CN210855422U - Nanoscale hydrogen bubble water preparation system - Google Patents

Abstract

The utility model relates to a nanometer hydrogen bubble water preparation system, including feed water tank, hydrogen plant, ionization device, mixed water tank, water pump I, water pump II, electromagnetism three-way valve and controlling means. The water pump I is installed on a pipeline between the water supply tank and the hydrogen production device, the water pump II is arranged on the pipeline between the water supply tank and the mixed water tank, and a hydrogen discharge pipe of the hydrogen production device penetrates into the mixed water tank. The utility model discloses can be the nanometer with the bubble diameter cutting of aquatic hydrogen for the quantity of hydrogen bubble can reach 13 hundred million in per milliliter mixing water, makes the content of hydrogen be higher than the index of high concentration mixing water 2 ~ 5ppm in the hydrogen-rich water, and is more ideal to the treatment of disease and prevention effect. Meanwhile, the mixed water is ionized, so that the viscosity of the nano-scale hydrogen bubbles is enhanced, and the rising speed of the hydrogen bubbles in the mixed water is reduced under the room temperature and atmospheric pressure condition, thereby being beneficial to long-term storage and drinking.

Description

Nanoscale hydrogen bubble water preparation system

Technical Field

The utility model belongs to the technical field of the water processing, concretely relates to is a nanometer hydrogen bubble water preparation system.

Background

Hydrogen water is water containing hydrogen as its name implies, and since the medical effect and biological effect of hydrogen have been found, international medical and biological circles have been actively studied in recent years. The hydrogen has selective antioxidation, is harmful to organisms, and can actively and selectively combine with the free radicals to generate water. The medical community generally considers the theory of free radicals as one of the root causes of disease and aging. The hydrogen selectively neutralizes harmful free radicals, provides a treatment method for diseases caused by oxidative damage, and more importantly provides a prevention measure for preventing the diseases and the aging of the human body. Hydrogen is the lightest of all elements and exists in a gaseous form at normal temperature and pressure. One of the methods for human body to utilize hydrogen is to dissolve hydrogen into high-purity water, and then the hydrogen enters into human body by using water as carrier, and then the hydrogen is diffused in human body so as to play a role of reduction on the oxidation of human body caused by harmful free radicals. Hydrogen has low solubility in water and is difficult to store, and how to dissolve hydrogen in water as much as possible and store hydrogen well becomes an important index for measuring hydrogen water.

At present, drinking hydrogen water is prepared by adopting a micro-electrolysis hydrogen-rich water activating cup, the preparation time is about 5 minutes generally, and the hydrogen concentration is about 900-. However, hydrogen is soluble in water up to 1.6mg/L at room temperature under atmospheric pressure. Therefore, the hydrogen water prepared by adopting the micro-electrolysis hydrogen-rich running water cup needs to be drunk up in a short time, otherwise, the hydrogen gas gradually volatilizes and loses the drinking value.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is: overcome prior art's not enough, provide a nanometer hydrogen bubble water preparation system, the utility model discloses can cut the bubble diameter of aquatic hydrogen for the nanometer for the quantity of hydrogen bubble can reach 13 hundred million in per milliliter mixing water, makes the content of hydrogen be higher than the index of high concentration mixing water 2 ~ 5ppm in the hydrogen-rich water, and is more ideal to the treatment of disease and prevention effect. Meanwhile, the mixed water is ionized, so that the viscosity of the nano-scale hydrogen bubbles is enhanced, and the rising speed of the hydrogen bubbles in the mixed water is reduced under the room temperature and atmospheric pressure condition, thereby being beneficial to long-term storage and drinking.

The utility model provides a technical scheme that the problem that prior art exists adopted is:

a nanoscale hydrogen bubble water preparation system comprises a water supply tank, a hydrogen production device, an ionization device, a mixed water tank, a water pump I, a water pump II, an electromagnetic three-way valve and a control device.

And the water pump I is arranged on a pipeline between the water supply tank and the hydrogen production device.

The water pump II is arranged on a pipeline between the water supply tank and the mixed water tank, the outlet of the water pump II is communicated with the inlet of the electromagnetic three-way valve through a pipeline, and an ionization device is arranged on the pipeline between the electromagnetic three-way valve and the water supply tank.

Two outlets of the electromagnetic three-way valve are respectively connected with a mixed water tank inlet pipe and a mixer inlet pipe in a through way, and the mixed water tank inlet pipe is connected with the mixed water tank in a through way.

The mixing water tank on be equipped with hydrogen bubble water discharge pipe, mixing water tank inside be equipped with the blender, the blender include hybrid tube, high-pressure water cavity, drainage orifice and bubble cutting orifice, annular high-pressure water cavity cover is located on the hybrid tube, a plurality of drainage orifice and a plurality of bubble cutting orifice set up on the periphery that the hybrid tube is in the high-pressure water cavity parcel, the bubble cutting orifice is arranged perpendicularly, the drainage orifice slope is arranged, drainage orifice slope direction compares in hybrid tube surface opening position and more is close to bubble cutting orifice direction in hybrid tube surface opening position for hybrid tube surface opening position, blender inlet tube and high-pressure water cavity through connection.

The hydrogen produced by the hydrogen production device is discharged through a hydrogen discharge pipe, and the tail end of the hydrogen discharge pipe penetrates into the mixing pipe.

And the water pump I, the water pump II and the electromagnetic three-way valve are respectively electrically connected with the control device.

Preferably, the axis of the pipeline at the tail end of the hydrogen discharge pipe coincides with the axis of the mixing pipe, and the outlet of the pipeline at the tail end of the hydrogen discharge pipe and the bubble cutting spray hole are respectively positioned on two sides of the drainage spray hole.

Preferably, the drainage spray holes and the bubble cutting spray holes are conical holes, and the diameters of openings of the drainage spray holes and the bubble cutting spray holes on the inner surface of the mixing pipe are larger than the diameter of the opening on the outer surface of the mixing pipe.

Preferably, a plurality of inclined flow mixing plates are arranged in the mixing pipe in a staggered mode, and the flow mixing plates are arranged between the tail end of the hydrogen discharge pipe and the drainage spray holes.

Preferably, the ionization device comprises a shell and a plurality of negative ion balls, the negative ion balls are filled in the shell, and two ends of the shell are respectively connected with pipelines in a through mode.

Preferably, the blender inlet tube on set up in booster pump and pressure sensor, pressure sensor set up between booster pump and electromagnetism three-way valve, booster pump and pressure sensor respectively with controlling means electric connection.

Preferably, the control device adopts a PLC.

Preferably, the feed water tank front end connect gradually filter equipment, water pump III and first water tank, water pump III pass through the pipe-line pump with the inside water of first water tank and go into filter equipment, filter the back and enter into inside the feed water tank, water pump III and controlling means electric connection.

Preferably, supply tank, mixed water tank, first water tank up end all be equipped with air relief valve, supply tank, mixed water tank, first water tank inside all be equipped with the electron level gauge, electron level gauge and controlling means electric connection.

Compared with the prior art, the utility model discloses beneficial effect who has:

(1) the hydrogen and the water are mixed by the mixer, and the hydrogen bubbles in the mixed water are further smashed by the high-pressure high-speed water flow sprayed from the bubble cutting spray holes in the mixing process, so that the diameter of the hydrogen bubbles in the mixed water discharged from the mixer reaches the nanometer level.

(2) The mixed water is ionized by the ionization device, so that the buoyancy of the nano-scale hydrogen bubbles is small, and the viscosity of the ionized mixed water to the hydrogen bubbles is enhanced. Therefore, the combination of the two can effectively reduce the rising time of hydrogen bubbles, so that the final hydrogen-enriched water can be kept for a long time and can be filled and transported by using a plastic container.

Drawings

The present invention will be further explained with reference to the drawings and examples.

FIG. 1 is a flow chart of a system for preparing nano-scale hydrogen bubble water according to the present invention,

figure 2 is a system flow diagram of the belt front end processing apparatus of the present invention,

FIG. 3 is a structural diagram of the ionization device of the present invention,

figure 4 is a structural diagram of the mixing water tank of the utility model,

fig. 5 is a partial enlarged view of the position a of the present invention.

In the figure: 1-water supply tank;

2-hydrogen production device, 2 a-hydrogen discharge pipe;

3-an ionization device, 3 a-a shell and 3 b-a negative ion ball;

4-mixed water tank, 4 a-hydrogen bubble water discharge pipe, 41-mixer, 411-mixed pipe, 412-high pressure water cavity, 413-drainage spray hole, 414-bubble cutting spray hole and 415-mixed flow plate;

5-a water pump I;

6-a water pump II;

7-an electromagnetic three-way valve, 7 a-a water inlet pipe of a mixed water tank and 7 b-a water inlet pipe of a mixer;

8-a booster pump;

9-a pressure sensor;

10-a control device;

11-water pump III;

12-a filtration device;

13-primary water tank;

14-automatic exhaust valve;

15-electronic level gauge.

Detailed Description

The attached drawings are the best embodiments of the nano-scale hydrogen bubble water preparation system, and the invention is further explained in detail by combining the attached drawings.

Example 1:

as shown in the attached drawing 1, the nano-scale hydrogen bubble water preparation system comprises a water supply tank 1, a hydrogen production device 2, an ionization device 3, a mixed water tank 4, a water pump I5, a water pump II 6, an electromagnetic three-way valve 7 and a control device 10, wherein the control device 10 adopts a PLC.

The water pump I5 is arranged on a pipeline between the water supply tank 1 and the hydrogen production device 2, and the water pump I5 supplies water inside the water supply tank 1 to the hydrogen production device 2. The hydrogen production device 2 adopts the existing electrolytic hydrogen production equipment, and the hydrogen production device 2 can adopt a medium-pressure water electrolysis hydrogen production device of Suzhou competitive hydrogen production equipment limited company and can also adopt hydrogen production devices of other companies. The hydrogen produced by the hydrogen production device 2 is discharged through a hydrogen discharge pipe 2 a.

The water pump ii 6 is provided in a pipe between the water supply tank 1 and the mixing water tank 4, and the water pump ii 6 supplies water inside the water supply tank 1 to the mixing water tank 4. The outlet of the water pump II 6 is communicated with the inlet of the electromagnetic three-way valve 7 through a pipeline, two outlets of the electromagnetic three-way valve 7 are respectively communicated with a mixed water tank inlet pipe 7a and a mixer inlet pipe 7b, and the mixed water tank inlet pipe 7a is communicated with the mixed water tank 4. And an ionization device 3 is arranged on a pipeline between the electromagnetic three-way valve 7 and the water supply tank 1. As shown in fig. 3, the ionization device 3 includes a housing 3a and a plurality of anion balls 3b, the plurality of anion balls 3b are filled in the housing 3a, and two ends of the housing 3a are respectively connected with a pipeline in a through manner.

The negative ion ball 3b has a positive electrode and a negative electrode, and instantly releases electric current in water upon contact with water, which is 0.06MA most suitable for a human body. When water comes into contact with the above weak electric current, hydrogen ions and hydroxide ions in the surrounding water molecules are separated. On one hand, hydrogen ions and electrons are combined into hydrogen gas, and hydroxide ions and surrounding water molecules are combined into interface active substances and can generate more than 300 times of negative ions. The hydrogen is 1.32PPM at the moment measured by ultrasonic wave, which shows that the reductive potential of water is good, the water in the environment is changed into alkaline ionized water (the pH value is about 7.4, which is the same as the body fluid of a human body), and the alkaline water can keep the acid-base balance of the internal environment of the body, is beneficial to eliminating vivotoxin, relieving the phenomenon of acid reversion and improving the immunity and optimizing the hydration. The anion ball 3b is the prior art, and can be directly purchased.

As shown in fig. 4 and 5, a hydrogen bubble water discharge pipe 4a is arranged below the side wall of the mixing water tank 4, the bottom surface of the mixing water tank 4 is provided with an inclined surface, and the lowest point of the bottom surface is communicated with the hydrogen bubble water discharge pipe 4a, so that the long-term retention of a part of water in the mixing water tank 4 is avoided. The mixing water tank 4 is internally provided with a mixer 41, and the mixer 41 comprises a mixing pipe 411, a high-pressure water cavity 412, a drainage spray hole 413 and a bubble cutting spray hole 414. An annular high pressure water chamber 412 is sleeved on the mixing pipe 411, and a plurality of drainage spray holes 413 and a plurality of bubble cutting spray holes 414 are arranged on the circumferential surface of the mixing pipe 411 wrapped by the high pressure water chamber 412. The bubble cutting spray holes 414 are vertically arranged, the drainage spray holes 413 are obliquely arranged, and the drainage spray holes 413 are obliquely oriented in a direction that the opening positions of the drainage spray holes 413 on the inner surface of the mixing pipe 411 are closer to the bubble cutting spray holes 414 than the opening positions of the drainage spray holes 413 on the outer surface of the mixing pipe 411. The drainage spray holes 413 and the bubble cutting spray holes 414 are conical holes, and the diameters of the openings of the drainage spray holes 413 and the bubble cutting spray holes 414 on the inner surface of the mixing pipe 411 are larger than the diameters of the openings on the outer surface of the mixing pipe 411. This may increase the speed at which the drainage nozzle 413 and the bubble cut nozzle 414 spray water.

The mixer inlet pipe 7b is communicated with the high-pressure water chamber 412. The end of the hydrogen discharge pipe 2a is inserted into the mixing pipe 411, the axis of the pipeline at the end of the hydrogen discharge pipe 2a coincides with the axis of the mixing pipe 411, and the outlet of the pipeline at the end of the hydrogen discharge pipe 2a and the bubble cutting nozzle 414 are respectively located on two sides of the drainage nozzle 413. The flow direction of the hydrogen gas discharged from the hydrogen gas discharge pipe 2a is from the diversion nozzle hole 413 toward the bubble cut nozzle hole 414.

The water supply tank 1, the mixed water tank 4 and the upper end face are all provided with an automatic exhaust valve 14, and the water supply tank 1, the mixed water tank 4 and the interior are all provided with an electronic liquid level meter 15.

The water pump I5, the water pump II 6, the electromagnetic three-way valve 7 and the electronic liquid level meter 15 are respectively electrically connected with the control device 10.

The water pump I5, the water pump II 6, the electromagnetic three-way valve 7, the control device 10, the electronic liquid level meter 15 and the automatic exhaust valve 14 all adopt the prior art.

Example 2:

the other contents of this embodiment are the same as embodiment 1, except that: as shown in fig. 4, a plurality of inclined flow mixing plates 415 are arranged in the mixing pipe 411 in a staggered manner, and the flow mixing plates 415 are arranged between the tail end of the hydrogen discharge pipe 2a and the drainage spray holes 413. The water sprayed from the drainage nozzle 413 moves the water in the mixing tank 4 from the mixing pipe 411, and the flow direction is from the drainage nozzle 413 to the bubble cutting nozzle 414. The part of water is mixed with the hydrogen at the outlet of the hydrogen discharge pipe 2a, and then flows continuously after mixing, and under the blocking of the mixed flow plates 415, the water flow changes phase to form a small-range vortex, so that the part of water is mixed with the hydrogen more thoroughly.

Set up simultaneously in booster pump 8 and pressure sensor 9 on blender inlet tube 7b, pressure sensor 9 set up between booster pump 9 and electromagnetism three-way valve 7, booster pump 8 and pressure sensor 9 respectively with controlling means 10 electric connection. When the pressure sensor 9 detects that the water pressure inside the mixer water inlet pipe 7b is lower than the threshold value, the control device 10 controls the booster pump 9 to start, so as to increase the pressure of the booster pump, and further increase the pressure and speed of the water flow sprayed out from the drainage spray holes 413 and the bubble cutting spray holes 414.

Example 3:

the other contents of this embodiment are the same as those of embodiment 1 or embodiment 2, except that: the front end of the water supply tank 1 is sequentially connected with a filtering device 12, a water pump III 11 and a primary water tank 13. The water pump III 11 pumps the water in the primary water tank 13 into the filtering device 12 through a pipeline, and the filtered water enters the water supply tank 1. The water pump III 11 and the filtering device 12 both adopt the prior art. The filtering device 12 can be a household water filtering device of Sudi filter manufacturing company Limited in salt cities, or a drinking water filtering device of water purifier manufacturers such as Qin Yuan.

An automatic exhaust valve 14 is arranged on the upper end face of the primary water tank 13, an electronic liquid level meter 15 is arranged inside the primary water tank 13, an electromagnetic valve is arranged at the water inlet of the primary water tank 13, and when the liquid level inside the primary water tank 13 is higher than a threshold value, the electromagnetic valve is arranged at the water inlet of the primary water tank 13 and is closed.

The water pump III 11 and the electronic liquid level meter 15 are respectively and electrically connected with the control device 10.

During the use, the water of 14 inside water tanks is first pumped into filter equipment 12 inside through water pump III 11 and is filtered, forms straight drink water after filtering, and later straight drink water enters into inside water supply tank 1 through the pipeline. An electromagnetic valve can be installed between the water supply tank 1 and the filtering device 12, and when the electronic liquid level meter 15 in the water supply tank 1 detects that the liquid level in the water supply tank 1 reaches the set highest point, the control device 10 can control the electromagnetic valve between the water supply tank 1 and the filtering device 12 to be closed, and also control the water pump iii 11 to stop working.

One part of direct drinking water in the water supply tank 1 is pumped into the hydrogen production device 2 through the water pump I5 to prepare hydrogen, and the prepared hydrogen is discharged through the hydrogen discharge pipe 2 a. The other part is pumped to the inlet of the electromagnetic three-way valve 7 through a water pump II 6. At the initial stage, the entry of electromagnetism three-way valve 7 and mixed water tank inlet tube 7a through connection, it is inside that direct drinking water flows into mixed water tank 4, when mixed water tank 4 inside electron level gauge 15 detected mixed water tank 4 inside water level and reached the settlement threshold value (this moment mixed water tank 4 inside blender 41 is immersed directly drinking water completely), controlling means 10 control electromagnetism three-way valve 7 changes the export direction, make entry and blender inlet tube 7b through connection, direct drinking water enters into inside the high-pressure water chamber 412, accessible booster pump 8 carries out the pressure boost before getting into (whether the pressure boost depends on the pressure numerical value that pressure sensor 9 detected, if the pressure numerical value is less than the settlement pressure threshold value that booster pump 8 started, booster pump 8 starts). The direct drinking water entering the high pressure water tank 412 is sprayed out through the drainage spray hole 413 and the bubble cutting spray hole 414, and the pressure and the spraying speed of the sprayed water flow can be improved because both spray holes are conical holes. Drainage spray holes 413 and bubble cutting spray holes 414 are arranged around the mixing pipe 414 in a circle, the drainage spray holes 413 can be arranged for 1-3 circles, and the bubble cutting spray holes 414 can be arranged for more than 10 circles. The water flow ejected from the drainage nozzle 413 is high-speed and high-pressure, so that a negative pressure region can be formed in the advancing direction of the water flow, and the water flow behind the water flow flows to the negative pressure region, so as to drive the direct drinking water in the mixing water tank 4 to continuously flow from one end of the mixer 41 to the other end for circulation. The water flow sprayed from the bubble cutting spray hole 414 continuously impacts the bubbles of the hydrogen in the direct drinking water to cut and smash the hydrogen bubbles in the direct drinking water, so that the diameter of the hydrogen bubbles reaches the nanometer level.

Finally, the prepared nano-scale hydrogen bubble water is discharged through a hydrogen bubble discharge pipe 4a to enter a filling pipeline or is stored for direct drinking.

The embodiments of the present invention have been described in detail with reference to the accompanying drawings, but the present invention is not limited to the above embodiments, and various changes can be made without departing from the gist of the present invention within the knowledge of those skilled in the art.

Claims (9)

1. A nanometer hydrogen bubble water preparation system is characterized in that:

comprises a water supply tank (1), a hydrogen production device (2), an ionization device (3), a mixed water tank (4), a water pump I (5), a water pump II (6), an electromagnetic three-way valve (7) and a control device (10),

the water pump I (5) is arranged on a pipeline between the water supply tank (1) and the hydrogen production device (2),

the water pump II (6) is arranged on a pipeline between the water supply tank (1) and the mixed water tank (4), the outlet of the water pump II (6) is communicated with the inlet of the electromagnetic three-way valve (7) through a pipeline, the pipeline between the electromagnetic three-way valve (7) and the water supply tank (1) is provided with an ionization device (3),

two outlets of the electromagnetic three-way valve (7) are respectively connected with a mixed water tank inlet pipe (7a) and a mixer inlet pipe (7b) in a run-through way, the mixed water tank inlet pipe (7a) is connected with the mixed water tank (4) in a run-through way,

the mixing water tank (4) is provided with a hydrogen bubble water discharge pipe (4a), the mixing water tank (4) is internally provided with a mixer (41), the mixer (41) comprises a mixing pipe (411), a high-pressure water cavity (412), drainage spray holes (413) and bubble cutting spray holes (414), the annular high-pressure water cavity (412) is sleeved on the mixing pipe (411), a plurality of drainage spray holes (413) and a plurality of bubble cutting spray holes (414) are arranged on the circumferential surface of the mixing pipe (411) wrapped by the high-pressure water cavity (412), the bubble cutting spray holes (414) are vertically arranged, the drainage spray holes (413) are obliquely arranged, the inclined direction of the drainage spray holes (413) is that the opening position of the inner surface of the mixing pipe (411) is closer to the direction of the bubble cutting spray holes (414) than the opening position of the outer surface of the mixing pipe (411), a mixer water inlet pipe (7b) is communicated with the high-pressure water cavity (412),

the hydrogen produced by the hydrogen production device (2) is discharged through a hydrogen discharge pipe (2a), the tail end of the hydrogen discharge pipe (2a) is arranged inside the mixing pipe (411) in a penetrating way,

the water pump I (5), the water pump II (6) and the electromagnetic three-way valve (7) are respectively electrically connected with the control device (10).

2. The system for preparing nano-scale hydrogen bubble water according to claim 1, wherein:

the axis of the pipeline at the tail end of the hydrogen discharge pipe (2a) is superposed with the axis of the mixing pipe (411), and the outlet of the pipeline at the tail end of the hydrogen discharge pipe (2a) and the bubble cutting spray holes (414) are respectively positioned at two sides of the drainage spray holes (413).

3. The system for preparing nano-scale hydrogen bubble water according to claim 1, wherein:

the drainage spray holes (413) and the bubble cutting spray holes (414) are conical holes, and the diameters of the openings of the drainage spray holes (413) and the bubble cutting spray holes (414) on the inner surface of the mixing pipe (411) are larger than the diameter of the opening on the outer surface of the mixing pipe (411).

4. The system for preparing nano-scale hydrogen bubble water according to claim 1, wherein:

a plurality of inclined mixed flow plates (415) are arranged in the mixing pipe (411) in a staggered mode, and the mixed flow plates (415) are arranged between the tail end of the hydrogen discharge pipe (2a) and the drainage spray holes (413).

5. The system for preparing nano-scale hydrogen bubble water according to claim 1, wherein:

ionization device (3) include shell (3a) and a plurality of anion ball (3b), inside a plurality of anion ball (3b) filled shell (3a), shell (3a) both ends are run through respectively and are connected with the pipeline.

6. The system for preparing nano-scale hydrogen bubble water according to claim 1, wherein:

blender inlet tube (7b) on set up in booster pump (8) and pressure sensor (9), pressure sensor (9) set up between booster pump (8) and electromagnetism three-way valve (7), booster pump (8) and pressure sensor (9) respectively with controlling means (10) electric connection.

7. The system for preparing nano-scale hydrogen bubble water according to claim 1, wherein:

the control device (10) adopts a PLC.

8. The system for preparing nano-scale hydrogen bubble water according to claim 1, wherein:

the front end of the water supply tank (1) is sequentially connected with a filtering device (12), a water pump III (11) and a primary water tank (13), the water pump III (11) pumps water in the primary water tank (13) into the filtering device (12) through a pipeline, the filtered water enters the water supply tank (1),

and the water pump III (11) is electrically connected with the control device (10).

9. The system for preparing nano-scale hydrogen bubble water according to claim 8, wherein:

supply tank (1), mix water tank (4), first water tank (13) up end all be equipped with automatic exhaust valve (14), supply tank (1), mix water tank (4), first water tank (13) inside all be equipped with electron level gauge (15), electron level gauge (15) and controlling means (10) electric connection.

Images