CN216687587U - Hydrogen-rich water's preparation facilities - Google Patents

Abstract

The utility model relates to a hydrogen-rich water's preparation facilities relates to drinking water equipment's field, and it includes the organism, has water inlet and delivery port, and the organism includes: the water purification module is connected with the water inlet and is used for receiving and treating water of an external water source; the water storage module is connected with the water purification module and is used for receiving and storing the water treated by the water purification module; the hydrogen production module is connected with the water storage module and is used for producing hydrogen by utilizing water flowing out of the water storage module; one end of the first mixing module is communicated with the water storage module and the hydrogen production module, and the other end of the first mixing module is connected with the water outlet and arranged between the hydrogen production module and the water outlet for mixing hydrogen and water generated by the hydrogen production module and continuously flowing out of the water outlet. The problem that the purified water does not contain substances harmful to the human body, but does not contain mineral substances, rare elements and the like beneficial to the human body, and the water is acidic and is harmful to health if being drunk frequently is solved.

Description

Hydrogen-rich water's preparation facilities

Technical Field

The application relates to the field of drinking water equipment, in particular to a preparation device of hydrogen-rich water.

Background

Along with the gradual improvement of the living standard and the understanding of the importance of water quality, the requirement of people on the water quality is also continuously improved. At present, a large amount of drinking water purifiers enter common families, the purification levels of the water purifiers are more, the water purification effect is good, purified water can be directly drunk, and the safety is higher.

In view of the above-mentioned related technologies, the inventor believes that the purified water of the water dispenser is only purified water, the purified water does not contain substances harmful to human bodies, but does not contain minerals, rare elements and the like beneficial to human bodies, and the water is acidic, so that the water is not good for health if being drunk frequently, and there is room for improvement.

SUMMERY OF THE UTILITY MODEL

The application provides a preparation device of hydrogen-enriched water in order to improve the problems that purified water does not contain substances harmful to human bodies, does not contain minerals, rare elements and the like beneficial to human bodies, is acidic in water and is not beneficial to health if being drunk in many ways.

The application provides a preparation facilities of hydrogen-rich water adopts following technical scheme:

an apparatus for preparing hydrogen-rich water, comprising a body having a water inlet and a water outlet for receiving and treating water from an external source and flowing out the treated water, the body comprising:

the water purification module is arranged in the machine body, is connected with the water inlet and is used for receiving and treating water of an external water source;

the water storage module is connected with the water purification module and is used for receiving and storing the water treated by the water purification module;

the hydrogen production module is connected with the water storage module and is used for producing hydrogen by utilizing water flowing out of the water storage module;

one end of the first mixing module is communicated with the water storage module and the hydrogen production module, and the other end of the first mixing module is connected with the water outlet and arranged between the hydrogen production module and the water outlet for mixing hydrogen and water generated by the hydrogen production module and continuously flowing out of the water outlet.

By adopting the technical scheme, the hydrogen element is mixed with the purified water after the water is purified, and the hydrogen element is mixed with the slightly acidic water, so that the water is purified and becomes alkalescent, the drinking water is more suitable for human bodies, and the health of the human bodies after drinking water is ensured.

Optionally, the first mixing module comprises

The first booster pump is connected with the water storage module and used for driving water in the water storage module to flow to the water outlet and the hydrogen production module;

the first double-channel waste water pen is arranged between the first booster pump and the water outlet, connected with the hydrogen production module and the first booster pump and used for mixing hydrogen and water generated by the hydrogen production module and continuously flowing out of the water outlet.

By adopting the technical scheme, the first booster pump promotes water in the water storage module to flow to the water outlet and flow to the hydrogen production module in the flowing process, so that the raw material supply efficiency of the hydrogen production module is improved; the first double-channel waste water pen enables hydrogen generated by the hydrogen production module to be mixed with water flowing out of the first booster pump, so that water flowing to the water outlet is enriched and hydrogenated, and the efficiency of mixing water and hydrogen is improved.

Optionally, still include the second and mix the module, the second mixes module and first mixed module and delivery port and links to each other, the second mixes the module and is provided with at least a set of, the second mixes the module and includes second booster pump and second dual-channel waste water pen, the quantity of second booster pump and second dual-channel waste water pen is the same and consecutive interval links to each other.

Through adopting above-mentioned technical scheme, through setting up the second mixing module for the water after the first mixing module mixes once more, mixes more fully.

Optionally, the hydrogen production module comprises

The hydrogen production device is provided with a pure water inlet, a hydrogen outlet and a waste outlet and is used for decomposing water into hydrogen and oxygen;

the first waste water pen is arranged between the first booster pump and the hydrogen production device, is communicated with the pure water inlet, and is used for locally discharging water flowing out of the first booster pump and flowing into the hydrogen production device;

and the first check valve is arranged between the first double-channel waste water pen and the hydrogen production device and is used for preventing water flowing from the first booster pump to the first double-channel waste water pen from flowing into the hydrogen production device from the hydrogen outlet.

By adopting the technical scheme, the water flowing out of the first booster pump can partially flow to the hydrogen production device through the first waste water pen, so that the convenience and the fluency of water taking of the hydrogen production device are improved; and the setting of first check valve for rivers are difficult for leading to the fact the unable circumstances of flowing out of hydrogen to take place in hydrogen plant from the hydrogen export inflow when first booster pump flows to first double channel waste water pen, have improved the smoothness nature of hydrogen manufacturing.

Optionally, the device further comprises a foaming module which comprises

The driving sub-module is connected with the second mixing module and is used for driving water flowing out of the second mixing module to move towards the water outlet;

and the non-return submodule is connected with the driving submodule and the water outlet and is used for preventing water from returning to the reverse flow.

By adopting the technical scheme, the arrangement of the foaming module increases the pressure of water flowing out of the second mixing module and increases the driving force on the one hand; on the other hand, further drive the hydrogen-rich water intensive mixing who mixes hydrogen, improved hydrogen water mixing efficiency.

Optionally, the drive submodule includes at least one second waste water pen, the second waste water pen links to each other and links to each other with the second mixing module end to end in proper order, the non return submodule includes at least one second check valve, the second check valve end to end in proper order and drive submodule continuous.

Through adopting above-mentioned technical scheme, form the foaming device through waste water pen and check valve, simple structure, the foaming is efficient, and the device is small and exquisite, and it is little to install to take up space in the box, has improved the small and exquisite nature of box.

Optionally, the water storage device further comprises a backflow module, the backflow module is arranged between the foaming module and the water outlet, one end of the backflow module is connected with the foaming module, and the other end of the backflow module is connected with the water storage module.

By adopting the technical scheme, on one hand, the backflow module can control the amount of the hydrogen-rich water flowing out of the water outlet, so that when the amount of the water flowing out of the foaming module is larger than that of the water outlet, a place can be used for flowing out; on the other hand, when the water flowing out of the water outlet does not meet the requirement, the water can be returned to the water tank through the backflow module to be subjected to hydrogen enrichment treatment again, and the manufacturing stability of the hydrogen-enriched water is improved.

Optionally, the water storage module comprises

The water tank is connected with the water purification module and is used for storing water flowing out after the water purification module purifies water;

and the inner container is connected with the water tank and the water outlet and is used for heating the water which does not flow to the first mixing module in the water tank.

Through adopting above-mentioned technical scheme, the setting of inner bag for the water of water tank internal part can heat the utilization, makes when going out water and hydrogen-rich water mixes the temperature that improves hydrogen-rich water, can be fit for the user and drink when winter, has improved hydrogen-rich water's preparation facilities's application range.

Optionally, a low level liquid level sensor is arranged in the water tank.

Through adopting above-mentioned technical scheme, low level sensor's setting for the liquid level in the water tank can obtain the control, thereby opens preceding solenoid valve and starts water purification module work when the liquid level is lower, and supplements the water in the water tank with the water among the water purification module inflow water tank.

Optionally, a floating ball is arranged in the water tank.

Through adopting above-mentioned technical scheme, the setting of floater for the water yield size in the water tank can obtain control, and when the water yield reachd certain height, the floater moves up to certain high back, closes the solenoid valve of intaking, makes rivers difficult for continuing to flow into in the water tank and make the rivers in the water tank spill over, has improved the stability of the water yield control in the water tank.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the hydrogen element is mixed with the purified water after the water is purified, and the hydrogen element is mixed with the water which is slightly acidic, so that the water is purified and is weakly alkaline, the water is more suitable for human bodies to drink, and the health of the human bodies after drinking is ensured;

2. by arranging the second mixing module, the water mixed by the first mixing module is mixed again, so that the mixing is more sufficient;

3. the setting of foaming module, the increase is from the pressure of the water that the second mixing module flows out, and the increase is driven power, further orders about the hydrogen-rich water intensive mixing who thoughtlessly has hydrogen, has improved hydrogen water mixing efficiency.

Drawings

FIG. 1 is a schematic diagram of a system of a water storage module, a first mixing module, a hydrogen production module, a second mixing module, and a foaming module in an embodiment of the present application.

Fig. 2 is a system schematic of a water purification module in an embodiment of the present application.

Fig. 3 is a schematic diagram of the structure of the first mixing module, the hydrogen production module, the second mixing module, and the foaming module in an embodiment of the present application.

Description of reference numerals: 1. a body; 11. a water purification module; 111. a melt blown fiber filter element; 1111. a raw water TDS sensor; 112. a third booster pump; 1121. a low voltage switch; 1122. a water inlet electromagnetic valve; 113. a front activated carbon filter element; 114. compressing the activated carbon filter element; 115. a reverse osmosis membrane; 1151. a pure water TDS sensor; 1152. a waste discharge electromagnetic valve; 1153. a waste water port; 116. a pressure barrel; 1161. a high voltage switch; 117. a flow meter; 118. an external water delivery and distribution interface; 12. a water storage module; 121. a water tank; 1211. a first solenoid valve; 1212. a floating ball; 1213. a low level liquid level sensor; 122. an inner container; 1221. a hot water outlet; 1222. a hot water solenoid valve; 13. a hydrogen production module; 131. a hydrogen production unit; 1311. a pure water inlet; 1312. a hydrogen outlet; 1313. a waste outlet; 132. a first waste pen; 133. a first check valve; 134. a third check valve; 14. a first mixing module; 141. a first booster pump; 142. a first dual channel waste pen; 15. a second mixing module; 151. a second booster pump; 152. a second dual channel waste pen; 16. a foaming module; 161. a drive sub-module; 1611. a second waste pen; 162. a non-return sub-module; 1621. a second check valve; 1622. a normal temperature check valve; 17. a reflow module; 171. a fourth check valve; 18. a water inlet; 19. and (7) a water outlet.

Detailed Description

The present application is described in further detail below with reference to figures 1-3.

The embodiment of the application discloses hydrogen-rich water's preparation facilities. Referring to fig. 1 and 2, a hydrogen-rich water preparation apparatus includes a body 1, and the body 1 includes a water purification module 11, a water storage module 12, a hydrogen production module 13, a first mixing module 14, a second mixing module 15, a foaming module 16, and a backflow module 17.

The body 1 has a water inlet 18 and a water outlet 19 so that the hydrogen-rich water preparing apparatus inserts water of an external water source into the body 1 and discharges the treated water. The water purification module 11 is in communication with the water inlet 18 via a pipe for sterilizing and purifying the incoming water so that the water flowing out of the water purification module 11 is relatively pure. The water storage module 12 is communicated with the water purification module 11 through a pipeline and is used for receiving and storing water treated by the water purification module 11. The hydrogen production module 13 is communicated with the water storage module 12 through a pipeline and is used for producing hydrogen by using water flowing out of the water storage module 12. The first mixing module 14 is communicated with the water storage module 12 and the hydrogen production module 13 through pipelines and is used for mixing hydrogen produced by the hydrogen production module 13 with water flowing out of the water storage module 12. The second mixing module 15 is in communication with the first mixing module 14 via a conduit for further mixing the hydrogen and water flowing from the first mixing module 14 again. The foaming module 16 is connected with the second mixing module 15 for linearly dispersing the water flowing out of the second mixing module 15 so as to allow sufficient contact mixing of hydrogen and water, and the foaming module 16 is further communicated with the water outlet 19 through a pipe to supply the outflow of the purified water rich in hydrogenation. One end of the backflow module 17 is communicated with the foaming module 16 through a pipeline, and the other end of the backflow module is communicated with the water storage module 12, so that purified water flowing out of the foaming module 16 flows back into the water storage module 12.

Referring to fig. 1 and 2, the water purification module 11 includes a meltblown fiber filter cartridge 111, a low pressure switch 1121, a raw water TDS sensor 1111, a water inlet solenoid valve 1122, a third booster pump 112, a pre-activated carbon filter cartridge 113, a compressed activated carbon filter cartridge 114, a reverse osmosis membrane 115, a pure water TDS sensor 1151, a pressure tank 116, a high pressure switch 1161, a flow meter 117, and a waste discharge solenoid valve 1152. The melt-blown fiber filter element 111 is communicated with the water inlet 18 through a pipeline to filter strong acid, strong alkali and organic solvent. The third booster pump 112 is communicated with the melt-blown fiber filter element 111 through a pipeline, and the water pressure of the water flow filtered by the melt-blown fiber filter element 111 is increased, so that the water flow is enabled to flow along the pipeline. The low pressure switch 1121 is installed between the booster pump and the meltblown fiber cartridge 111, and is used to detect the water pressure flowing in a pipe connecting the booster pump and the meltblown fiber cartridge 111, and when the external water pressure is insufficient, the low pressure switch 1121 is turned off to prevent the third booster pump 112 from idling. The raw water TDS sensor 1111 is installed between the third booster pump 112 and the meltblown fiber filter element 111, and is used to detect the quality of the raw water passing through the meltblown fiber filter element 111, so as to conveniently check whether the meltblown fiber filter element 111 is working normally. The water inlet electromagnetic valve 1122 is installed between the third booster pump 112 and the melt-blown fiber filter element 111, and is located behind the low pressure switch 1121 and the raw water TDS sensor 1111, and is used for opening or closing a water inlet pipeline.

The pre-activated carbon filter element 113, the compressed activated carbon filter element 114 and the reverse osmosis membrane 115 are sequentially installed behind the third booster pump 112 and are communicated with each other through pipelines, and further purify and sterilize the raw water. After passing through the pre-activated carbon filter 113, the compressed activated carbon filter 114, and the reverse osmosis membrane 115, the raw water is divided into two streams, one of which is pure water and the other is wastewater.

The body 1 is further provided with a waste water port 1153, and one end of the reverse osmosis membrane 115 from which waste water flows is communicated with the waste water port 1153 for discharging waste water. The waste discharge solenoid valve 1152 is installed between the reverse osmosis membrane 115 and the waste water port 1153 and is communicated with one end of the reverse osmosis membrane 115 from which waste water flows through a pipe for controlling the outflow of the waste water.

The pure water TDS sensor 1151 is installed behind the reverse osmosis membrane 115 and is in pipe communication with one end of the reverse osmosis membrane 115 from which pure water flows, for checking whether the front activated carbon filter cartridge 113, the compressed activated carbon filter cartridge 114, and the reverse osmosis membrane 115 are normally operated. The pressure tank 116 and the pure water TDS sensor 1151 are in communication via a conduit for balancing the amount and pressure of water in the conduit. The high voltage switch 1161 is installed after the pure water TDS sensor 1151 and is in communication with the pressure tank 116 through a pipe. When the pressure barrel 116 is full of water and reaches a certain pressure value, the high-voltage switch 1161 is turned on, the power supply is cut off, the water purification module 11 stops working, when the pressure barrel 116 is full of water, the pressure is reduced, the high-voltage switch 1161 is turned off, and the water purification module 11 starts to work. The flow meter 117 is installed behind the high-voltage switch 1161 and is communicated with the high-voltage switch 1161 for sensing the water output of the purified water.

Referring to fig. 1 and 2, the body 1 further has an external water delivery interface 118, and the water purification module 11 is connected to the water meter 117 through a pipe. The water flowing out through the water purification module 11 flows out through the water outlet port 118, and the other water flows into the water storage module 12.

The water storage module 12 includes a water tank 121 and an inner container 122. The water tank 121 is installed behind the flow meter 117 and is in communication with the flow meter 117 through a pipe for receiving water flowing out of the water purification module 11. A first solenoid valve 1211 is also mounted on the pipe between the water tank 121 and the flow meter 117 to control the amount of water flowing into the water tank 121. A float 1212 and a low level sensor 1213 are installed in the water tank 121, and the float 1212 may be mechanical or electronic, or a combination of the two, and is used for sensing the water level in the water tank 121 to control the closing of the first solenoid 1211. And the low level sensor 1213 may detect the lowest water level in the water tank 121. When the water in the water tank 121 is high, the float 1212 rises to close the first solenoid valve 1211, so as to reduce the water flowing into the water tank 121 from the water purification module 11, and when the water in the water tank 121 goes low, the low level liquid level sensor 1213 receives a sensing signal, so as to open the first solenoid valve 1211, so that the water flows into the water tank 121 from the water purification module 11, and the water level in the water tank 121 is ensured.

The water tank 121 has two water outlet ends, and the inner container 122 is communicated with one of the water outlet ends, so that water in the water tank 121 flows into the inner container 122 to be heated. The body 1 further has a hot water outlet 1221, the inner container 122 and the hot water outlet 1221 are communicated with each other to discharge hot water, and the inner container 122 is further communicated with the water outlet 19 to discharge hot water from the water outlet 19. A hot water solenoid valve 1222 is installed between the inner container 122 and the water outlet 19 to control the outflow of hot water.

Referring to fig. 1 and 3, the first mixing module 14 includes a first pressurizing pump 141 and a first dual-channel waste pen 142. The first booster pump 141 is in communication with the other outlet end of the water tank 121 for boosting the water flowing out of the water tank 121, thereby driving the water locally in the water tank 121 to flow into the first mixing module 14. The first dual channel waste pen 142 is installed after the first pressurizing pump 141 and is communicated with the first pressurizing pump 141 and the hydrogen production module 13, and a part of water of the first pressurizing pump 141 flows into the hydrogen production module 13 and the other part of water flows into the first dual channel waste pen 142. When the hydrogen gas in the hydrogen production module 13 flows into the first dual-channel waste water pen 142, the pure water flowing from the first pressurizing pump 141 into the first dual-channel waste water pen 142 and the hydrogen gas moving from the hydrogen production module 13 into the first pressurizing pump 141 are mixed to form preliminary hydrogen-rich water.

Referring to fig. 1 and 3, hydrogen generation module 13 includes a hydrogen generation device 131, a first waste pen 132, and a first check valve 133. Hydrogen production apparatus 131 may be any apparatus capable of electrolyzing water into hydrogen gas and oxygen-containing compound or oxygen gas. The hydrogen plant 131 has a pure water inlet 1311, a hydrogen outlet 1312, and a waste outlet 1313. The pure water inlet 1311 and the first booster pump 141 are connected by a pipe for receiving pure water flowing out of the first booster pump 141. The first waste water pen 132 is installed between the first pressurizing pump 141 and the hydrogen plant 131 and is in communication with the first pressurizing pump 141 through a pipe so that water flowing out of the first pressurizing pump 141 is divided into two and one can flow into the pure water inlet 1311 through the first waste water pen 132. The hydrogen outlet 1312 of the hydrogen generating apparatus 131 and the first dual channel waste pen 142 are communicated through a pipe to supply hydrogen to the first dual channel waste pen 142 through the hydrogen outlet 1312 to be mixed. The first check valve 133 is installed between the hydrogen production device 131 and the first dual-channel waste water pen 142 and is communicated with the hydrogen production device 131 through a pipeline, so that water directly flowing from the first booster pump 141 to the first dual-channel waste water pen 142 is not easy to flow back into the hydrogen production device 131 from the hydrogen outlet 1312 to affect the output of hydrogen from the hydrogen outlet 1312. The waste outlet 1313 of the hydrogen production apparatus 131 and the waste water port 1153 of the body 1 are communicated through a pipe to discharge oxygen-containing water or oxygen. A third check valve 134 is also installed between the waste outlet 1313 and the waste port 1153 so that waste water is not easily returned into the hydrogen plant 131.

Referring to fig. 1 and 3, the number of the second mixing modules 15 is at least one, and if the number of the second mixing modules 15 is greater than or equal to two, the multiple groups of second mixing modules 15 are connected in series in sequence to further mix the hydrogen-rich water, which is taken as an example in the embodiment of the present application. The second mixing module 15 includes a second pressurizing pump 151 and a second dual-channel waste water pen 152, the number of the second pressurizing pump 151 and the second dual-channel waste water pen 152 is the same, and when the number of the second mixing module 15 is several, the second pressurizing pump 151 and the second dual-channel waste water pen 152 are spaced apart. The second pressurizing pump 151 is in communication with the first dual-channel waste pen 142 through a pipe to pressurize the hydrogen-rich water mixed in the first dual-channel waste pen 142 to continue to flow forward along the pipe. The second dual-passage waste water pen 152 is in communication with the second pressurizing pump 151 through a pipe to further mix the hydrogen-rich water pressurized by the second pressurizing pump 151.

Referring to fig. 1 and 3, the foaming module 16 includes a drive sub-module 161 and a non-return sub-module 162. The driving sub-module 161 is connected to the second mixing module 15 for driving the water of the second mixing module 15 to go on. The driving sub-module 161 includes at least one second waste pen 1611, and when the number of the second waste pens 1611 is more than one, the second waste pens 1611 are connected end to end in sequence, and the second waste pen 1611 closest to the second mixing module 15 is communicated with the second dual-channel waste pen 152, so as to drive the water flowing out from the second mixing module 15 to move to the water outlet 19. The check submodule 162 is connected to the drive submodule 161 to prevent the water from returning back to the reverse flow. The check submodule 162 includes at least one second check valve 1621, and when the second check valve 1621 is more than one, the second check valve 1621 is end to end connected in proper order, and the second check valve 1621 closest to the drive submodule 161 and the second waste water pen 1611 are communicated through a pipeline to prevent flowing back from the second check valve 1621 into the drive submodule 161. The second check valve 1621, furthest from the driver sub-module 161, communicates with the water outlet 19 to allow the flow of the bubbled hydrogen-rich water. A normal temperature solenoid valve 1622 is further provided between the second check valve 1621 farthest from the driving submodule 161 and the water outlet 19 to control the flow rate and the flow rate of the hydrogen-rich water flowing out of the water outlet 19.

Referring to fig. 1 and 3, the second check valve 1621 farthest from the driving sub-module 161 also communicates with the water tank 121 through the backflow module 17 to backflow water passing through the first mixing module 14, the second mixing module 15, the hydrogen generation module 13, and the foaming module 16 into the water tank 121 when the water does not flow out of the water outlet 19. The backflow module 17 includes a fourth check valve 171, one end of the fourth check valve 171 communicates with the second check valve 1621 farthest from the driving sub-module 161 through a pipe, and the other end communicates with the water tank 121 through a pipe, so as to prevent water in the water tank 121 from directly flowing from the backflow module 17 into the water outlet 19.

The implementation principle of the preparation facilities of this application embodiment hydrogen-rich water is: water from a water source enters the machine body 1 from the water inlet 18, then flows into the water storage module 12 after being purified by the water purification module 11, part of water in the water storage module 12 flows through the hydrogen production module 13 to produce hydrogen, the other part of water flows into the first mixing module 14 to be mixed with the hydrogen produced by the hydrogen production module 13, then is further mixed by the second mixing module 15, is foamed by the foaming module 16, and finally flows out from the water outlet 19.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (10)

1. A preparation facilities of hydrogen-rich water which characterized in that: comprising a body (1) having a water inlet (18) and a water outlet (19) for receiving and treating water from an external source and effluent treated water, said body (1) comprising:

the water purification module (11) is arranged on the machine body (1), is connected with the water inlet (18) and is used for receiving and treating water of an external water source;

the water storage module (12) is connected with the water purification module (11) and is used for receiving and storing the water treated by the water purification module (11);

the hydrogen production module (13) is connected with the water storage module (12) and is used for producing hydrogen by using water flowing out of the water storage module (12);

and one end of the first mixing module (14) is communicated with the water storage module (12) and the hydrogen production module (13), and the other end of the first mixing module is connected with the water outlet (19) and arranged between the hydrogen production module (13) and the water outlet (19) for mixing hydrogen and water generated by the hydrogen production module (13) and continuously flowing out of the water outlet (19).

2. The apparatus for producing a hydrogen-rich water according to claim 1, characterized in that: the first mixing module (14) comprises

The first booster pump (141) is connected with the water storage module (12) and is used for driving water in the water storage module (12) to flow to the water outlet (19) and the hydrogen production module (13);

and the first double-channel waste water pen (142) is arranged between the first booster pump (141) and the water outlet (19), is connected with the hydrogen production module (13) and the first booster pump (141), and is used for mixing hydrogen and water generated by the hydrogen production module (13) and continuously flowing out of the water outlet (19).

3. The apparatus for producing a hydrogen-rich water according to claim 2, characterized in that: still include second mixing module (15), second mixing module (15) and first mixing module (14) and delivery port (19) link to each other, second mixing module (15) are provided with at least a set of, second mixing module (15) include second booster pump (151) and second dual-channel waste water pen (152), the quantity of second booster pump (151) and second dual-channel waste water pen (152) is the same and consecutive interval links to each other.

4. The apparatus for producing a hydrogen-rich water according to claim 2, characterized in that: the hydrogen production module (13) comprises

A hydrogen production apparatus (131) having a pure water inlet (1311), a hydrogen outlet (1312), and a waste outlet (1313) for splitting water into hydrogen and oxygen;

the first waste water pen (132) is arranged between the first booster pump (141) and the hydrogen production device (131), is communicated with the pure water inlet (1311), and is used for locally discharging water discharged from the first booster pump (141) and flowing into the hydrogen production device (131);

and a first check valve (133) provided between the first dual-passage waste pen (142) and the hydrogen production device (131) and preventing water flowing from the first booster pump (141) to the first dual-passage waste pen (142) from flowing into the hydrogen production device (131) from the hydrogen outlet (1312).

5. The apparatus for producing a hydrogen-rich water according to claim 3, characterized in that: further comprising a frothing module (16), said frothing module (16) comprising

The driving sub-module (161) is connected with the second mixing module (15) and is used for driving the water flowing out of the second mixing module (15) to move towards the water outlet (19);

and the check submodule (162) is connected with the driving submodule (161) and the water outlet (19) and is used for preventing water from returning and reversely flowing.

6. The apparatus for producing a hydrogen-rich water according to claim 5, characterized in that: drive submodule piece (161) includes at least one second waste water pen (1611), second waste water pen (1611) end to end and link to each other with second mixing module (15) in proper order, non return submodule piece (162) includes at least one second check valve (1621), second check valve (1621) end to end and link to each other with drive submodule piece (161) in proper order.

7. The apparatus for producing a hydrogen-rich water according to claim 5, characterized in that: still include backward flow module (17), backward flow module (17) are located between foaming module (16) and delivery port (19) and one end links to each other with foaming module (16), the other end of backward flow module (17) links to each other with water storage module (12).

8. The apparatus for producing a hydrogen-rich water according to claim 1, characterized in that: the water storage module (12) comprises

The water tank (121) is connected with the water purification module (11) and is used for storing water flowing out after the water purification module (11) purifies water;

and the inner container (122) is connected with the water tank (121) and the water outlet (19) and is used for heating the water which does not flow to the first mixing module (14) in the water tank (121).

9. The apparatus for producing hydrogen-rich water according to claim 8, characterized in that: and a low-level liquid level sensor (1213) is arranged in the water tank (121).

10. The apparatus for producing a hydrogen-rich water according to claim 8, characterized in that: a floating ball (1212) is arranged in the water tank (121).

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