrogen content sensor

30 pipeline liquid level sensor

31 fifth solenoid valve

32 electrolytic tank water inlet pipe

33 electrolytic bath oxygen outlet and water pipe

34 hydrogen outlet pipe of electrolytic cell

35 auxiliary water tank level sensor

Detailed Description

The following description is provided for illustrative purposes, and other advantages and features of the present invention will become apparent to those skilled in the art from the following detailed description.

Please refer to fig. 1 to 3. It should be understood that the structure, ratio, size and the like shown in the drawings attached to the present specification are only used for matching with the content disclosed in the specification, so as to be known and read by those skilled in the art, and are not used for limiting the limit conditions that the present invention can be implemented, so that the present invention has no technical essential meaning, and any structure modification, ratio relationship change or size adjustment should still fall within the scope covered by the technical content disclosed in the present invention without affecting the function and the achievable purpose of the present invention. Meanwhile, the terms such as "upper", "lower", "left", "right", "middle" and "one" used in the present specification are for convenience of description, and are not intended to limit the scope of the present invention, and changes or adjustments of the relative relationship thereof may be made without substantial technical changes.

As shown in fig. 1 to 2, the utility model provides an integrated machine of oxyhydrogen gas and hydrogen-rich water, which comprises a main water tank 1, an auxiliary water tank 2, a water-gas separator 3, an electrolytic tank 4, a control module 6 and a power module 5; the integrated machine of oxyhydrogen gas and hydrogen-rich water generally comprises a shell (not marked), wherein an oxygen outlet 13, a hydrogen outlet 14 and a hydrogen-rich water outlet 15 are arranged on the shell, the main water tank 1, the auxiliary water tank 2, the water-gas separator 3, the electrolytic bath 4, the control module 6 and the power module 5 can be positioned or partially positioned in the shell, the main water tank 1, the auxiliary water tank 2 and the water-gas separator 3 are respectively provided with corresponding water storage tanks, and the main water tank 1, the auxiliary water tank 2, the water-gas separator 3, internal pipelines and other components are made of food-grade materials; the main water tank 1 is communicated with the auxiliary water tank 2, the moisture separator 3 and a water outlet (the water outlet here can comprise a water outlet 20 on the main water tank 1 and on the casing) through a three-way joint (the three-way joint can be multiple, such as a three-way joint 17 and a three-way joint 18 marked in fig. 1), and the main water tank 1 is also communicated with a hydrogen-rich water outlet 15 and a water supplementing source (not shown), wherein the water supplementing source is preferably a pure water source; the auxiliary water tank 2 is communicated with the water inlet, the water outlet 19 and the water-oxygen mixed outlet of the electrolytic bath 4, for example, the bottom of the auxiliary water tank 2 is communicated with the water inlet and the water outlet 19 of the electrolytic bath 4 through an electrolytic bath water inlet pipe 32, and the middle upper part of the auxiliary water tank 2 is communicated with the water-oxygen mixed outlet of the electrolytic bath 4 through an electrolytic bath oxygen outlet and water pipe 33; the top outlet of the auxiliary water tank 2 is communicated with the oxygen outlet 13 and the hydrogen outlet 14; a hydrogen outlet of the electrolytic cell 4 is communicated with the water-gas separator 3 and the main water tank 1; a first electromagnetic valve 10 is arranged on a communication pipeline (namely an electrolyzer hydrogen outlet pipe 34 in figure 1) between the hydrogen outlet of the electrolyzer 4 and the water-gas separator 3, a second electromagnetic valve 11 is arranged on a communication pipeline between the hydrogen outlet of the electrolytic cell 4 and the main water tank 1, a third electromagnetic valve 23 is arranged on a communication pipeline between the auxiliary water tank 2 and the oxygen outlet 13, a fourth electromagnetic valve 24 is arranged on a communication pipeline between the top outlet of the auxiliary water tank 2 and the hydrogen outlet 14, a fifth electromagnetic valve 31 is arranged on a communication pipeline between the auxiliary water tank 2 and the three-way joint, the first solenoid valve 10, the second solenoid valve 11, the third solenoid valve 23, the fourth solenoid valve 24 and the fifth solenoid valve 31 are all connected with the control module 6, the control module 6 and the anode and the cathode of the electrolytic bath 4 are connected with the power module 5.

The utility model discloses a multiple functions such as oxygen, breathing hydrogen, breathing oxyhydrogen mist and drinking hydrogen rich water have been assembled to oxyhydrogen gas and hydrogen rich water all-in-one, and the user can select corresponding function according to self needs. This exemplary operation is as follows:

1. hydrogen and oxygen evolution modes

The machine is set to default to a hydrogen and oxygen outlet mode, and after the machine is started, the first electromagnetic valve 10 and the third electromagnetic valve 23 are opened, and the second electromagnetic valve 11 and the fourth electromagnetic valve 24 are closed. After the electrolytic tank 4 starts to electrolyze water, hydrogen flows out of the electrolytic tank 4 and enters the water-gas separator 3 through a pipeline, the hydrogen flows out of the water-gas separator 3 and is discharged from the hydrogen outlet 14, oxygen flows out of the electrolytic tank 4 and enters the auxiliary water tank 2 through a pipeline, the oxygen flows out of the auxiliary water tank 2 and is discharged from the oxygen outlet 13 through the third electromagnetic valve 23, and a user can breathe hydrogen or oxygen only by inserting a breathing pipe into the hydrogen outlet 14 or the oxygen outlet 13 of the machine.

2. Oxygen-hydrogen mixed gas outlet mode

After the start-up, the user selects the hydrogen-oxygen mixed gas mode through the control module 6, the first electromagnetic valve 10 and the fourth electromagnetic valve 24 are opened, and the second electromagnetic valve 11 and the third electromagnetic valve 23 are closed. After the electrolytic tank 4 starts to electrolyze water, oxygen flows out of the electrolytic tank 4 and enters the auxiliary water tank 2 through a pipeline, the oxygen flows out of the auxiliary water tank 2 and then passes through the fourth electromagnetic valve 24, then the oxygen and the hydrogen are mixed at the hydrogen outlet of the water-gas separator 3, the mixed hydrogen-oxygen mixed gas is discharged from the hydrogen outlet 14 on the machine, and a user can breathe the hydrogen-oxygen mixed gas only by inserting a breathing pipe into the hydrogen outlet 14 of the machine.

3. Hydrogen rich water mode

After the power-on, the user selects the hydrogen-rich water mode through the control module 6, the second electromagnetic valve 11 and the third electromagnetic valve 23 are opened, and the first electromagnetic valve 10 and the fourth electromagnetic valve 24 are closed. After the electrolytic tank 4 starts to electrolyze water, hydrogen is communicated with the main water tank 1 through the second electromagnetic valve 11 after coming out from the electrolytic tank 4, and after the hydrogen-rich water is made, a user can drink the hydrogen-rich water by opening the hydrogen-rich water outlet 15 (the user can drink the hydrogen-rich water by opening the hydrogen-rich water outlet 15 after the machine is opened for a preset time or by information given by the control module 6, which will be described later).

The utility model discloses a structure design of the gaseous and hydrogen-rich water all-in-one of oxyhydrogen through the improvement, the function is abundanter for the user can select oxygen, hydrogen, oxyhydrogen mist and hydrogen-rich water according to self needs, can fully satisfy user's variety demand, and the sense is experienced in the reinforcing. And the whole device has simple structure and very convenient operation.

By way of example, the control module 6 includes, but is not limited to, a PLC controller, and the power module 5 is a dc power output module that outputs a dc current or a dc voltage to act on the electrolytic cell 4; the oxyhydrogen gas and hydrogen-rich water all-in-one machine can also further comprise a power interface and a switch module 12 which are electrically connected with the power module 5 so as to control the on-off of the power supply.

As an example, the integrated oxyhydrogen gas and hydrogen-rich water machine further comprises a bubbled stone 7 positioned in the main water tank 1, the hydrogen outlet of the electrolytic cell 4 is communicated with the bubbled stone 7, and the second electromagnetic valve 11 is arranged on a communication pipeline between the hydrogen outlet of the electrolytic cell 4 and the bubbled stone 7. Through setting up air pocket stone 7, can beat hydrogen into nanometer bubble and water fully contact to make the hydrogen distribution of aquatic more even, improve the hydrogen-rich water's of preparation quality.

As an example, the main water tank 1 includes a water tank cover 28, a filter 27 and a water adding pump 21, the water tank cover 28, the water adding pump 21 and the filter 27 are preferably an integral structure, water supplemented by a water supplementing source enters the main water tank 1 through the water adding pump 21 and the filter 27, and the water adding pump 21 is connected with the control module 6. Water enters the main water tank 1 after being filtered by the filter 27, so that the purity of pure water is improved, the trouble of manual water adding is solved, and on the other hand, the filter 27, the water adding pump 21 and the water tank cover 28 are integrated, so that the space for installing the filter 27 is saved.

As an example, a liquid level sensor is arranged in each of the main tank 1 and the auxiliary tank 2 to detect the liquid level in the corresponding tank in real time, and the liquid level sensor is connected with the control module 6. For example, an upper liquid level sensor 22 located at the upper part and a lower liquid level sensor 9 located at the lower part may be arranged in the main water tank 1 (the upper part and the lower part are a relative concept, for example, measured by whether the height of the main water tank 1 is one-half higher), an auxiliary water tank liquid level sensor 35 is arranged at the bottom of the auxiliary water tank 2, the upper liquid level sensor 22, the lower liquid level sensor 9 and the auxiliary water tank liquid level sensor 35 of the main water tank 1 are all connected with the control module 6, when the water levels in the main water tank 1 and the auxiliary water tank 2 are lower than a preset value, the control module 6 may start a water replenishing function, for example, the water replenishing pump 21 is started to replenish water to the main water tank 1, because the main water tank 1 is communicated with the auxiliary water tank 2 through a communication pipeline, after pure water is added to the main water tank 1, water may enter the auxiliary water tank 2 through a pipeline; or the control module 6 can send out alarm information (the oxyhydrogen gas and hydrogen-rich water all-in-one machine can be provided with an alarm electrically connected with the control module 6) to remind a user of manually supplementing water, and the water is stopped when the water is higher than the upper limit water level. And a pipeline liquid level sensor 30 can be arranged on the oxygen outlet and water pipe 33 of the electrolytic cell.

As an example, the lowest liquid level of the subtank 2 is lower than the lowest liquid level of the main tank 1, for example, the bottom surface of the main tank 1 is higher than the bottom surface of the subtank 2, so that a part of water remains at the bottom of the subtank 2 after the water in the main tank 1 is completely discharged, so as to ensure that the electrolytic bath 4 does not lack water during operation.

By way of example, the auxiliary water tank 2 is positioned above the electrolytic bath 4, or at least the connection port between the auxiliary water tank 2 and the electrolytic bath 4 is ensured to be higher than the upper surface of the electrolytic bath 4, so that water in the auxiliary water tank 2 can flow automatically to enter the water inlet of the electrolytic bath 4 through a pipeline and then flow out through the water-oxygen mixing outlet, a water circulating pump can be omitted, parts needing maintenance are reduced, noise of a machine is reduced, and cost of the system is reduced.

In an example, a hydrogen content sensor 29 is further disposed in the main water tank 1 to detect the hydrogen content in the water, and the hydrogen content sensor 29 is connected to the control module 6 to stop supplying hydrogen to the main water tank 1 and/or send a prompt message when the hydrogen content in the water in the main water tank 1 reaches a preset value, so as to remind a user that the hydrogen-rich water is completely produced and the user can drink the hydrogen-rich water by opening the hydrogen-rich water outlet 15.

In an example, a TDS (Total dispersed Solids, chinese translation name is Total Dissolved Solids) sensor 8 is further disposed in the main water tank 1 to detect the Dissolved Solids content in the water in real time, and the TDS sensor 8 is connected to the control module 6, so that when the Dissolved Solids content in the water is detected to exceed a standard, the control module 6 controls the power module 5 to be turned off, and prompts a user to replace purified water or a filter. In other examples, the hydrogen content sensor 29 and the TDS sensor 8 may also be provided simultaneously.

As an example, the oxyhydrogen gas and hydrogen-rich water all-in-one machine further includes a key and display module 16 for a user to select a desired function by pressing a key, the key and display module 16 is connected to the control module 6, and the key and display module 16 includes but is not limited to a touch screen.

As an example, the oxyhydrogen gas and hydrogen-rich water all-in-one machine further comprises a pressure sensor, the pressure sensor is arranged on a pipeline communicated with the hydrogen outlet and/or the water-oxygen mixing outlet of the electrolytic cell 4, for example, a pressure sensor 25 and a pressure sensor 26 are respectively arranged on a hydrogen outlet pipe 34 of the electrolytic cell and an oxygen outlet and water pipe 33 of the electrolytic cell, so as to detect the pressure in the corresponding pipeline in real time and monitor whether the inside of the corresponding pipeline is blocked, and the pressure sensor is connected with the control module 6. When excessive pressure is detected, the machine can be stopped and an alarm can be given.

As an example, an inclination sensor is further arranged on the oxyhydrogen gas and hydrogen-rich water all-in-one machine to detect whether the machine is inclined or not, so that water in the auxiliary water tank 2 and the water-gas separator 3 can be prevented from flowing out through pipelines when the machine is toppled, and the inclination sensor is connected with the control module 6. The oxygen outlet 13 of the auxiliary water tank 2 and the hydrogen outlet of the water-gas separator 3 can be respectively provided with air-permeable and water-impermeable materials.

The utility model discloses an electrolysis trough 4 in oxyhydrogen gas and hydrogen-rich water all-in-one can adopt common structure, and one of them structure for the sake of exemplification is shown in fig. 2, including the cell body, be located water inlet 401 on the cell body (be linked together with electrolysis trough inlet tube 32), go out hydrogen mouth 402 (be linked together with electrolysis trough play hydrogen pipe 34), water oxygen hybrid outlet 403 (be linked together with electrolysis trough play oxygen and water pipe 33), anodal utmost point ear 404 and negative pole utmost point ear 405 accessible cable are connected with 5 electricity of power module. Since the construction and the operating principle of the electrolytic cell 4 are well known to those skilled in the art, they will not be elaborated upon in detail.

In order to make the technical scheme and advantages of the utility model more outstanding, it is right to combine the attached drawing 3 below the utility model discloses a work flow of oxyhydrogen gas and hydrogen-rich water all-in-one does an exemplary description. Note that the solenoid valves 1, 2, 3, 4, and 5 in the block of fig. 3 correspond to the first solenoid valve 10, the second solenoid valve 11, the third solenoid valve 23, the fourth solenoid valve 24, and the fifth solenoid valve 31 one by one:

under the condition that the water tank cover 28, the water adding pump 21 and the filter 27 of the main water tank 1 are integrated, a pipeline is connected to an external drinking water source from the interface of the water adding pump 21 on the water tank cover 28, after a machine key is pressed down by the machine, the control module 6 is initialized, the first electromagnetic valve 10 and the third electromagnetic valve 23 are opened by default, the second electromagnetic valve 11, the fourth electromagnetic valve 24 and the fifth electromagnetic valve 31 are closed by default, and the power supply module 5 is closed; if the machine is detected to be inclined, the control module 6 gives an alarm and turns off the power supply module 5, and if the machine is not inclined, the control module 6 automatically selects whether to supplement water according to the water level information in the main water tank 1; for example, when the control module 6 detects a water shortage state according to the lower liquid level sensor 9, the water adding pump 21 is started to add water into the main water tank 1, and the water enters the water tank through the filter 27 to play a role in purifying water; when the control module 6 detects that the upper liquid level sensor 22 is in a water-lack state, the water adding pump 21 automatically stops adding water; after the main water tank 1 is filled with water, the control module 6 controls whether to open the fifth electromagnetic valve 31 according to the state of the liquid level sensor 35 of the auxiliary water tank 2, when the control module 6 detects that the auxiliary water tank 2 is in a water shortage state, the fifth electromagnetic valve 31 is opened, water in the main water tank 1 enters the auxiliary water tank 2 and the water-gas separator 3 through the bottom communicating pipeline, water in the auxiliary water tank 2 enters the electrolytic tank 4 through the electrolytic tank water inlet pipe 32 and comes out from the electrolytic tank oxygen outlet pipe and the water pipe 33, after a certain time, the water level in the auxiliary water tank 2 is equal to the water level in the main water tank 1, and the fifth electromagnetic valve 31 is closed; on the basis of the steps, then the control module 6 can control whether to start the power module 5 according to the state of the liquid level sensor in the pipeline, and when the control module 6 detects that oxygen is discharged from the electrolytic bath and no water exists in the water pipe 33, the control module 6 gives an alarm; when the control module 6 detects that oxygen is discharged from the electrolytic cell and water is in the water pipe 33, the power module 5 is started, and the electrolytic cell 4 starts to electrolyze water to produce hydrogen; the hydrogen gas comes out from the hydrogen outlet 14 of the electrolytic bath 4, the hydrogen gas is mixed with water and enters the water-gas separator 3 through the hydrogen outlet pipe 34 of the electrolytic bath, the water is remained in the water-gas separator 3, and the hydrogen gas is discharged from the hydrogen outlet 14. Similarly, oxygen and water are fed from the water and oxygen mixing outlet of the electrolytic cell 4 through the cell outlet oxygen and water line 33 back to the subtank 2, water is retained in the subtank 2, and oxygen is discharged from the oxygen outlet 13. If the TDS sensor 8 and/or the pressure sensor are/is provided, the control module 6 may also perform corresponding operations according to the detection results of the corresponding sensors, specifically refer to the content in fig. 3, and are not expanded one by one here.

Of course, the above-described process is merely exemplary. Depending on the differences in the specific structure of the oxyhydrogen gas and hydrogen-rich water integrated machine, the steps in the operation flow chart in fig. 3 may be omitted or adjusted, and are not described in detail.

To sum up, the utility model provides an integrated machine of oxyhydrogen gas and hydrogen-rich water, which comprises a main water tank, an auxiliary water tank, a water-gas separator, an electrolytic bath, a control module and a power module; the integrated oxyhydrogen gas and hydrogen-rich water machine is provided with an oxygen outlet, a hydrogen outlet and a hydrogen-rich water outlet; the main water tank is communicated with the auxiliary water tank, the water-gas separator and the water outlet through a three-way joint, and is also communicated with a hydrogen-rich water outlet and a water supplementing source; the auxiliary water tank is communicated with a water inlet, a water outlet and a water-oxygen mixing outlet of the electrolytic bath, and an outlet at the top of the auxiliary water tank is communicated with the oxygen outlet and the hydrogen outlet; the hydrogen outlet of the electrolytic cell is communicated with the water-gas separator and the main water tank; a first electromagnetic valve is arranged on a communication pipeline between a hydrogen outlet of the electrolytic cell and the water-gas separator, a second electromagnetic valve is arranged on a communication pipeline between the hydrogen outlet of the electrolytic cell and the main water tank, a third electromagnetic valve is arranged on a communication pipeline between the auxiliary water tank and the oxygen outlet, a fourth electromagnetic valve is arranged on a communication pipeline between a top outlet of the auxiliary water tank and the hydrogen outlet, a fifth electromagnetic valve is arranged on a communication pipeline between the auxiliary water tank and the tee joint, the first electromagnetic valve, the second electromagnetic valve, the third electromagnetic valve, the fourth electromagnetic valve and the fifth electromagnetic valve are all connected with the control module, and the control module and the positive and negative poles of the electrolytic cell are connected with the power module. The utility model discloses a structure design of the gaseous and hydrogen-rich water all-in-one of oxyhydrogen through the improvement, the function is abundanter for the user can select oxygen, hydrogen, oxyhydrogen mist and hydrogen-rich water according to self needs, can fully satisfy user's variety demand, and the sense is experienced in the reinforcing. And the whole device has simple structure and very convenient operation. Therefore, the utility model effectively overcomes various defects in the prior art and has high industrial utilization value.

The above embodiments are merely illustrative of the principles and effects of the present invention, and are not to be construed as limiting the invention. Modifications and variations can be made to the above-described embodiments by those skilled in the art without departing from the spirit and scope of the present invention. Accordingly, it is intended that all equivalent modifications or changes which may be made by those skilled in the art without departing from the spirit and technical spirit of the present invention be covered by the claims of the present invention.

Claims (10)

1. An integrated machine of oxyhydrogen gas and hydrogen-rich water is characterized by comprising a main water tank, an auxiliary water tank, a water-gas separator, an electrolytic tank, a control module and a power module; the integrated oxyhydrogen gas and hydrogen-rich water machine is provided with an oxygen outlet, a hydrogen outlet and a hydrogen-rich water outlet; the main water tank is communicated with the auxiliary water tank, the water-gas separator and the water outlet through a three-way joint, and is also communicated with a hydrogen-rich water outlet and a water supplementing source; the auxiliary water tank is communicated with a water inlet, a water outlet and a water-oxygen mixing outlet of the electrolytic bath, and an outlet at the top of the auxiliary water tank is communicated with the oxygen outlet and the hydrogen outlet; the hydrogen outlet of the electrolytic cell is communicated with the water-gas separator and the main water tank; a first electromagnetic valve is arranged on a communication pipeline between a hydrogen outlet of the electrolytic cell and the water-gas separator, a second electromagnetic valve is arranged on a communication pipeline between the hydrogen outlet of the electrolytic cell and the main water tank, a third electromagnetic valve is arranged on a communication pipeline between the auxiliary water tank and the oxygen outlet, a fourth electromagnetic valve is arranged on a communication pipeline between a top outlet of the auxiliary water tank and the hydrogen outlet, a fifth electromagnetic valve is arranged on a communication pipeline between the auxiliary water tank and the tee joint, the first electromagnetic valve, the second electromagnetic valve, the third electromagnetic valve, the fourth electromagnetic valve and the fifth electromagnetic valve are all connected with the control module, and the control module and the positive and negative poles of the electrolytic cell are connected with the power module.

2. The integrated oxyhydrogen gas and hydrogen-rich water machine according to claim 1, further comprising a bubbled stone located in the main water tank, wherein the hydrogen outlet of the electrolytic cell is connected to the bubbled stone, and the second solenoid valve is disposed on a communication pipe between the hydrogen outlet of the electrolytic cell and the bubbled stone.

3. The oxyhydrogen gas and hydrogen-rich water all-in-one machine according to claim 1, wherein the main water tank comprises a water tank cover, a filter and a water adding pump, the water tank cover, the water adding pump and the filter are of an integrated structure, water supplemented by a water supplementing source enters the main water tank through the water adding pump and the filter, and the water adding pump is connected with the control module.

4. The integrated oxyhydrogen gas and hydrogen-rich water machine according to claim 1, wherein a liquid level sensor is disposed in the main tank and/or the auxiliary tank, and the liquid level sensor is connected to the control module.

5. The integrated oxyhydrogen gas and hydrogen-rich water machine according to claim 1, wherein the minimum liquid level of the secondary water tank is lower than the minimum liquid level of the primary water tank.

6. The oxyhydrogen gas, and hydrogen-rich water all-in-one machine according to claim 1, wherein the auxiliary tank is located above the electrolytic cell.

7. The oxyhydrogen gas and hydrogen-rich water all-in-one machine according to claim 1, wherein a hydrogen content sensor and/or a TDS sensor is further disposed in the main water tank, and the hydrogen content sensor and/or the TDS sensor is connected with the control module.

8. The integrated oxyhydrogen gas and hydrogen-rich water machine according to claim 1, further comprising a button and a display module, wherein the button and display module is connected to the control module.

9. The integrated oxyhydrogen gas and hydrogen-rich water machine according to claim 1, further comprising a pressure sensor disposed on a pipeline communicated with the hydrogen outlet of the electrolyzer and/or the water-oxygen mixing outlet, wherein the pressure sensor is connected to the control module.

10. The integrated oxyhydrogen gas and hydrogen-rich water machine according to claim 1, wherein an inclination sensor is further disposed on the integrated oxyhydrogen gas and hydrogen-rich water machine, and the inclination sensor is connected to the control module.

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