Hydrogen-rich water preparation system
Technical Field
The utility model relates to the technical field of hydrogen-rich water preparation, in particular to a hydrogen-rich water preparation system.
Background
The hydrogen-rich water can eliminate malignant oxygen free radicals in human bodies, prevent various diseases and promote human health, and has the following effects: (1) activating human cells, delaying aging, and removing harmful substances in cell membranes or blood vessels; (2) enhancing immunity and improving cell activity; (3) promoting digestion and excretion functions, softening blood vessels, activating mucosal cells, promoting intestinal peristalsis, facilitating excretion, and preventing and improving constipation; (4) the permeability is strong, and the product can penetrate into tissues such as vascular endothelial space, remove precipitate, activate cell tissue, dredge blood vessels, and improve blood circulation function; (5) improving gastrointestinal function, promoting blood circulation and metabolism, maintaining endocrine balance, and promoting lipodieresis.
In addition, the hydrogen-rich water has effects of preventing and treating diabetes, cardiovascular and cerebrovascular diseases, rheumatism, brain tumor, dermatogic disease, headache, giddiness, blood circulation disorder, kidney disease, female climacteric syndrome, infantile eczema, bronchus, thyroid gland, insomnia, epilepsy, anaphylaxis, and also has effects of caring skin, reducing weight and resisting aging.
The existing hydrogen-rich water production method mainly comprises the following steps: (1) the hydrogen rod or the hydrogen porcelain is put into water to react with water to directly form hydrogen-rich water, but the hydrogen-rich water formed by the method has low concentration and is easy to consume, and the hydrogen rod or the hydrogen porcelain mainly comprises chemical substances such as magnesium, aluminum and the like, so that a human body can ingest a large amount of trace elements to be harmful to the body; (2) hydrogen is directly injected into water through a high-pressure hydrogen tank to form hydrogen-rich water, but the method has high danger coefficient and is not easy to operate; (3) hydrogen gas is filled into bags or bottles, which is advantageous for drinking but not for long-term storage. The hydrogen-rich water prepared by the method has low hydrogen content and short dissolving time.
Disclosure of Invention
An object of the present invention is to provide a hydrogen-rich water production system that can produce a high-concentration hydrogen-rich water.
In order to solve the technical problems, the technical scheme adopted by the utility model specifically comprises the following contents:
a hydrogen-rich water preparation system, includes hydrogen generator, nanometer bubble generator and the hydrogen melter that communicates in proper order, hydrogen generator is used for generating hydrogen and with the hydrogen transmission who generates extremely nanometer bubble generator, nanometer bubble generator utilizes the hydrogen of receipt to generate nanometer hydrogen bubble and with the nanometer hydrogen bubble transmission who generates extremely the hydrogen melter, the hydrogen melter utilizes the nanometer hydrogen bubble of receipt to form hydrogen-rich water.
Preferably, the hydrogen generator comprises a pure water tank, an electrolytic tank, a water pump, a water quality detector arranged in the electrolytic tank, a water quality detection control plate electrically connected with the water quality detector, a water level detector arranged in the pure water tank and an electrolytic power supply electrically connected with an electrolytic module of the electrolytic tank, wherein the water quality detection control plate is electrically connected with the electrolytic power supply; two ends of the water pump are respectively communicated with the water outlet of the pure water tank and the water inlet of the electrolytic bath; the water return port of the pure water tank is communicated with the water return port of the electrolytic cell, and the gas outlet of the electrolytic cell is communicated with the gas inlet of the nano bubble generator.
Preferably, the hydrogen generator further comprises an automatic water adding system, the automatic water adding system comprises a pure water device electrically connected with the water level detector, and a water outlet of the pure water device is communicated with a water inlet of the pure water tank.
Preferably, the nanobubble generator includes a first one-way valve, a hydrogen delivery device, a gas mixing pump, a water inlet valve, a gas mixing tank, a nano aeration device and a second one-way valve, two ends of the first one-way valve are respectively communicated with the inlet end of the hydrogen delivery device and the hydrogen outlet end of the electrolytic cell, the outlet end of the hydrogen delivery device is communicated with the gas inlet end of the gas mixing pump, two ends of the water inlet valve are respectively communicated with the liquid inlet end of the gas mixing pump and an external water source, the outlet end of the gas mixing pump is communicated with the inlet end of the gas mixing tank, the outlet end of the gas mixing tank is communicated with the inlet end of the nano aeration device, the outlet end of the nano aeration device is communicated with the inlet end of the second one-way valve, and the outlet end of the second one-way valve is communicated with the hydrogen melting device.
Preferably as above-mentioned scheme, the hydrogen melting device includes the hydrogen melting tank, sets up pressure regulating assembly, vacuum regulating assembly, blowdown subassembly and the subassembly of discharging on the hydrogen melting tank, the entrance point intercommunication of hydrogen melting tank the exit end of second check valve, pressure regulating assembly is used for adjusting the pressure value of hydrogen melting tank, vacuum regulating assembly is used for adjusting the vacuum of hydrogen melting tank, blowdown subassembly is used for discharging the discarded object of hydrogen melting tank, the subassembly of discharging is used for discharging hydrogen-rich water in the hydrogen melting tank.
Preferably, the pressure regulating assembly comprises a negative pressure valve, a pressure switch and a pressure relief valve which are arranged at the top of the hydrogen melting tank.
Preferably, the vacuum adjustment assembly includes a vacuum gauge communicated with the hydrogen melting tank and a vacuum pump communicated with the vacuum gauge.
Preferably, the discharge assembly includes a water outlet valve communicated with the water outlet port of the hydrogen melting tank.
Preferably, the drainage assembly comprises a drainage valve communicated with a drainage port of the hydrogen melting tank.
Preferably, the hydrogen melter further comprises an internal circulation assembly, the internal circulation assembly comprises an internal circulation valve, and two ends of the internal circulation valve are respectively communicated with the liquid inlet end of the air mixing pump and the water discharge port of the hydrogen melting tank.
Compared with the prior art, the utility model has the beneficial effects that:
the hydrogen-rich water preparation system comprises a hydrogen generator, a nano bubble generator and a hydrogen melter which are sequentially communicated, wherein hydrogen generated by the hydrogen generator can be formed into nano-level small molecular hydrogen through the nano bubble generator, so that the dissolving amount of the hydrogen in the hydrogen melter is increased.
The foregoing description is only an overview of the technical solutions of the present invention, and in order to make the technical means of the present invention more clearly understood, the present invention may be implemented in accordance with the content of the description, and in order to make the above and other objects, features, and advantages of the present invention more clearly understood, the following preferred embodiments are described in detail with reference to the accompanying drawings.
Drawings
Fig. 1 is a block diagram showing the structure of a hydrogen-rich water production system of the present invention;
wherein the reference numerals in fig. 1 are:
1. a hydrogen generator; 2. a nanobubble generator; 3. a hydrogen melting device; 4. a pure water tank; 5. an electrolytic cell; 6. a water pump; 7. a water quality detector; 8. a water quality detection control panel; 9. an electrolysis power supply; 10. a water level detector; 11. a water purification device; 12. a first check valve; 13. a hydrogen transfer device; 14. a gas mixing pump; 15. a water inlet valve; 16. a gas mixing tank; 17. a nano aeration device; 18. a second one-way valve; 19. a hydrogen melting tank; 20. a negative pressure valve; 21. a pressure switch; 22. a pressure relief valve; 23. a vacuum gauge; 24. a vacuum pump; 25. a water outlet valve; 26. a drain valve; 27. an internal circulation valve.
Detailed Description
To further illustrate the technical means and effects of the present invention adopted to achieve the predetermined objects, the following detailed description of the embodiments, structures, features and effects according to the present invention with reference to the accompanying drawings and preferred embodiments is as follows:
as shown in fig. 1, the hydrogen-rich water preparation system disclosed in the present invention comprises a hydrogen generator 1, a nano-bubble generator 2 and a hydrogen melter 3 which are connected in sequence, wherein the hydrogen generator 1 is used for generating hydrogen and transmitting the generated hydrogen to the nano-bubble generator 2, the nano-bubble generator 2 generates nano-hydrogen bubbles by using the received hydrogen and transmits the generated nano-hydrogen bubbles to the hydrogen melter 3, and the hydrogen melter 3 forms hydrogen-rich water by using the received nano-hydrogen bubbles, and the hydrogen generated by the hydrogen generator 1 can be formed into nano-scale small-molecule hydrogen by the nano-bubble generator 2, so that the dissolving amount of hydrogen in the hydrogen melter 3 is increased.
Preferably, the hydrogen generator 1 includes a pure water tank 4, an electrolytic cell 5, a water pump 6, a water quality detector 7 disposed in the electrolytic cell 5, a water quality detection control plate 8 electrically connected to the water quality detector 7, a water level detector 10 disposed in the pure water tank 4, and an electrolytic power supply 9 electrically connected to an electrolytic module of the electrolytic cell 5, wherein the water quality detection control plate 8 is electrically connected to the electrolytic power supply 9; two ends of the water pump 6 are respectively communicated with the water outlet of the pure water tank 4 and the water inlet of the electrolytic bath 5; the water return port of the pure water tank 4 is communicated with the water return port of the electrolytic cell 5, and the gas outlet of the electrolytic cell 5 is communicated with the gas inlet of the nano bubble generator 2.
When the water level detector 10 detects that the water level in the pure water tank 4 reaches a preset water level and the water quality detector 7 detects that the water quality in the electrolytic cell 5 meets a preset standard, the water level detector 10 and the water quality detector 7 transmit the information to the electrolysis power supply 9, and then the electrolysis power supply 9 controls the electrolysis module of the electrolytic cell 5 to work to generate hydrogen; the finally generated hydrogen gas is transferred to the nanobubble generator 2 through the gas outlet of the electrolytic bath 5.
Preferably, the hydrogen generator 1 further comprises an automatic water adding system, the automatic water adding system comprises a pure water device 11 electrically connected to the water level detector 10, a water outlet of the pure water device 11 is communicated with a water inlet of the pure water tank 4, and when the water level detector 10 detects that the water level of the pure water tank 4 is lower than a preset value, the pure water device 11 will supplement pure water into the pure water tank 4 until the water level in the pure water tank 4 reaches the preset value.
Preferably, the nano-bubble generator 2 comprises a first one-way valve 12, a hydrogen conveying device 13, a gas mixing pump 14, a water inlet valve 15, a gas mixing tank 16, a nano-aeration device 17 and a second one-way valve 18, two ends of the first one-way valve 12 are respectively communicated with the inlet end of the hydrogen conveying device 13 and the hydrogen outlet end of the electrolytic cell 5, the outlet end of the hydrogen conveying device 13 is communicated with the gas inlet end of the gas mixing pump 14, the two ends of the water inlet valve 15 are respectively communicated with the liquid inlet end of the gas mixing pump 14 and an external water source, the outlet end of the air mixing pump 14 is communicated with the inlet end of the air mixing tank 16, the outlet end of the air mixing tank 16 is communicated with the inlet end of the nano aeration device 17, the outlet end of the nano aeration device 17 is communicated with the inlet end of the second one-way valve 18, and the outlet end of the second one-way valve 18 is communicated with the hydrogen melter 3.
Preferably, the hydrogen feeder 13 is a filter with a pore size of 5-10 um.
When the device works, the hydrogen output by the electrolytic cell 5 flows through the hydrogen conveying device 13 to become high-pressure micromolecule hydrogen, and then the high-pressure micromolecule hydrogen and the water flowing through the water inlet valve 15 enter the air mixing pump 14; then, the high-pressure small-molecule hydrogen and the water entering the air mixing pump 14 form water and hydrogen nano bubbles under the action of high-speed rotation of an impeller of the air mixing pump 14; then, after entering the gas mixing tank 16, the water and the hydrogen nanobubbles are dissolved again and flow into the nano aeration device 17, and the redundant gas is discharged through an exhaust valve of the gas mixing tank 16, so as to ensure that the water of the hydrogen-rich water preparation system can flow smoothly; then, the water and hydrogen nanobubbles flowing into the nano-aeration device 17 flow out in a spiral spray shape to form more water and hydrogen nanobubbles.
Preferably, the hydrogen melting device comprises a hydrogen melting tank 19, and a pressure regulating assembly, a vacuum regulating assembly, a sewage discharging assembly and a discharging assembly which are arranged on the hydrogen melting tank 19, wherein the inlet end of the hydrogen melting tank 19 is communicated with the outlet end of the second one-way valve 18, the pressure regulating assembly is used for regulating the pressure value of the hydrogen melting tank 19, the vacuum regulating assembly is used for regulating the vacuum degree of the hydrogen melting tank 19, the sewage discharging assembly is used for discharging the waste of the hydrogen melting tank 19, the discharging assembly is used for discharging the hydrogen-rich water in the hydrogen melting tank 19, and the vacuum regulating assembly can ensure that the hydrogen melting tank 19 is vacuumized, so that the hydrogen-rich water is filled in the hydrogen melting tank 19.
Preferably, the pressure regulating assembly comprises a negative pressure valve 20, a pressure switch 21 and a pressure relief valve 22 which are arranged at the top of the hydrogen melting tank 19, and when the pressure in the hydrogen melting tank 19 reaches a preset value, the pressure switch 21 is opened, so that the pressure in the hydrogen melting tank 19 is reduced, and the situation that the pressure in the hydrogen melting tank 19 is too high and fails is avoided; when the hydrogen-rich water in the hydrogen tank 19 is discharged, the internal and external pressures of the hydrogen tank 19 can be adjusted by the negative pressure valve 20 and the relief valve 22 to ensure the safety of the hydrogen tank 19, in order to ensure the safety of the hydrogen tank 19.
Preferably, the vacuum adjusting assembly comprises a vacuum gauge 23 communicated with the hydrogen melting tank 19 and a vacuum pump 24 communicated with the vacuum gauge, and the vacuum gauge 23 can be used for checking the vacuum degree in the hydrogen melting tank 19 so as to ensure that the vacuum degree in the hydrogen melting tank 19 reaches a preset value.
Preferably, the discharge means includes a water outlet valve 25 communicating with a water outlet port of the hydrogen melting tank 19, and the hydrogen-rich water in the hydrogen melting tank 19 can be discharged through the water outlet valve 25.
Preferably, the drainage assembly includes a drainage valve 26 communicated with the drainage port of the hydrogen melting tank 19, and the drainage valve 26 can drain the wastewater in the hydrogen melting tank 19.
Preferably, the hydrogen melter further comprises an internal circulation assembly, the internal circulation assembly comprises an internal circulation valve 27, two ends of the internal circulation valve 27 are respectively communicated with the liquid inlet end of the air mixing pump 14 and the water outlet port of the hydrogen melting tank 19, the internal circulation valve 27 can make the hydrogen-rich water in the hydrogen melting tank 19 repeatedly enter the air mixing pump 14, cut and processed to form water and hydrogen nanobubbles, and continuously transmit the water and the hydrogen nanobubbles to the hydrogen-rich tank 19, so that the pressure in the hydrogen melting tank 19 can be increased, and the water and the hydrogen nanobubbles in the hydrogen melting tank 19 can be continuously increased, so as to increase the hydrogen content of the oxygen-rich water in the hydrogen melting tank 19.
It should be noted that the terms "first," "second," and the like in the description of the present invention are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.
The above embodiments are only preferred embodiments of the present invention, and the protection scope of the present invention is not limited thereby, and any insubstantial changes and substitutions made by those skilled in the art based on the present invention are within the protection scope of the present invention.