阅读说明：本技术 氢水产生器、微奈米氢气泡水产生装置及微奈米氢气泡水的制造方法及其应用 (Hydrogen water generator, micro-nano hydrogen bubble water generating device, and manufacturing method and application of micro-nano hydrogen bubble water ) 是由 张荣桂 蔡宇洲 于 2018-08-31 设计创作，主要内容包括：本发明揭露一种氢水产生器、微奈米氢气泡水产生装置及微奈米氢气泡水的制造方法及其应用,本发明主要利用氢水产生器来接收水及氢气,并透过氢水产生器的本体的内部所形成的五个区段来使氢气可与水混合形成为氢水,而无需利用压缩机对氢气进行额外加压。其中,氢水产生器的液体输入区段可提供水输入并流通至加压区段进行加压,经加压后的水则可进一步流通至吸入混合区段以与氢气进行混合,而混合有氢气的水在透过氢水产生器的释压区段进行释压后,则可通过氢水产生器的氢水输出区段来输出带有微奈米氢气泡的氢水。(The invention discloses a hydrogen water generator, a micro-nano hydrogen bubble water generating device, a manufacturing method of micro-nano hydrogen bubble water and application thereof. The liquid input section of the hydrogen water generator can provide water input and circulate to the pressurizing section for pressurizing, the pressurized water can further circulate to the suction mixing section for mixing with hydrogen, and the hydrogen-mixed water can output the hydrogen water with micro-nano hydrogen bubbles through the hydrogen water output section of the hydrogen water generator after being subjected to pressure release through the pressure release section of the hydrogen water generator.)

1. A hydrogen water generator is characterized in that the generator is provided with a body (11) which is in a T-shaped structure, the opposite ends of the body (11) are respectively provided with a liquid input end (111) and a hydrogen output end (112), and a hydrogen input end (113) is arranged between the liquid input end (111) and the hydrogen water output end (112), wherein, the interior of the body (11) is sequentially formed with a liquid input section (A), a pressurizing section (B), an absorbing and mixing section (C), a pressure releasing section (D) and a hydrogen water output section (E) from the liquid input end (111) to the hydrogen water output end (112), a hydrogen input section (F) is arranged between the hydrogen input end (113) and the suction mixing section (C), and the portion of the hydrogen gas input section (F) that engages the suction mixing section (C) forms a hydrogen gas inlet (F1); wherein the diameter (D1) of the liquid inlet section (A) divided by the diameter (D4) of the intake mixing section (C) is between 1.5 and 5, and the diameter (D2) of the hydrogen water output section (E) is larger than the diameter (D4) of the suction mixing section (C), the length (L) of the suction mixing section (C) divided by the diameter (D4) of the suction mixing section (C) is between 1.5 and 5, the inner wall of the pressurizing section (B) is inclined at an angle (theta 1) of 10-50 degrees, the inner wall of the pressure release section (D) has an inclination angle (theta 2) of 10 to 50 degrees, the inclination angle (theta 1) of the inner wall of the pressure-increasing section (B) divided by the inclination angle (theta 2) of the inner wall of the pressure-releasing section (D) is between 1 and 5, wherein the diameter (D1) of the liquid input section (A) divided by the diameter (D3) of the hydrogen inlet (F1) is between 3.25 and 650.

2. The hydrogen water generator of claim 1, characterized in that the diameter (D1) of the liquid input section (a) divided by the diameter (D4) of the suction mixing section (C) is between 2 and 4.

3. The hydrogen water generator of claim 1, characterized in that the length (L) of the suction mixing section (C) divided by the diameter (D4) of the suction mixing section (C) is between 2 and 4.

4. The hydrogen water generator of claim 1, characterized in that the inner wall of the pressurizing section (B) is inclined at an angle (θ 1) between 16 degrees and 25 degrees.

5. The hydrogen water generator of claim 1, characterized in that the inner wall of the pressure relief section (D) is inclined at an angle (θ 2) between 14 degrees and 25 degrees.

6. The hydrogen water generator of claim 1, characterized in that the inclination angle (θ 1) of the inner wall of the pressurization section (B) divided by the inclination angle (θ 2) of the inner wall of the pressure release section (D) is between 1 and 1.5.

7. A micro-nano hydrogen bubble water generating device, characterized in that it comprises at least a hydrogen generating device (20) for providing hydrogen, a water supplying device (30), and a hydrogen water generator (10) according to any one of claims 1 to 6, the liquid input end (111) of the hydrogen water generator (10) is connected with the water supply device (30), the hydrogen input end (113) of the hydrogen water generator (10) is connected with the hydrogen production equipment (20), after the water provided by the water supply device (30) is pressurized from the liquid input section (A) to the pressurizing section (B), is passed to the suction mixing section (C) to be mixed with the hydrogen passing through the hydrogen input section (F), after the water mixed with hydrogen is decompressed through the decompression section (D), Hydrogen Water (HW) with micro-nano hydrogen bubbles is produced through the hydrogen water output section (E) and the hydrogen water output end (112).

8. The micro-nano hydrogen bubble water generating device according to claim 7, wherein the water supply apparatus (30) comprises a water supply tank (31) and a water pump (32), the water inlet of the water pump (32) is connected to the water supply tank (31), the water outlet of the water pump (32) is connected to the liquid input (111) of the hydrogen water generator (10), and the hydrogen water output (112) of the hydrogen water generator (10) is connected to the water supply tank (31).

9. The micro-nano hydrogen bubble water generating device of claim 7, wherein the water supply apparatus (30) comprises a body (33), a water supply tank (31), a water pump (32) and a water outlet device (332), the body (33) provides the hydrogen generating apparatus (20), the hydrogen water generator (10), the water supply tank (31) and the water pump (32) for arrangement, a water inlet end of the water pump (32) is connected to the water supply tank (31), a water outlet end of the water pump (32) is connected to the liquid input end (111) of the hydrogen water generator (10), and the hydrogen water output end (112) of the hydrogen water generator (10) corresponds to a hydrogen water storage tank (331) of the body (33), wherein the water outlet device (332) is connected to the hydrogen water storage tank (331).

10. The micro-nano hydrogen bubble water generating device of claim 7, wherein the water supply apparatus (30) comprises a body (33), a water supply tank (31), a water pump (32) and a water outlet device (332), the body (33) provides the hydrogen generating apparatus (20), the hydrogen water generator (10), the water supply tank (31) and the water pump (32) to be disposed, a water inlet end of the water pump (32) is connected to the water supply tank (31), a water outlet end of the water pump (32) is connected to the liquid input end (111) of the hydrogen water generator (10) and the water outlet device (332) of the body (33), and the hydrogen water output end (112) of the hydrogen water generator (10) is connected to the water supply tank (31).

11. The micro-nano hydrogen bubble water generating apparatus according to claim 7, comprising a fuel tank (40) connected to the hydrogen-producing device (20) for providing fuel for the hydrogen-producing device (20) to perform hydrogen-producing operation.

12. The micro-nano hydrogen bubble water generating device according to claim 7, wherein the hydrogen generating apparatus (20) comprises a liquid-gas separation module (21), a proton exchange membrane hydrogen generating module (22), a power supply and control circuit module (23) and a filtering module (24), the proton exchange membrane hydrogen generating module (22) and the liquid-gas separation module (21) are connected with each other and the filtering module (24), and the liquid-gas separation module (21) is connected with the hydrogen input end (113) of the hydrogen water generator (10).

13. A method for producing hydrogen bubbles with micro-nano characteristics comprises the following steps:

-receiving water provided by a water supply device (30) through the liquid input (111) of an hydrogen water generator (10) according to any of claims 1 to 6, passing water to the liquid input section (a) of the hydrogen water generator (10);

pressurizing water through the pressurizing section (B) when the water is passed through the liquid input section (a) to the pressurizing section (B) of the hydrogen water generator (10), and passing the pressurized water flow to the suction mixing section (C) of the hydrogen water generator (10);

receiving hydrogen provided by a hydrogen production device (20) through the hydrogen input end (113) of the hydrogen water generator (10), and enabling the hydrogen to pass through the hydrogen input section (F) of the hydrogen water generator (10) and enter the suction mixing section (C) of the hydrogen water generator (10) so as to enable the hydrogen to be sucked into the pressurized water for mixing;

when the water mixed with hydrogen gas is circulated to the pressure release section (D) of the hydrogen water generator (10) through the suction mixing section (C), the water mixed with hydrogen gas is subjected to pressure release operation through the pressure release section (D) to generate Hydrogen Water (HW) with micro-nano hydrogen bubbles; and

sequentially passing through the hydrogen water output section (E) and the hydrogen water output end (112) of the hydrogen water generator (10) to output Hydrogen Water (HW) with micro-nano hydrogen bubbles.

14. A food cleaning device capable of providing micro-nano hydrogen bubbles is characterized by at least comprising: a water pump (32), a hydrogen-producing device (20), a hydrogen storage tank (331) and a hydrogen water generator (10) according to any one of claims 1 to 6, wherein a water inlet of the water pump (32) is connected to a water supply device (30), a water outlet of the water pump (32) is connected to the liquid input (111) of the hydrogen water generator (10), an output of the hydrogen-producing device (20) is connected to the hydrogen input (113) of the hydrogen water generator (10), wherein the water (W) and the hydrogen (H) respectively received by the liquid input (111) and the hydrogen input (113) are combined inside the hydrogen water generator (10) to form a micro-nano hydrogen bubble water, and the hydrogen water output (112) of the hydrogen water generator (10) provides and outputs the micro-nano hydrogen bubble water to the hydrogen water storage tank (331); wherein the hydrogen water storage tank (331) comprises at least one storage tank inlet end and at least one storage tank outlet end, wherein the storage tank inlet end is used for connecting the hydrogen water output end (112) of the hydrogen water generator (10), and the storage tank outlet end is connected with a water outlet device (332); wherein the water outlet device (332) is connected with a cleaning device (333), so that the cleaning device (333) can receive the Hydrogen Water (HW) of the micro-nano hydrogen bubbles flowing out from the water outlet device (332).

15. A compound cultivation system capable of providing micro-nano hydrogen bubbles is characterized by at least comprising: the hydrogen water generator (10) of any one of claims 1 to 6, a water pump (32), a hydrogen-generating device (20), a hydrogen water generating tank (50), and a cultivation area (51) for cultivation, wherein a water outlet of the water pump (32) is connected to the liquid input (111) of the hydrogen water generator (10), and the hydrogen-generating device (20) is connected to the hydrogen input (113) of the hydrogen water generator (10), the hydrogen water generating tank (50) is connected to the hydrogen water output (112) of the hydrogen water generator (10), the cultivation area (51) is connected to one end of a hydrogen water pump (52), and the other end of the hydrogen water pump (52) is connected to the hydrogen water generating tank (50), wherein water (W) and hydrogen (H) received by the liquid input (111) and the hydrogen input (113), respectively, are combined inside the hydrogen water generator (10) into a HW of micro-hydrogen bubbles, enabling the hydrogen water output end (112) of the hydrogen water generator (10) to provide Hydrogen Water (HW) outputting the micro-nano hydrogen bubbles to the hydrogen water generating tank (50); wherein the cultivation area (51) is any one or combination of more than two of a plant cultivation area, an animal cultivation area or an aquaculture cultivation area.

16. A cleaning device capable of providing micro-nano hydrogen bubbles is characterized by at least comprising: the hydrogen water generator (10) of any of claims 1 to 6, a hydrogen-generating device (20), a water pump (32), and a cleaning device (70), wherein a water outlet of the water pump (32) is connected to the liquid input (111) of the hydrogen water generator (10), an output of the hydrogen-generating device (20) is connected to the hydrogen input (113) of the hydrogen water generator (10), wherein the water (W) and the hydrogen (H) received by the liquid input (111) and the hydrogen input (113), respectively, are combined inside the hydrogen water generator (10) into a Hydrogen Water (HW) of micro-nano hydrogen bubbles, and the hydrogen water output (HW) 112 of the hydrogen water generator (10) provides the Hydrogen Water (HW) outputting the micro-nano hydrogen bubbles to the cleaning device (70); wherein the cleaning device (70) is any one of a shower head, a bathtub or a faucet.

Technical Field

The present invention relates to a hydrogen water production technology, and more particularly, to a hydrogen water generator, a micro-nano hydrogen bubble water generating device, a micro-nano hydrogen bubble water producing method, and a micro-nano hydrogen bubble water producing method, which can break hydrogen molecular groups into a large number of micro-nano hydrogen bubbles that can be dissolved in water quickly to form hydrogen water without using a compressor to additionally pressurize the hydrogen.

Background

Accordingly, the academic literature has described that hydrogen gas has a considerable degree of health care or therapeutic effect when applied to the human body, and furthermore, the research results of a great deal of literature have shown that hydrogen gas has a considerable effect on agriculture or even aquaculture. In general, hydrogen is dissolved in water to form hydrogen water for spraying or drinking, or hydrogen is directly absorbed by body, and both absorption modes are performed in the form of hydrogen molecules.

In the process of preparing hydrogen water, the conventional technology mostly directly introduces hydrogen into drinking water, but due to the limited solubility of hydrogen in water, it usually takes a long time to dissolve the hydrogen into the desired amount of hydrogen, and hydrogen rapidly escapes from water over time, so that the hydrogen water is not easy to store, and the actual amount of hydrogen dissolved is far less than desired.

In order to solve the above problems, there is a conventional technique that uses a hydrogen compressor to compress hydrogen gas, and the compressed hydrogen gas can be rapidly dissolved in water in a water tank after passing through a plate with fine holes. However, since the conventional high-pressure compressor has a danger of generating sparks and having flammable characteristics, a certain volume and space are required to avoid the danger, and thus the high-cost hydrogen compressor increases the manufacturing cost of the hydrogen water.

In addition, there is a conventional technique that utilizes an ultrasonic vibration sheet to vibrate on the water surface to break the hydrogen gas into micro-molecules by the energy during vibration, so that the hydrogen gas can be rapidly combined with the water. However, since the ultrasonic oscillation plate must use a higher vibration frequency, if the volume of the ultrasonic oscillation plate is too large, the conventional ultrasonic oscillation plate has a smaller area, and cannot form a large amount of micro-nano hydrogen bubbles in a short time, which limits the use of the ultrasonic oscillation plate.

Disclosure of Invention

In view of the above problems of the prior art, the present invention provides a hydrogen water generator, a micro-nano hydrogen bubble water generating device, a micro-nano hydrogen bubble water manufacturing method and applications thereof, which can break hydrogen molecular groups into a large number of micro-nano hydrogen bubbles capable of accelerating dissolution in water to form hydrogen water without using a compressor to additionally pressurize the hydrogen gas, a micro-nano hydrogen bubble water generating device, a micro-nano hydrogen bubble water manufacturing method and applications thereof.

Another objective of the present invention is to provide a drinking device, which can be used to make hydrogen water with high solubility by dissolving hydrogen in water, and can be used to drink by a user by combining with the drinking device, so as to provide the advantage that the user can absorb beneficial substances in hydrogen water more quickly.

Another objective of the present invention is to provide a food cleaning device, which uses the excellent oxidation resistance of hydrogen gas to achieve the effect of deep washing and the effect of hydrogen gas addition in cleaning and preserving food materials, so that the food cleaning device can be applied to cleaning of a large amount of vegetables, fruits or meat, thereby achieving the efficient cleaning and preserving effect.

The invention also provides an application of the combined cultivation system, which mainly utilizes the structural configuration design of the water pump, the hydrogen water generator and the hydrogen water generating tank to ensure that the cultivated animals, plants and aquatic products can absorb a large amount of hydrogen molecules, thereby promoting the growth, effectively improving the cultivation and cultivation environment of animals and plants, avoiding the environmental pollution and the like.

Another objective of the present invention is to provide an application of a cleaning device, in which hydrogen generated by a hydrogen generation device is mixed with water to generate hydrogen water with micro-nano hydrogen bubbles through a hydrogen water generator, and a large amount of negative charges generated by the hydrogen water with micro-nano hydrogen bubbles are utilized to attract dirt with positive charges, and the micro-nano hydrogen bubbles are very small and can easily enter skin pores, and the dirt is taken away through the principle of positive and negative attraction, so as to achieve the advantages of beauty and deep cleaning.

According to the objective of the present invention, a hydrogen water generator is provided, which has a body with a substantially T-shaped structure, wherein two opposite ends of the body are respectively provided with a liquid input end and a hydrogen water output end, and a hydrogen input end is arranged between the liquid input end and the hydrogen water output end, wherein a liquid input section, a pressurization section, a suction mixing section, a pressure release section and a hydrogen water output section are sequentially formed inside the body from the liquid input end to the hydrogen water output end, a hydrogen input section is arranged between the hydrogen input end and the suction mixing section, and a hydrogen inlet is formed by the part of the hydrogen input section connected with the suction mixing section; wherein, the diameter of the liquid input section divided by the diameter of the suction mixing section is between 1.5 and 5, the diameter of the hydrogen water output section is larger than that of the suction mixing section, the length of the suction mixing section divided by the diameter of the suction mixing section is between 1.5 and 5, the inclination angle of the inner wall of the pressurizing section is between 10 and 50 degrees, the inclination angle of the inner wall of the pressure releasing section is between 10 and 50 degrees, the inclination angle of the inner wall of the pressurizing section divided by the inclination angle of the inner wall of the pressure releasing section is between 1 and 5, and the diameter of the liquid input section divided by the diameter of the hydrogen inlet is between 3.25 and 650.

According to the above technical characteristics, the diameter of said liquid input section divided by the diameter of the suction mixing section is further comprised between 2 and 4.

According to the above technical feature, the length of the suction mixing section divided by the diameter of the suction mixing section is further between 2 and 4.

According to the above technical features, the inner wall of the pressing section is inclined at an angle further between 16 degrees and 25 degrees.

According to the above technical features, the inner wall of the pressure release section is inclined at an angle further between 14 degrees and 25 degrees.

According to the above technical features, the inclination angle of the inner wall of the pressure-applying section divided by the inclination angle of the inner wall of the pressure-releasing section is further between 1 and 1.5.

According to the above technical features, the diameter of the hydrogen inlet is further between 0.01mm and 2 mm.

According to the objective of the present invention, there is provided a micro-nano hydrogen bubble water generating apparatus at least comprising a hydrogen generating device for providing hydrogen, a water supplying device, and a hydrogen water generator as described above, wherein the liquid input end of the hydrogen water generator is connected to the water supplying device, the hydrogen input end of the hydrogen water generator is connected to the hydrogen generating device, when the water provided by the water supplying device is pressurized from the liquid input section to the pressurizing section, the water can further flow to the suction mixing section to be mixed with the hydrogen passing through the hydrogen input section, and after the water mixed with hydrogen is depressurized through the pressure relieving section, the hydrogen water with micro-nano hydrogen bubbles can be produced through the hydrogen water output section and the hydrogen water output end.

According to the above technical feature, the water supply equipment contains a water supply tank and a water pump, and the water supply tank is connected to the income water end of water pump, and the liquid input of hydrogen water generator is connected to the play water end of water pump, and hydrogen water generator's hydrogen water output links up the water supply tank.

According to the above technical features, the water supply equipment contains a organism, a water supply tank, a water pump and a water installation, and the organism provides hydrogen production equipment, hydrogen water generator, water supply tank and water pump setting, and the water supply tank is connected to the income water end of water pump, and the liquid input of hydrogen water generator is connected to the play water end of water pump, and hydrogen water generator's hydrogen water output corresponds to a hydrogen water storage tank to the organism, wherein this water installation connection sets up in this hydrogen water storage tank.

According to the above technical features, the water supply apparatus further comprises a body, a water supply tank, a water pump and a water outlet device, the body provides the hydrogen production apparatus, the hydrogen water generator, the water supply tank and the water pump, the water inlet end of the water pump is connected with the water supply tank, and the water outlet end of the water pump is connected with the liquid input end of the hydrogen water generator and the water outlet device of the body.

According to the above technical features, the micro-nano hydrogen bubble water generating device further comprises a fuel tank connected to the hydrogen generating apparatus to provide fuel for the hydrogen generating apparatus to perform hydrogen generating operation.

According to the technical characteristics, the hydrogen production equipment comprises a liquid-gas separation module, a proton exchange membrane hydrogen production module, a power supply and control circuit module and a filtering module, wherein the proton exchange membrane hydrogen production module, the liquid-gas separation module and the filtering module are connected with each other, and the liquid-gas separation module is connected with a hydrogen input end of a hydrogen water generator.

According to the objective of the present invention, a method for producing hydrogen bubbles with micro-nano structure is further provided, which comprises the following steps: receiving water provided by a water supply device through a liquid input end of a hydrogen water generator, so that the water can circulate to a liquid input section of the hydrogen water generator; when water flows to a pressurizing section of the hydrogen water generator through the liquid input section, the water is pressurized through the pressurizing section, and the pressurized water can flow to an absorbing and mixing section of the hydrogen water generator; receiving hydrogen provided by a hydrogen production device through a hydrogen input end of the hydrogen water generator, so that the hydrogen can pass through a hydrogen input section of the hydrogen water generator and enter an inhalation mixing section of the hydrogen water generator, and the hydrogen can be inhaled into pressurized water for mixing; when the water mixed with hydrogen is circulated to a pressure release section of the hydrogen water generator through the suction mixing section, the pressure release section is used for releasing the pressure of the water mixed with hydrogen so as to generate hydrogen water with micro-nano hydrogen bubbles; and outputting the hydrogen water with the micro-nano hydrogen bubbles through a hydrogen water output section and a hydrogen water output end of the hydrogen water generator in sequence.

According to the objective of the present invention, a food cleaning device capable of providing micro-nano hydrogen bubbles is provided, which at least comprises: a water pump, a hydrogen production equipment, a hydrogen water storage tank and as above hydrogen water generator, wherein the income water end of this water pump connects a water supply equipment, this liquid input of this hydrogen water generator is connected to the play water end of this water pump, this hydrogen water generator's this hydrogen input is connected to this hydrogen production equipment's output, wherein this liquid input and this hydrogen input respectively received water and hydrogen can combine for the hydrogen water of little nanometer hydrogen bubble in the inside of this hydrogen water generator, this hydrogen water output of this hydrogen water generator provides the hydrogen water of this little nanometer hydrogen bubble of output to this hydrogen water storage tank.

According to the above technical features, the hydrogen water storage tank further comprises at least one storage tank inlet end and at least one storage tank outlet end, wherein the storage tank inlet end is connected to the hydrogen water outlet end of the hydrogen water generator, and the storage tank outlet end is connected to a water outlet device; wherein the water outlet device is further connected with a cleaning device, so that the cleaning device can receive the hydrogen water of the micro-nano hydrogen bubbles flowing out from the water outlet device.

According to the objective of the present invention, a compound cultivation system capable of providing hydrogen bubbles of micro-nano meters is further provided, which at least comprises: one as above hydrogen water generator, a water pump, a hydrogen production facility, a hydrogen water production groove and a cultivation district of breeding, wherein this liquid input of this hydrogen water generator is connected to the play water end of this water pump, and this hydrogen production facility connects this hydrogen input of this hydrogen water generator, this hydrogen water output of this hydrogen water generator is connected to this hydrogen water production groove, this cultivation district of breeding is connected with a hydrogen water pump one end, and the other end of this hydrogen water pump is connected with this hydrogen water production groove, wherein this liquid input and this hydrogen input respectively received water and hydrogen can combine in the inside of this hydrogen water generator for the hydrogen water of a little nanometer hydrogen bubble, make this hydrogen water output of this hydrogen water generator provide the hydrogen water of exporting this little nanometer hydrogen bubble to this hydrogen water production groove.

According to the above technical features, the cultivation area may be any one or a combination of two or more of a plant cultivation area, an animal cultivation area, and an aquaculture cultivation area.

According to the objective of the present invention, a cleaning device for providing micro-nano hydrogen bubbles is further provided, which at least comprises: the hydrogen water generator, the hydrogen production device, the water pump and the cleaning device are characterized in that the water outlet end of the water pump is connected with the liquid input end of the hydrogen water generator, the output end of the hydrogen production device is connected with the hydrogen input end of the hydrogen water generator, the water and the hydrogen respectively received by the liquid input end and the hydrogen input end can be combined into hydrogen water with micro-nano hydrogen bubbles in the hydrogen water generator, and the hydrogen water output end of the hydrogen water generator provides the hydrogen water for outputting the micro-nano hydrogen bubbles to the cleaning device.

According to the above technical feature, the cleaning device is any one of a shower head, a bathtub and a faucet.

In view of the above, the hydrogen water generator, the micro-nano hydrogen bubble water generating device, and the manufacturing method and application of the micro-nano hydrogen bubble water of the present invention have the following advantages.

1. The hydrogen water generator is mainly used for receiving water and hydrogen, and hydrogen molecular groups are smashed and dispersed into micro-nano bubbles through the structure formed in the hydrogen water generator body, so that the hydrogen can be mixed with the water to form the hydrogen water on the premise of not additionally pressurizing the hydrogen, and a compressor can be omitted, so that the cost for preparing the hydrogen water is reduced.

2. The hydrogen water generator can break and disperse hydrogen molecular groups into micro-nano bubbles, and the micro-nano bubbles have the characteristics of better Mass transfer (Mass transfer), slower rising and dissipation and the like, so the dissolution speed of hydrogen in water can be accelerated, the preparation of hydrogen water can be completed in a short time, and the time for storing the hydrogen in the hydrogen water can be prolonged.

3. By dissolving hydrogen in water, the hydrogen water with high solubility can be quickly prepared, and the hydrogen water can be combined with a drinking device to be drunk by a user, so that the user can more quickly absorb beneficial substances in the hydrogen water.

4. The food material cleaning and fresh-keeping method has the advantages that the excellent oxidation resistance of hydrogen is utilized, so that the food material cleaning and fresh-keeping method has the effect of deep washing and the effect of superposition of the oxidation resistance of hydrogen, and can be applied to cleaning operation of a large number of vegetables, fruits or meat products, and therefore the efficient cleaning and fresh-keeping effects are achieved.

5. The structural configuration design of penetrating through water pump, hydrogen water generator and hydrogen water production groove makes the animal, plant, the aquatic products of breed can absorb a large amount of hydrogen molecules, and then promotes to grow, makes its environment that can effectively promote animal and plant cultivation and breed, can also avoid the environment to receive advantages such as pollution.

6. The hydrogen produced by the hydrogen production equipment is mixed with water through the hydrogen water generator to produce the hydrogen water of the micro-nano hydrogen bubbles, and a large amount of negative charges formed when the hydrogen water of the micro-nano hydrogen bubbles is produced are utilized, so that the hydrogen water can attract dirt with positive charges, the micro-nano hydrogen bubbles are very small, can easily enter skin pores, and take away the dirt through the principle of positive and negative attraction, and the advantages of beauty treatment and deep cleaning are achieved.

Drawings

Fig. 1 is a schematic cross-sectional view of a hydrogen water generator according to the present invention.

Fig. 2 is a schematic view of a micro-nano hydrogen bubble water generating device according to a first embodiment of the present invention.

Fig. 3 is a schematic view of a micro-nano hydrogen bubble water generating device according to a second embodiment of the present invention.

Fig. 4 is a schematic view of a micro-nano hydrogen bubble water generating device according to a third embodiment of the present invention.

Fig. 5 is a schematic view of a micro-nano hydrogen bubble water generating device according to a fourth embodiment of the present invention.

FIG. 6 is a flow chart of the method for manufacturing hydrogen bubbles.

Fig. 7 is a schematic structural view of a food washing device to which the present invention is applied.

FIG. 8 is a first schematic view of the present invention applied to a compound cultivation system.

FIG. 9 is a second schematic view of the composite cultivation system of the present invention.

FIG. 10 is a third schematic view of the composite cultivation system of the present invention.

FIG. 11 is a fourth schematic view of the present invention applied to a compound cultivation system.

FIG. 12 is a schematic view of a cleaning apparatus according to the present invention.

Description of the figure numbers:

10 hydrogen water generator

11 main body

111 liquid input end

112 hydrogen water output

113 hydrogen input end

20 hydrogen production equipment

21 liquid-gas separation module

22 proton exchange membrane hydrogen production module

23 power supply and control circuit module

24 filter module

25 fuel apparatus

26 waste gas calandria

30 water supply equipment

31 water supply tank

32 water pump

321 hydrogen water circulating end

33 machine body

331 hydrogen water storage tank

332 water outlet device

333 cleaning device

40 fuel barrel

50 hydrogen water generating tank

51 hydrogen water pump

52 hydrogen water level meter

60 cultivation area

61 plant cultivation area

611 watering device

612 hygrometer

62 animal breeding area

621 animal breeding branch valve inlet end

622 circulation water outlet end for animal breeding

623 animal breeding circulating pump

624 animal breeding level gauge

63 aquiculture and culture area

631 inlet end of a diverter valve for aquaculture

632 circulation water outlet end for aquaculture

633 circulating pump for aquaculture

634 aquiculture culture cultivation liquid level meter

64-way valve

65 control module

66 remote control module

67 control center

70 cleaning device

H hydrogen gas

HW hydrogen water

W water

A liquid input section

B pressurized section

C suction mixing section

D pressure relief segment

E hydrogen water output section

F hydrogen gas input section

F1 Hydrogen gas Inlet

D1 to D4 diameters

Length of L

Theta 1-theta 2 angle

G waste gas

S11 to S15.

Detailed Description

The hydrogen water generator of the invention can mainly absorb hydrogen gas through the suction force generated when liquid flows from the pipe with large cross section to the pipe with small cross section, and smashes the gas molecular group of the hydrogen gas to the level of micro-nano bubbles by the flow velocity of the liquid, so that good gas-liquid mixing effect can be achieved between the hydrogen gas and the liquid, and the hydrogen water is prepared. Please refer to fig. 1, which is a schematic cross-sectional view of a hydrogen water generator according to the present invention; as shown in the drawings, the hydrogen water generator 10 of the present invention has a body 11 with a substantially T-shaped structure, two opposite ends of the body 11 are respectively provided with a liquid input end 111 for water W to enter and a hydrogen water output end 112 for outputting hydrogen water HW, and the body 11 is provided with a hydrogen input end 113 for hydrogen gas H to enter between the liquid input end 111 and the hydrogen water output end 112. Furthermore, a liquid input section a, a pressurization section B, an intake mixing section C, a pressure release section D and a hydrogen water output section E are sequentially formed in the body 11 from the liquid input end 111 to the hydrogen water output end 112, and the body 11 has a hydrogen gas input section F between the hydrogen gas input end 113 and the intake mixing section C, and a hydrogen gas inlet F1 is formed at a portion of the hydrogen gas input section F connected to the intake mixing section C.

When the hydrogen water generator 10 is used to prepare hydrogen water HW, the water W can enter the liquid input section a through the liquid input end 111, and after the water W passes through the liquid input section a and reaches the pressurizing section B to be pressurized, the water W can further flow to the suction mixing section C, and then the water W flows from the pipe with the large cross-sectional area to the pipe with the small cross-sectional area, so that suction can be generated to suck hydrogen H passing through the hydrogen inlet F1 of the hydrogen input section F into the water W, and meanwhile, the gas molecular groups of the hydrogen H can be crushed to micro-nano hydrogen bubbles through the flow velocity of the water W, so that the hydrogen H can be sucked into the mixing section C to be mixed with the water W. Then, after the water W mixed with the hydrogen H is decompressed by the decompression section D, the hydrogen water HW with micro-nano hydrogen bubbles can be produced through the hydrogen water output section E and the hydrogen water output end 112.

Of the above, the diameter D1 of the liquid input section a and the diameter D2 of the hydrogen water output section E are larger than the diameter D4 of the suction mixing section C; wherein the diameter D1 of the liquid input section a divided by the diameter D4 of the suction mixing section C may be 1.5 to 5, preferably 2 to 4; the length L of the suction mixing section C divided by the diameter D4 of the suction mixing section C may be 1.5 to 5, preferably 2 to 4; the inner wall of the pressurizing section B is inclined at an angle θ 1 of 10 to 50 degrees, preferably 16 to 25 degrees; the inner wall of the pressure release section D may be inclined at an angle θ 2 of 10 to 50 degrees, preferably 14 to 25 degrees; the angle θ 1 at which the inner wall of the pressurizing section B is inclined divided by the angle θ 2 at which the inner wall of the pressure-releasing section D is inclined may be 1 to 5, preferably 1 to 1.5; wherein the diameter D1 of the liquid input section a divided by the diameter D3 of the hydrogen inlet F1 may be 3.25 to 650; wherein, the diameter D3 of the hydrogen inlet F1 can be 0.01mm to 2mm, preferably 0.4mm to 1.5 mm.

Referring to fig. 1 and 2 together, fig. 2 is a schematic view of a micro-nano hydrogen bubble water generating device according to a first embodiment of the present invention. As shown in the drawings, the micro-nano hydrogen bubble water generating apparatus of the present invention comprises, in addition to the hydrogen water generator 10, a hydrogen generating device 20, a water supply device 30 and a fuel tank 40, wherein the hydrogen generating device 20 is connected to the hydrogen input end 113 of the hydrogen water generator 10 and is connected to the fuel tank 40, and the water supply device 30 is connected to the liquid input end 111 of the hydrogen water generator 10. Further, the water supply apparatus 30 comprises a water supply tank 31 and a water pump 32, wherein a water inlet of the water pump 32 is connected to the water supply tank 31, a water outlet of the water pump 32 is connected to the liquid input 111 of the hydrogen water generator 10, and the hydrogen water output 112 of the hydrogen water generator 10 is connected to the water supply tank 31. Wherein, the fuel tank 40 can be provided with hydrogen production fuel such as petrochemical fuel, pure water for electrolysis, electrolyte, etc., when the fuel tank 40 delivers the fuel to the hydrogen production device 20, the hydrogen production device 20 can discharge unnecessary waste gas G and deliver hydrogen H to the hydrogen water generator 10, and continuously mix water W and hydrogen H through the hydrogen water generator 10 in an open circulation or closed circulation manner, and store the HW hydrogen water with micro-nano hydrogen bubbles formed by mixing in the water supply tank 31.

Referring to fig. 1 and 3 together, fig. 3 is a schematic view of a micro-nano hydrogen bubble water generating device according to a second embodiment of the present invention. As shown in the drawings, the micro-nano hydrogen bubble water generating apparatus of the present invention comprises, in addition to the hydrogen water generator 10, a hydrogen generating device 20 and a water supply device 30, wherein the water supply device 30 comprises a water supply tank 31, a water pump 32 and a body 33; the body 33 provides hydrogen production device 20, hydrogen water generator 10, water supply tank 31 and water pump 32, hydrogen production device 20 connects hydrogen input 113 of hydrogen water generator 10, water supply tank 31 is connected to the income water end of water pump 32, the liquid input 111 of hydrogen water generator 10 is connected to the play water end of water pump 32, and hydrogen water output 112 of hydrogen water generator 10 corresponds to a hydrogen water storage tank 331 of body 33. The hydrogen input end 113 of the hydrogen water generator 10 can receive the hydrogen gas provided by the hydrogen production device 20, the water pump 32 can pump the water in the water supply tank 31 into the liquid input end 111 of the hydrogen water generator 10, and the hydrogen gas H and the water W are mixed through the hydrogen water generator 10 to form the hydrogen water HW which can be output to a hydrogen water storage tank 331 of the body 33, wherein the water outlet device 332 is connected to the hydrogen water storage tank 331, and when a user opens the water outlet device 332 of the body 33, the hydrogen water HW stored in the hydrogen water storage tank 331 can be obtained; wherein the water supply tank 31 may be a water storage tank for a water dispenser.

Referring to fig. 1 and 4 together, fig. 4 is a schematic view illustrating a micro-nano hydrogen bubble water generating device according to a third embodiment of the present invention. As shown in the drawings, the micro-nano hydrogen bubble water generating apparatus of the present invention comprises, in addition to the hydrogen water generator 10, a hydrogen generating device 20 and a water supply device 30, wherein the water supply device 30 comprises a water supply tank 31, a water pump 32 and a body 33; the body 33 provides hydrogen production equipment 20, hydrogen water generator 10, water supply tank 31 and water pump 32, the hydrogen production equipment 20 is connected with the hydrogen input end 113 of the hydrogen water generator 10, the water inlet end of the water pump 32 is connected with the water supply tank 31, the water outlet end of the water pump 32 is connected with the liquid input end 111 of the hydrogen water generator 10 and corresponds to a water outlet device 332 of the body 33, and the hydrogen water output end 112 of the hydrogen water generator 10 is connected with the water supply tank 31. In this embodiment, the hydrogen water HW is continuously formed in the water supply tank 31 by a closed cycle, so as to increase the purity of the hydrogen contained in the hydrogen water HW, and when the user opens the water outlet device 332 of the body 33, the hydrogen water HW can be immediately obtained for use; wherein the water supply tank 31 may be a water storage tank for a water dispenser.

Referring to fig. 1 and 5, fig. 5 is a schematic view of a micro-nano hydrogen bubble water generating device according to a fourth embodiment of the present invention. As shown in the drawings, the micro-nano hydrogen bubble water generating apparatus of the present invention includes the hydrogen water generator 10, a hydrogen generating device 20 and a water supply device 30. The hydrogen production apparatus 20 may be any hydrogen production apparatus, but is not limited thereto. In a preferred embodiment of the present invention, the hydrogen production apparatus 20 comprises a liquid-gas separation module 21, a proton exchange membrane hydrogen production module 22, a power supply and control circuit module 23 and a filtering module 24, the power supply and control circuit module 23 is disposed in the hydrogen production apparatus 20, so that it is electrically connected to each module and used for supplying and controlling power and opening and closing of each module of the hydrogen production apparatus 20, the proton exchange membrane hydrogen production module 22, the liquid-gas separation module 21 and the filtering module 24 are connected to each other to form a closed cycle, and the liquid-gas separation module 21 is connected to the hydrogen input end 113 of the hydrogen water generator 10; therefore, after the proton exchange membrane hydrogen production module 22 produces oxygen, hydrogen H and water W, the oxygen and a part of the water W are guided back to the filtering module 24 through the pipeline, the hydrogen H and the water W are separated by the liquid-gas separation module 21 and are conveyed to the hydrogen input end 113 of the hydrogen water generator 10, and the rest of the water W is guided back to the filtering module 24 through the pipeline, and the filtered water W is used as a raw material source of the proton exchange membrane hydrogen production module 22 through the filtering of the filtering module 24; wherein, the hydrogen production through the proton exchange membrane hydrogen production module 22 can make the hydrogen purity reach more than 99.995%, and the produced hydrogen has no worry of pollution. The water supply apparatus 30 comprises a water supply tank 31 and a water pump 32, wherein a water inlet end of the water pump 32 is connected to the water supply tank 31, a water outlet end of the water pump 32 is connected to the liquid input end 111 of the hydrogen water generator 10, and the hydrogen water output end 112 of the hydrogen water generator 10 is connected to the water supply tank 31; wherein the water supply tank 31 may be a movable kettle.

Referring to fig. 1, 2 and 6, fig. 6 is a flow chart of the method for manufacturing micro-nano hydrogen bubbles according to the present invention, which at least includes the following steps.

Step S11: a liquid input step of receiving the water W supplied from the water supply device 30 through the liquid input end 111 of the hydrogen water generator 10 so that the water W can flow to the liquid input section a of the hydrogen water generator 10.

Step S12: a pressurizing step; when the water W is passed through the liquid input section a to the pressurizing section B of the hydrogen water generator 10, the water W is pressurized through the pressurizing section B, and the pressurized water W is passed through the suction mixing section C of the hydrogen water generator 10.

Step S13: the hydrogen gas H provided by the hydrogen generation device 20 is received through the hydrogen input end 113 of the hydrogen water generator 10, and then the hydrogen gas H can pass through the hydrogen input section F of the hydrogen water generator 10 and enter the suction mixing section C of the hydrogen water generator 10, so that the hydrogen gas H can be sucked into the pressurized water W for mixing and breaking up hydrogen gas molecular groups.

Step S14: a pressure releasing step; when the water W mixed with the hydrogen H flows to the pressure release section D of the hydrogen water generator 10 through the suction mixing section C, the water W mixed with the hydrogen H is subjected to a pressure release operation through the pressure release section D to generate hydrogen water HW with micro-nano hydrogen bubbles.

Step S15: an output step of outputting the hydrogen water HW with micro-nano hydrogen bubbles through the hydrogen water output section E and the hydrogen water output end 112 of the hydrogen water generator 10 in sequence.

Specifically, the invention mainly utilizes the change of the cross section of the internal structure of the hydrogen water generator to pressurize the liquid, so that the hydrogen can be sucked into the liquid, and simultaneously the gas molecular group of the hydrogen can be crushed by the flow velocity of the liquid, so that the hydrogen can form a large amount of micro-nano hydrogen bubbles and can be quickly dissolved in the liquid without using a compressor to additionally pressurize the hydrogen, and the micro-nano hydrogen bubbles have the advantages of better mass transfer, slower rising and dissipation and the like, so that the time for storing the hydrogen in the hydrogen water can be further prolonged.

Referring to fig. 1 and 7 together, fig. 7 is a schematic structural diagram of a food cleaning device according to the present invention. As shown in the drawings, the food washing device capable of providing micro-nano hydrogen bubbles of the present invention at least comprises: a water pump 32, a hydrogen-producing device 20, a hydrogen water storage tank 331 and the hydrogen water generator 10 as described above, wherein the water inlet end of the water pump 32 is connected with a water supply device 30, the water outlet end of the water pump 32 is connected with the hydrogen water generator 10, wherein the opposite ends of the hydrogen water generator 10 are respectively provided with the liquid input end 111 and the hydrogen water output end 112, and the hydrogen input port 113 is disposed between the liquid input port 111 and the hydrogen water output port 112, the liquid input end 111 is connected with the water pump 32, the hydrogen input end 113 is connected with the hydrogen production device 20, the hydrogen water output end 112 is connected with the hydrogen water storage tank 331, the hydrogen production equipment 20 can be any one of a petrochemical fuel hydrogen production device, an electrolyzed water hydrogen production device, a proton exchange membrane hydrogen production device, a solar hydrogen production device and the like, wherein the water supply equipment 30 is any one of a reservoir, a water tower, a water storage tank, a water tap and the like.

Wherein the hydrogen water storage tank 331 further comprises at least one storage tank inlet end and at least one storage tank outlet end, wherein the storage tank inlet end is used to connect the hydrogen water output end 112 of the hydrogen water generator 10, the storage tank outlet end is connected to a water outlet device 332, the water outlet device 332 is further connected to a cleaning device 333, so that the cleaning device 333 can receive the hydrogen water of micro-nano hydrogen bubbles flowing out from the water outlet device 332, wherein the water outlet device 332 is any one of a faucet, a sprinkler tube (as shown in fig. 7) or a water tube; the cleaning device 333 is any one of a conveying cleaning platform (as shown in fig. 7), a cleaning tank or a cleaning barrel, but not limited thereto; therefore, through the structural configuration design of the hydrogen water generator 10, the hydrogen water storage tank 331, the water outlet device 332 and the cleaning device 333, residual pesticides, microorganisms, bacteria or chemical agents in vegetables, fruits or food can be effectively washed, and the advantages of fresh-keeping, bacteriostasis and decomposition effects can be achieved. Wherein, the hydrogen water storage tank 331 is any one of a cleaning tank and a cleaning barrel, when the hydrogen water output end 112 of the hydrogen water generator 10 outputs the hydrogen water HW of the micro-nano hydrogen bubbles to the hydrogen water storage tank 331, food can be cleaned and preserved, pesticide, microorganism, bacteria or chemical agent remained on the vegetables and fruits or the food can be effectively cleaned, and the advantages of bacteriostasis and decomposition effect can be achieved.

Wherein, the present invention is applied to a food cleaning device capable of providing micro-nano hydrogen bubbles, and further comprises: a fuel device 25 connected to the hydrogen production device 20, and a waste gas exhaust pipe 26 disposed on one side of the hydrogen production device 20, wherein the fuel device 25 can be provided with hydrogen production fuels such as petrochemical fuels, pure water for electrolysis, and electrolyte, when the fuel device 25 delivers the fuel to the hydrogen production device 20, the hydrogen production device 20 can discharge unnecessary waste gas G by using the waste gas exhaust pipe 26, and deliver hydrogen H to the hydrogen water generator 10, so as to continuously mix water W and hydrogen H through the hydrogen water generator 10, and store the hydrogen water HW with micro-nano hydrogen bubbles in the hydrogen water storage tank 331; in addition, in a preferred embodiment of the present invention, the hydrogen production apparatus 20 uses a proton exchange membrane as a hydrogen production technology, so that the purity of hydrogen gas can reach more than 99.995%, and the produced hydrogen gas has no contamination.

Referring to fig. 1 and 8, fig. 8 is a first schematic view of the composite cultivation system according to the present invention. As shown in the drawings, the present invention is applied to a compound cultivation system capable of providing micro-nano hydrogen bubbles, which at least comprises: a water pump 32, a hydrogen-generating device 20, a hydrogen water generator 10 as described above, a hydrogen water generating tank 50 and at least one cultivation area 60. Wherein the water pump outlet end of the water pump 32 is connected to the liquid input end 111 of the hydrogen water generator 10, the hydrogen production apparatus 20 is connected to the hydrogen input end 113 of the hydrogen water generator 10, the hydrogen water generation tank 50 is connected to the hydrogen water output end 112 of the hydrogen water generator 10, the cultivation area 60 is connected to one end of the hydrogen water pump 51, and the other end of the hydrogen water pump 51 is connected to the hydrogen water generation tank 50, wherein the water W and the hydrogen H respectively received by the liquid input end 111 and the hydrogen input end 113 can be combined inside the hydrogen water generator 10 into hydrogen water HW of micro-nano hydrogen bubbles, and the hydrogen water output end 112 of the hydrogen water generator 10 provides hydrogen water HW outputting the micro-nano hydrogen bubbles to the hydrogen water generation tank 50.

The hydrogen production equipment 20 can be any one of a petrochemical fuel hydrogen production device, an electrolyzed water hydrogen production device, a proton exchange membrane hydrogen production device, a solar hydrogen production device and the like, so that the hydrogen production equipment 20 can produce a large amount of high-purity hydrogen with the purity of more than 99.95 percent, and the hydrogen H produced by the hydrogen production equipment 20 is mixed with the water W supplied by the water pump 32 by the structural design of the hydrogen water generator 10 to form HW hydrogen water of micro-nano hydrogen bubbles, and then the HW hydrogen water is introduced into the hydrogen water production tank 50; therefore, the sectional area of the internal structure of the hydrogen water generator 10 is changed, so that the hydrogen gas H can be sucked into the water W, the gas molecular group of the hydrogen gas H can be broken by the speed of the water flow, and the hydrogen gas H can form a large number of micro-nano hydrogen bubbles without using a compressor to additionally pressurize the hydrogen gas H, so that the hydrogen gas H can be quickly dissolved in the water W for a long time to form the hydrogen water HW of the micro-nano hydrogen bubbles, the preparation of the hydrogen water HW can be completed in a short time, and the time for storing the hydrogen gas in the hydrogen water can be prolonged.

Referring to fig. 8 to 11 again, in an embodiment of the present invention, the cultivation area 60 may be any one or a combination of two or more of a plant cultivation area 61 (as shown in fig. 10), an animal cultivation area 62, or an aquaculture cultivation area 63. Further, please refer to fig. 9 to 10, wherein the cultivation area 60 is a plant cultivation area 61, and a sprinkling device 611 connected to the hydrogen water pump 51 and a hygrometer 612 for detecting the environmental humidity of the plant cultivation area 61 are further disposed in the plant cultivation area 61; thereby, the hydrogen water HW of micro-nano hydrogen bubbles is generated by the hydrogen water generator 10, and then the hydrogen water HW is injected into the sprinkling device 611 of the plant cultivation area 61 from the hydrogen water pump 51 of the hydrogen water generation tank 50, wherein the sprinkling device 611 is further provided with an ultrasonic oscillator (not shown) or an atomizing nozzle (not shown) for oscillating or atomizing the hydrogen water into small water droplets, and the HW is sprinkled into the plant cultivation area 61 through the sprinkling device 611, thereby effectively promoting the seed germination rate of plant cultivation, plant flowering time regulation, plant stress resistance improvement and quality improvement of agricultural products.

Furthermore, the present invention is applied to an embodiment of the compound cultivation system, wherein the cultivation area 60 is an animal cultivation area 62, the animal cultivation area 62 further comprises an animal cultivation diversion valve inlet end 621 and an animal cultivation circulation outlet end 622, wherein the animal cultivation circulation outlet end 622 is connected to an animal cultivation circulation pump 623, the animal cultivation circulation pump 623 is connected to the liquid input end 111 of the hydrogen water generator 10 through the diversion valve 64, and the animal cultivation diversion valve inlet end 621 of the animal cultivation area 62 is connected to the hydrogen water output end 112 of the hydrogen water generator 10, so as to form a hydrogen water HW of micro-nano hydrogen bubbles; wherein the animal breeding area 62 is further provided with an animal breeding level meter 624 and an animal breeding water quality detector (not shown), when the animal breeding level meter 624 or the animal breeding water quality detector detects impure water, the animal breeding circulating water outlet end 622 of the animal breeding area 62 discharges impure hydrogen water to the animal breeding circulating pump 623, and then discharges or circulates the impure hydrogen water through the diverter valve 64, thereby achieving the concept of waste water reuse; furthermore, the inlet end 621 of the animal breeding diversion valve is further provided with an ultrasonic oscillator (not shown) or an atomizing nozzle (not shown), whether the content of hydrogen H in the animal breeding area 62 is sufficient is detected through a control module 65, when the content of hydrogen H is insufficient, the hydrogen H generated by the hydrogen generating equipment 20 can be diverted to the inlet end 621 of the animal breeding diversion valve of the animal breeding area 62 through each diversion valve 64, and high-purity hydrogen is injected into the animal breeding area 62 through the diversion valve 64, so that the hydrogen content of HW in the hydrogen water in the animal breeding area 62 can be directly increased; therefore, a fixed amount of water W can be regularly introduced from the animal breeding branch valve inlet end 621, hydrogen H is introduced into the animal breeding area 62, hydrogen HW of micro-nano hydrogen bubbles generated by the water W is provided for the bred animals to drink, the actual conditions of the hydrogen level in the animal breeding area 62 and the water quality (or nutrient solution components) in the animal water tank can be monitored through the animal breeding level gauge 624 and the animal breeding water quality detector, the component in the nutrient solution can be adjusted by controlling the branch valve nutrient solution injection end (not shown) through the branch valve 64, and if the water quality is too bad, the nutrient solution or the wastewater to be replaced can be discharged from the branch valve drainage end (not shown) of the branch valve 64 through the control module 65; in addition, the aquaculture cultivation area 63 further comprises a flow controller (not shown) connected to the aquaculture cultivation circulating pump 633 for controlling the flow of the aquaculture water in the aquaculture cultivation area 60; and a water quality monitoring module (not shown) connected to the flow controller for detecting the quality of the cultivation water in the cultivation area 60 and obtaining water quality data, wherein the water quality data includes water temperature, oxidation-reduction potential, pH value, dissolved oxygen, ammonia nitrogen, total dissolved solids and conductivity; therefore, the constant amount of water in the cultivation area can be discharged to the water quality monitoring module through the flow controller, the water quality data is analyzed, the control module 65 controls the hydrogen production amount of the hydrogen production equipment 20 and the water inlet amount of the water pump according to the water quality data, if the water quality in the cultivation area 60 is deteriorated or deteriorated, the control module 65 controls the branch valve 64 to discharge waste water, the hydrogen pump 51 supplies fresh hydrogen water HW, and liquid level meters are respectively arranged to control the water levels of the hydrogen water production tank 50 and the cultivation area 60.

Referring to fig. 10, the cultivation area 60 is implemented as a plant cultivation area 61, a water spraying device 611 and a moisture meter 612 are installed in the plant cultivation area 61 to analyze whether the water required by the plant is sufficient, if the humidity is too low, the hydrogen water pump 51 is started through the control module 65, and the hydrogen water HW is guided from the hydrogen water production tank 50 to the water spraying device 611 at a certain pressure, and the water spraying device 611 is further installed with an ultrasonic oscillator (not shown) or an atomizing nozzle (not shown), and the hydrogen water HW is vibrated or atomized into small water drops to provide the water required by the plant; in addition, the hydrogen water production tank 50 can monitor whether the water amount and the hydrogen gas amount in the hydrogen water production tank 50 are sufficient or not through a hydrogen water level meter 52 and a hydrogen water quality meter (not shown), if the water amount and the hydrogen gas amount are insufficient, the control module 65 can instruct the water pump 32 to automatically fill water and the hydrogen production apparatus 20 can simultaneously produce hydrogen H to the hydrogen water generator 10 to form hydrogen water HW of micro-nano hydrogen bubbles, and then the hydrogen water HW of the micro-nano hydrogen bubbles is delivered to the hydrogen water production tank 50; by monitoring and collecting the data of all the ecosystems and analyzing the data, the remote control module 66 can adjust the ecosystems to different ecosystems at any time, and when the cultivation area 60 is the plant cultivation area 61, the hygrometer 612 can determine the frequency and duration of the watering and humidifying of the watering device 611.

Furthermore, in another embodiment of the present invention, the cultivation area 60 is the cultivation area 63, which further comprises an inlet port 631 of a diversion valve for aquaculture cultivation and an outlet port 632 of aquaculture cultivation circulation, wherein the outlet port 632 of aquaculture cultivation is connected to an aquaculture cultivation circulation pump 633, the aquaculture cultivation circulation pump 633 is connected to the liquid input port 111 of the hydrogen water generator 10 through the diversion valve 64, and the inlet port 631 of the diversion valve for aquaculture cultivation of the cultivation area 63 is connected to the output port 112 of the hydrogen water generator 10 to form the HW of micro-nano hydrogen bubbles, wherein the cultivation area 63 is further provided with an aquaculture liquid level meter 634 and an aquaculture water quality detector (not shown); when the water quality is detected to be impure by the aquaculture liquid level meter 634 or an aquaculture water quality detector, the aquaculture circulating water outlet end 632 of the aquaculture area 63 discharges impure hydrogen water to the aquaculture circulating pump 633, and then discharges or circulates the impure hydrogen water through the diverter valve 64, thereby achieving the concept of wastewater reuse; furthermore, the inlet port 631 of the aquaculture diversion valve is further provided with an ultrasonic oscillator (not shown) or an atomizing nozzle (not shown), when the control module 65 detects that the content of the hydrogen H in the aquaculture area 63 is insufficient, the hydrogen H generated by the hydrogen generation device 20 can be diverted to the inlet port 631 of the aquaculture diversion valve of the aquaculture area 63 through the diversion valves 64, and water and hydrogen are respectively injected into the hydrogen water generator 10 through the diversion valves 64, so that the hydrogen water HW of micro-nano hydrogen bubbles is formed in the aquaculture area 63, thereby increasing the hydrogen content of the aquaculture area 63; therefore, a fixed amount of water can be regularly introduced from an aquaculture water inlet end (not shown), the liquid level in the aquaculture area 63 and the nutrient solution component of hydroponic plants can be monitored by the aquaculture liquid level meter 634 and the aquaculture water quality detector (not shown), the component in the nutrient solution can be adjusted by controlling the branch valve nutrient solution injection end (not shown) through the branch valve 64, and if the water quality is too bad, the nutrient solution to be replaced can be discharged from the water outlet end of the branch valve 64 through the control module 65. Wherein, the cultivation area 60 is an aquaculture cultivation area 63, and the level meter and the water quality meter are used to determine when water W needs to be added, when hydrogen H needs to be added into the hydrogen water production tank 50, and the filling amount needs to be controlled, and the like, and the advantages of management, control, recording, analysis, and the like are transmitted to the control center 67 through the remote control module 66.

Referring to fig. 11, at least one direction dividing valve 64 is disposed on the hydrogen water pump 51, and the control module 65 controls the opening and closing of the hydrogen water pump 51 and divides the hydrogen water HW into the cultivation areas 60 through the direction dividing valve 64 to form a hydrogen water cultivation farm, so that the cultivation and cultivation environment can be effectively improved, and the environment can be prevented from being polluted; the hydrogen production device 20 can be selected from a plurality of hydrogen production devices, the hydrogen H produced by the hydrogen production device 20 is connected to the hydrogen input end 113 of the hydrogen water generator 10, the water outlet end of the water pump 32 is connected to the liquid input end 111 of the hydrogen water generator 10, so that the hydrogen water output end 112 of the hydrogen water generator 10 is connected to the hydrogen water production tank 50; in an embodiment of the present invention, the number of the hydrogen generation apparatuses 20 is two, but not limited thereto, and the hydrogen generation apparatuses 20 are mainly connected to the hydrogen water generator 10 through a plurality of hydrogen generation apparatuses 20, the hydrogen water generator 10 is connected to the hydrogen water production tank 50, so that the hydrogen content in the hydrogen water HW forming micro-nano hydrogen bubbles can be kept stable, and the hydrogen water production tank 50 can be used as a large hydrogen water storage tank, and the hydrogen water HW is divided to each of the cultivation areas 60 through the branch valve 64 of the hydrogen water pump 51, so as to form a composite cultivation field, which can effectively improve the cultivation and cultivation environment.

Referring to fig. 12, fig. 12 is a schematic structural view of a cleaning device according to the present invention. As shown in the drawings, the present invention is applied to a cleaning device capable of providing micro-nano hydrogen bubbles, which at least comprises: a hydrogen generating device 20, a water pump 32, a hydrogen water generator 10 and a cleaning device 70 as described above, wherein the hydrogen water generator 10 has the liquid input end 111 connected to the water outlet end of the water pump 32, the hydrogen input end 112 of the hydrogen water generator 10 connected to the hydrogen generating device 20, the hydrogen water output end 113 of the hydrogen water generator 10 is connected to the cleaning device 70, water W and hydrogen H respectively received through the liquid input end 111 and the hydrogen input end 112 can be combined inside the hydrogen water generator 10 into hydrogen water HW of micro-nano hydrogen bubbles, and the hydrogen water output end 113 of the hydrogen water generator 10 provides hydrogen water HW of the micro-nano hydrogen bubbles to the cleaning device 70; wherein the cleaning device 70 is any one of a shower head, a bathtub, or a faucet. Therefore, the sectional area of the internal structure of the hydrogen generator 10 is changed, so that the hydrogen H can be sucked into the water W, the gas molecular group of the hydrogen H can be broken by the speed of the water flow, the hydrogen H can form a large number of micro-nano hydrogen bubbles without using a compressor to additionally pressurize the hydrogen H, and the hydrogen H can be quickly dissolved in the water W for a long time to form the hydrogen HW of the micro-nano hydrogen bubbles, so that when a user opens the cleaning device capable of providing the micro-nano hydrogen bubbles, the dirt can be taken away by using the positive and negative attraction principle, and the effects of beauty treatment and deep cleaning can be achieved.

In addition, the water inlet end of the water pump 32 further includes a hydrogen water circulation end 321, the hydrogen water circulation end 321 is connected to the cleaning device 70, mainly pumping out the hydrogen water HW of the micro-nano hydrogen bubbles in the cleaning device 70 and performing a closed circulation through the water pump 32, so as to increase the content of the micro-nano hydrogen bubbles in the hydrogen water HW of the micro-nano hydrogen bubbles (as shown in fig. 12), wherein the cleaning device 70 is a bathtub; in another embodiment, the present invention is applied to a cleaning device, wherein the cleaning device 70 is a shower head or a faucet, the water pump 32 further comprises a water source input end (not shown) connected to a water supply device 30, the water W supplied by the water supply device 30 enters from the water inlet end of the water pump 32, is transmitted to the liquid input end 111 of the hydrogen water generator 10 through the water outlet end of the water pump 32, and is introduced into the hydrogen gas H produced by the hydrogen production device 20 through the hydrogen gas input end 112 of the hydrogen water generator 10, dissolving hydrogen H in water W to form hydrogen water HW of micro-nano hydrogen bubbles, and introducing the hydrogen water HW of micro-nano hydrogen bubbles into the cleaning device 70 through the hydrogen water output terminal 113 of the hydrogen water generator 10, thereby being used for bathing or foot bathing or bathing of a user to achieve the advantages of deep cleaning or beauty and skin care. Moreover, when a user operates the cleaning device, the dirt attached to the upper side part of the human skin layer is taken away by flushing the hydrogen water of the micro-nano hydrogen bubbles generated by the cleaning device, and the dirt is easily taken away because most of the dirt is positively charged and the micro-nano hydrogen bubbles form a large amount of negative charges when being generated, and the micro-nano hydrogen bubbles and the dirt are attracted to each other when approaching to each other and the pressure of the bubbles during explosion and the buoyancy of air in water are added. Moreover, the micro-nano hydrogen bubbles are very tiny and can penetrate into various tiny gaps for deep cleaning, the size of human skin pores is generally about 20-150 nm, and the size of the micro-nano bubbles is only about 1-10 nm, so the hydrogen water HW of the micro-nano bubbles can easily enter, dirt can be taken away by utilizing the principle that the micro-nano bubbles attract each other positively and negatively, and the beautifying effects of deep cleaning, sterilization, cell activation, nerve calming, consciousness restoring, fatigue elimination and the like are achieved.