CN218841694U - Gas-liquid mixing filling machine - Google Patents

Abstract

The utility model discloses a liquid filling machine of gas-liquid mixture, reverse osmosis filter in the organism has connected gradually the pure water tank through first water pump, the heating jar, first solenoid valve and pure water receiving mouth, the pure water tank passes through the second water pump and is connected with gas-liquid mixture's water inlet, gas-liquid mixture's delivery port is connected with hydrogen-rich water receiving mouth and hydrogen-rich water filling mouth through second solenoid valve and third solenoid valve respectively, the water supply of electrolysis hydrogen plant is given to the electrolyte water tank, the water inlet intercommunication of electrolysis hydrogen plant and second water pump. Therefore, the device has the functions of drinking purified water, drinking hydrogen-rich water and filling hydrogen-rich water, so that the device has multiple purposes, and the use cost of a user is effectively reduced; simultaneously gas-liquid mixing device extrudees, cuts, spiral intensive mixing with hydrogen and water in its inside many times and becomes hydrogen-rich water, effectively improves the concentration that makes hydrogen-rich water, consequently has multiple practical function, satisfies user's in-service use demand.

Description

Gas-liquid mixing's liquid filling machine

Technical Field

The utility model belongs to the technical field of drinking water equipment technique and specifically relates to a gas-liquid mixture's liquid filling machine.

Background

As is well known, hydrogen has the functions of resisting inflammation and oxidation, has no side effect and is easy to obtain. The human body can not directly absorb the hydrogen, but the hydrogen is dissolved in the water of the human body to enter the blood circulation to exert the effect of strengthening the physique, and because the hydrogen is insoluble in the water, most of the hydrogen is discharged out of the body along with the breathing.

Therefore, a hydrogen-rich water generator is available on the market, which mixes high-concentration hydrogen with water to generate hydrogen-rich water for people to drink, so that the hydrogen in the water enters the blood circulation of human body along with the water, and the same or even better health care effect as the inhaled hydrogen is achieved. However, the existing hydrogen-rich water generator only has a simple hydrogen-rich water generating function, and the efficiency of dissolving hydrogen in water is low, so that a large amount of hydrogen is wasted by dissipation, and the concentration of the generated hydrogen-rich water is low; the existing pressure drinking water barrel can be used in a movable mode, is convenient to carry and use when a user goes out, a water cup can be filled with hydrogen-rich water for drinking by opening a valve of the pressure drinking water barrel when the user goes out, and when the pressure drinking water barrel is used in practice, the hydrogen-rich water is generally filled into the pressure barrel through a filling machine for drinking, so that the user needs to purchase another set of pressure filling machine, and the use cost of the user is high; meanwhile, the Chinese patent 202210059788.8 discloses an automatic filling device for hydrogen-rich water, which is relatively complex in structure, simple in function, relatively high in use cost and not suitable for household or commercial use as can be seen by reading the specification and the attached drawings; for this purpose, we propose a filling machine for gas-liquid mixing to solve the above problems.

SUMMERY OF THE UTILITY MODEL

To the not enough of existence among the above-mentioned prior art, the utility model aims to provide a liquid filling machine of gas-liquid mixture.

In order to realize the purpose, the utility model adopts the following technical scheme:

a filling machine for gas-liquid mixing comprises a machine body, wherein a reverse osmosis filter device, an electrolytic hydrogen production device, a gas-liquid mixing device, an electrolyte water tank and a host machine for controlling orderly operation of a system are arranged in the machine body, a tap water filling port, a hydrogen-rich water receiving port and a hydrogen-rich water filling port are arranged on the outer surface of the machine body, the reverse osmosis filter device is connected with a municipal tap water pipe through the tap water filling port, the reverse osmosis filter device is sequentially connected with a purified water tank, a heating tank, a first electromagnetic valve and a purified water receiving port through a first water pump, the purified water tank is connected with a water inlet of the gas-liquid mixing device through a second water pump, the delivery port of gas-liquid mixing device is connected with hydrogen-rich water receiving mouth and hydrogen-rich water filling mouth through second solenoid valve and third solenoid valve respectively, the electrolyte water tank supplies water for electrolysis hydrogen plant's positive negative pole respectively through the pipeline, the hydrogen that electrolysis hydrogen plant's negative pole circular telegram produced and get into water inlet, positive and atmosphere intercommunication of second water pump through the pipeline, the second water pump is mixed in with hydrogen and pure water pump income gas-liquid mixing device and is made hydrogen-rich water, be provided with display device and button on the organism, display device, button, heating jar, electrolysis hydrogen plant, first water pump, second water pump, first solenoid valve, second solenoid valve and third solenoid valve all with host computer electric connection.

Preferably, the gas-liquid mixing device is including the jar body that is hollow structure, jar body both ends communicate respectively has inlet tube and outlet pipe, jar internal chamber is provided with at least one baffle and is formed with two hybrid chambers, be provided with the spray pipe with inlet tube and outlet pipe dislocation on the baffle, be formed with the offset clearance between the port of spray pipe and the hybrid chamber inner wall that corresponds, be formed with the offset clearance between the port of inlet tube and outlet pipe and the corresponding baffle terminal surface, the inlet tube loops through offset clearance, hybrid chamber, spray pipe and outlet pipe intercommunication.

Preferably, the gas-liquid mixing device comprises a tank body with a hollow structure, when the tank body is provided with two partition plates, the tank body is provided with three mixing chambers, the partition plates are adjacent to each other, water spray pipes are arranged on the partition plates in a staggered mode, the water spray pipes are arranged in a staggered mode with the water inlet pipe and the water outlet pipe, opposite-flushing gaps are formed between ports of the water spray pipes and the end faces of the partition plates corresponding to the inner walls of the mixing chambers, and opposite-flushing gaps are formed between the ports of the water inlet pipe and the water outlet pipe and between the ports of the water inlet pipe and the end faces of the partition plates corresponding to the mixing chambers.

Preferably, the height of the counter-punch gap is 0.1 to 5 mm.

Preferably, the inner diameter of the sprinkler pipe is 0.5 mm to 10 mm.

Preferably, a pressure gauge and a pressure sensor are connected in series on a pipeline between the water outlet of the gas-liquid mixing device and the third electromagnetic valve, and the pressure sensor is electrically connected with the host.

Preferably, the water tank cover of the electrolyte water tank is provided with air holes, the anode of the electrolytic hydrogen production device is communicated with the electrolyte water tank through a pipeline, and hydrogen produced by the anode of the electrolytic hydrogen production device penetrates through the electrolyte water tank and is discharged to the atmosphere through the air holes.

Preferably, button and manometer set up in the front surface of organism, the front surface of organism is provided with the water receiving platform, pure water receiving mouth and hydrogen-rich water receiving mouth are located water receiving platform department.

Preferably, the hydrogen-rich water filling opening is a quick connector.

Since the proposal is adopted, the utility model discloses following beneficial effect has:

1. the reverse osmosis filter device is sequentially connected with a purified water tank, a heating tank, a first electromagnetic valve and a purified water receiving port through a first water pump, the purified water tank is sequentially connected with a gas-liquid mixing device through a second water pump, a second electromagnetic valve, a third electromagnetic valve, a hydrogen-rich water receiving port and a hydrogen-rich water filling port, the negative electrode of the electrolytic hydrogen production device is electrified to generate hydrogen and is connected with the water inlet of the second water pump through a pipeline, hydrogen and water enter the gas-liquid mixing device to be mixed for multiple times to produce high-concentration hydrogen-rich water, so that a user can receive purified water through the purified water receiving port, receive the hydrogen-rich water through the hydrogen-rich water receiving port and fill the hydrogen-rich water into the pressure drinking water barrel through the hydrogen-rich water filling port, the device has the purified water drinking function and the hydrogen-rich water drinking function, and also has the hydrogen-rich water filling function, thereby having multiple use functions, effectively reducing the use cost of the user and facilitating the practical use of the user;

2. the two ends of the tank body of the gas-liquid mixing device are respectively communicated with a water inlet pipe and a water outlet pipe, the inner cavity of the tank body is provided with at least one partition plate and is formed with at least two mixing cavities, two ports of a water spray pipe on the partition plate are formed with opposite-flushing gaps, therefore, when a second water pump sucks hydrogen and high-pressure water simultaneously and pumps the hydrogen and high-pressure water out at the outlet of the second water pump, the mixture of the pumped hydrogen and the high-pressure water repeatedly impacts the cavity wall of the mixing cavity and is repeatedly extruded into small bubbles, and the small bubbles of the hydrogen are repeatedly extruded and cut into small bubbles through the opposite-flushing gaps, then the hydrogen bubbles and the water are repeatedly and spirally and fully mixed in different mixing cavities, and high-concentration hydrogen-rich water is discharged through the water outlet pipe, therefore, the gas-liquid mixing device fully mixes the hydrogen and the water, the efficiency of dissolving the hydrogen in the water is effectively improved, the loss of the hydrogen is reduced, the concentration of the prepared hydrogen-rich water is greatly improved, the gas is convenient for users to drink actually, the gas-liquid, the gas mixing device is simple in structure, the hydrogen mixing effect and low in cost, the mass production and the family use convenience are realized, and the practical use of the mass production and the household use of the device is realized.

Drawings

Fig. 1 is an isometric view of an embodiment of the invention.

Fig. 2 is a schematic structural diagram of the back of the embodiment of the present invention.

Fig. 3 is a schematic structural view of the vent according to the embodiment of the present invention.

Fig. 4 is a schematic structural diagram of a reverse osmosis filtration device according to an embodiment of the present invention.

Fig. 5 is another schematic structural diagram of a reverse osmosis filtration device according to an embodiment of the present invention.

Fig. 6 is a schematic diagram of a liquid path diagram according to an embodiment of the present invention.

In the figure:

1. a body; 2. a reverse osmosis filtration device; 3. an electrolytic hydrogen production device; 4. a gas-liquid mixing device; 5. an electrolyte tank; 6. a host; 7. a tap water filling port; 8. a hydrogen-rich water receiving port; 9. a hydrogen-rich water filling port; 10. a first water pump; 11. a purified water tank; 12. a heating tank; 13. a first solenoid valve; 14. the purified water is connected with a water port; 15. a second water pump; 16. a second solenoid valve; 17. a third electromagnetic valve; 18. a pipeline; 19. a display device; 20. a button; 21. a tank body; 22. a water inlet pipe; 23. a water outlet pipe; 24. a partition plate; 25. a mixing chamber; 26. a water spray pipe; 27. a hedging gap; 28. a pressure gauge; 29. a pressure sensor; 30. air holes are formed; 31. a water receiving platform.

Detailed Description

The embodiments of the invention will be described in detail below with reference to the drawings, but the invention can be implemented in many different ways as defined and covered by the claims.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like, indicate orientations and positional relationships based on those shown in the drawings, and are used only for convenience of description and simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be construed as limiting the present invention. Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, features defined as "first", "second", may explicitly or implicitly include one or more of the described features. In the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

In the description of the present invention, it should be noted that the terms "mounted," "connected," and "connected" are to be construed broadly and may include, for example, a fixed connection, a detachable connection, or an integral connection unless otherwise specifically stated or limited. Either mechanically or electrically. Either directly or indirectly through intervening media, either internally or in any other relationship. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

Before the working description of the embodiment, for the convenience of the examiner to understand the embodiment, the principle of hydrogen-rich water health care will be described: hydrogen-rich water is the water that is rich in hydrogen as its name implies, and hydrogen in the hydrogen-rich water gets into the human body after, can bring many benefits to the human body, but hydrogen is difficult to dissolve in water, so need use hydrogen-rich water machine, hydrogen-rich water machine produces the separation of oxyhydrogen through electrolysis water, and hydrogen-rich water machine can pass through the physical mode simultaneously and let the water wrap up hydrogen molecule, makes hydrogen and water blend and be in steady state.

The hydrogen-rich water has the functions of: activating human body cells, delaying aging, removing harmful substances in cell membrane or blood vessel, and inhibiting oxygen free radical; enhancing immunity, improving cell activity, preventing common cold; promoting digestive excretion function, softening blood vessel, activating mucosa cell, promoting enterokinesia, facilitating excretion, and preventing and improving constipation; the permeability is strong, and the product can penetrate into tissues such as vascular endothelial space, remove precipitate, activate cell tissue, dredge blood vessels, and improve blood circulation function; improving gastrointestinal function, promoting blood circulation and metabolism, maintaining endocrine balance, and promoting lipodieresis.

The reverse osmosis water purifier is a set of water purifying system mainly comprising a filter, a reverse osmosis device and a dosing and sterilizing device. The filter is mainly used for pretreatment, the water quality of the reverse osmosis inlet water is ensured, and the situations of blockage, scaling and the like of the reverse osmosis are avoided.

The working principle of reverse osmosis is as follows: reverse osmosis is the most precise membrane liquid separation technology, operating pressure is applied to the water inlet (concentrated solution) side to overcome natural osmotic pressure, when the operating pressure higher than the natural osmotic pressure is applied to the concentrated solution side, the flow direction of natural permeation of water molecules is reversed, and part of the water molecules in the water inlet (concentrated solution) becomes purified water on the dilute solution side through a reverse osmosis membrane; the reverse osmosis equipment can block all soluble salts and organic matters with molecular weight more than 100, but allows water molecules to permeate, and the desalination rate of the reverse osmosis composite membrane is generally more than 98%.

For the convenience of the examiner to understand the embodiment, the operation principle of the electrolytic hydrogen production apparatus 3 will be explained: the electrolytic hydrogen production device 3 is under the power-on state, the anode generates oxygen, the cathode generates hydrogen, namely the principle of water electrolysis; the water inlet of the electrolytic hydrogen production device 3 is connected with the electrolyte water tank 5, the hydrogen outlet of the electrolytic hydrogen production device 3 is communicated with the water inlet of the second water pump 15, the purified water tank 11 is also communicated with the water inlet of the second water pump 15 through a pipeline 18, the oxygen outlet of the electrolytic hydrogen production device 3 is communicated with the electrolyte water tank 5 through a pipeline 18, and oxygen produced by the electrolytic hydrogen production device 3 is discharged through the air holes 30 of the water tank cover of the electrolyte water tank 5.

As shown in fig. 1 to 6, the filling machine for gas-liquid mixing provided by this embodiment includes a machine body 1, a reverse osmosis filter 2, an electrolytic hydrogen production device 3, a gas-liquid mixing device 4, an electrolyte tank 5 and a host 6 for controlling orderly operation of the system are disposed in the machine body 1, a tap water filling port 7, a hydrogen-rich water receiving port 8 and a hydrogen-rich water filling port 9 are disposed on an outer surface of the machine body 1, the reverse osmosis filter 2 is connected to a municipal tap water pipe through the tap water filling port 7, the reverse osmosis filter 2 is sequentially connected to a purified water tank 11, a heating tank 12 capable of heating water, a first electromagnetic valve 13 and a purified water receiving port 14 through a first water pump 10, the purified water tank 11 is connected to a water inlet of the gas-liquid mixing device 4 through a second water pump 15, purified water produced by the purified water tank 11 and hydrogen produced by the electrolytic hydrogen production device 3 are merged in a pipeline 18 and then flow into the water inlet of the second water pump 15, the water outlet of the second water pump 15 is connected with the water inlet of the gas-liquid mixing device 4, and the water flowing from the water outlet of the gas-liquid mixing device 4 is hydrogen-rich water, the water outlet of the gas-liquid mixing device 4 is respectively connected with a hydrogen-rich water receiving port 8 and a hydrogen-rich water filling port 9 through a second electromagnetic valve 16 and a third electromagnetic valve 17, the electrolyte water tank 5 respectively supplies water to the anode and the cathode of the electrolytic hydrogen production device 3 through a pipeline 18, hydrogen generated by electrifying the cathode of the electrolytic hydrogen production device 3 enters the water inlet of the second water pump 15 through the pipeline 18, oxygen is generated by electrifying the anode and communicated with the atmosphere and discharged, the hydrogen and the purified water are pumped into the gas-liquid mixing device 4 by the second water pump 15 to be mixed to obtain the hydrogen-rich water, the machine body 1 is provided with a display device 19 and a button 20, the display device 19, the button 20, the heating tank 12, the electrolytic hydrogen production device 3, first water pump 10, second water pump 15, first solenoid valve 13, second solenoid valve 16 and third solenoid valve 17 all with host computer 6 electric connection, further, the display device 19 of this embodiment is the touch-sensitive screen of convenience of customers' operation.

In practical use of the embodiment, the host machine 6 is powered on, municipal tap water is filtered by the reverse osmosis filter device 2 to produce purified water, and is injected into the purified water tank 11 through the second water pump 15, water in the purified water tank 11 is injected into the heating tank 12 through a pipe, under the control of the host machine 6, when a user needs hot water, the user sends a heating instruction to the host machine 6 through the operation display device 19, the water in the heating tank 12 is heated, the host machine 6 controls the first electromagnetic valve 13 to be opened, the purified water receiving port 14 can flow out hot purified water, and meanwhile, when the heating tank 12 is not heated, the purified water receiving port 14 can flow out normal-temperature purified water; when a user needs to drink hydrogen-rich water, firstly, the user sends an instruction for making the hydrogen-rich water to the host 6 through the operation display device 19, the second water pump 15 sucks water in the purified water tank 11 out, the water is pumped out at the outlet of the second water pump 15 under high pressure, the negative electrode of the electrolytic hydrogen production device 3 is electrified to produce hydrogen and is connected with the water inlet of the second water pump 15 through the pipeline 18, the hydrogen and the water enter the gas-liquid mixing device 4 to be mixed for multiple times to produce high-concentration hydrogen-rich water, the hydrogen-rich water flowing out of the water outlet pipe 23 of the gas-liquid mixing device 4 passes through the opened second electromagnetic valve 16, and the user can drink the high-concentration hydrogen-rich water at the hydrogen-rich water inlet 8; when a pressure drinking water bucket of a user needs to be filled with hydrogen-rich water for drinking, the user firstly connects the pressure drinking water bucket with a hydrogen-rich water filling port 9 through a pipeline 18, then the user sends an instruction for making the filled hydrogen-rich water to a host computer 6 through an operation display device 19, at the moment, a negative electrode of an electrolytic hydrogen production device 3 is electrified to generate hydrogen and is connected with a water inlet of a second water pump 15 through the pipeline 18, hydrogen and water are pumped into a gas-liquid mixing device 4, the hydrogen and the water are mixed for many times in the gas-liquid mixing device 4 to generate the high-concentration hydrogen-rich water, the hydrogen-rich water flowing out of a water outlet pipe 23 of the gas-liquid mixing device 4 passes through a third electromagnetic valve 17 opened by the host computer 6, under the action of continuous high-pressure pump water of the second water pump 15, the hydrogen-rich water is filled into the pressure drinking water bucket at the moment, when the pressure in the pressure drinking water bucket is detected by a pressure sensor 29 and reaches the pressure preset by the host computer 6, the host computer 6 controls the third electromagnetic valve 17 to be closed, meanwhile, the filling of the hydrogen-rich water in the pressure drinking water bucket is also completed, and the process is automatically completed; so the existing pure water of this device drinks the function, has hydrogen-rich water again and drinks the function, and hydrogen-rich water filling function in addition, and then has multiple service function, and a tractor serves several purposes effectively reduces user use cost, convenience of customers in-service use.

Further, the gas-liquid mixing device 4 of this embodiment includes a tank 21 having a hollow structure, two ends of the tank 21 are respectively communicated with a water inlet pipe 22 and a water outlet pipe 23, an inner cavity of the tank 21 is provided with at least one partition 24 and two mixing cavities 25, the partition 24 is provided with a water spray pipe 26 dislocated with the water inlet pipe 22 and the water outlet pipe 23, an opposite-flushing gap 27 is formed between a port of the water spray pipe 26 and an inner wall of the corresponding mixing cavity 25, an opposite-flushing gap 27 is formed between ports of the water inlet pipe 22 and the water outlet pipe 23 and an end face of the corresponding partition 24, the water inlet pipe 22 is communicated with the water outlet pipe 23 sequentially through the opposite-flushing gap 27, the mixing cavities 25, the water spray pipe 26, the water inlet pipe 22 is communicated with a water outlet of the second water pump 15, and the water outlet pipe 23 is communicated with inlets of the second solenoid valve 17 and the third solenoid valve 17 (as shown in fig. 4). Therefore, when the negative electrode of the electrolytic hydrogen production device 3 is electrified to generate hydrogen and enters the water inlet of the second water pump 15 through the pipeline 18, and then the water outlet of the second water pump 15 pumps out a mixture of large hydrogen bubbles and high-pressure water and enters the tank body 21 through the water inlet pipe 22, the mixture of the hydrogen bubbles and the high-pressure water in the water inlet pipe 22 firstly strikes the partition plate 24, under the impact action of high-speed water flow, the large hydrogen bubbles are struck into small bubbles, meanwhile, the small hydrogen bubbles and the water pass through the opposite-flushing gap 27, because the height of the opposite-flushing gap 27 is small, the actual height is only 0.1 mm-0.5 mm, and further after the small hydrogen bubbles pass through the opposite-flushing gap 27, the hydrogen bubbles are cut into numerous tiny bubbles by the opposite-flushing gap 27, and further the diameter of the hydrogen bubbles is greatly reduced, because the water spray pipe 26 is arranged in a staggered way with the water inlet pipe 22 and the water outlet pipe 23, therefore, the water flow in the mixing chamber 25 needs to turn upwards and rotate to enter the spray pipe 26, so that the high-pressure water and hydrogen micro-bubbles sprayed out through the opposite-flushing gap 27 form vortex and turbulent flow in the mixing chamber 25 and are fully mixed, then the mixture of water and hydrogen enters the spray pipe 26 through the opposite-flushing gap 27 at the upper end of the spray pipe 26 again, the mixture of water and hydrogen in the spray pipe 26 collides against the wall of the mixing chamber 25 at the lower end and reduces the diameter of the small hydrogen bubbles, then the mixture of water and hydrogen passes through the opposite-flushing gap 27 at the lower end of the spray pipe 26 again, at this time, the hydrogen bubbles are cut again and reduced in diameter by the opposite-flushing gap 27, the high-pressure water and hydrogen micro-bubbles sprayed out from the opposite-flushing gap 27 at the lower end of the spray pipe 26 form vortex and turbulent flow in the mixing chamber 25 and are fully mixed again, and enter the water outlet pipe 23 through the opposite-flushing gap 27 at the upper end of the water outlet pipe 23, at this time, the water outlet pipe 23 discharges high-concentration hydrogen-rich water mixed with hydrogen; the above gas-liquid mixing principle is also used to mix ozone with water to prepare ozone water, which has the functions of disinfection, preservation, and odor removal, and the device can be used for mixing other gases and liquids, and the embodiment does not specifically limit the specific types of the mixed gas and liquid in the gas-liquid mixing device 4.

Further, when two partition plates 24 are arranged in the inner cavity of the tank body 21, three mixing cavities 25 (as shown in fig. 5) are formed in the inner cavity of the tank body 21, water spraying pipes 26 are arranged on the adjacent partition plates 24 in a staggered manner, the water spraying pipes 26 are arranged in a staggered manner with the water inlet pipe 22 and the water outlet pipe 23, opposite-flushing gaps 27 are formed between ports of the water spraying pipes 26 and the inner walls of the corresponding mixing cavities 25 and the end surfaces of the partition plates 24, and opposite-flushing gaps 27 are formed between the ports of the water inlet pipe 22 and the water outlet pipe 23 and the end surfaces of the corresponding partition plates 24 and the mixing cavities 25. When the inner chamber of the tank 21 is formed with three mixing chambers 25, the impact of water and hydrogen, cutting, the principle of mixing is the same as the above-mentioned principle, all be with water and hydrogen multiple impact, cutting, mix and form high concentration hydrogen-rich water, but there are three mixing chambers 25 in the tank 21, in, lower three mixing chamber 25, two mixing chambers 25 have inlet tube 22 respectively about, spray pipe 26 and outlet pipe 23, only spray pipe 26 is located on the both sides of mixing chamber 25 in the middle, therefore the space of mixing chamber 25 in the middle is great (as shown in fig. 5), so can form rivers swirl in the middle part of mixing chamber 25 when the mixture of water and hydrogen is spouted out to spray pipe 26 on the upper end of mixing chamber 25 in the middle, and then make water and hydrogen intensive mixing, middle mixing chamber 25 can set up a plurality of, so make hydrogen can dissolve in aqueous completely, reduce the hydrogen loss, greatly improve the concentration of making hydrogen-rich water.

Further, the height of the backlash 27 in the present embodiment is 0.1 mm to 5 mm. In practical application, the height of the hedging gap 27 is set to be 0.1 mm or 0.3 mm, so that a plurality of micro bubbles with the diameter of 0.1 mm to 0.3 mm are cut after the large hydrogen bubbles pass through the gap of the hedging gap 27 for a plurality of times, the efficiency of dissolving hydrogen in water is effectively improved, and hydrogen dissipation is reduced.

Further, the inner diameter of the spout 26 of the present embodiment is 0.5 mm to 10 mm. In practice, the inner diameter of the water jet pipe 26 is set to 0.5 mm-2 mm, and according to Bernoulli's principle, in the water flow or air flow, the pressure is high if the speed is low, and the pressure is low if the speed is high. Therefore, the inner diameter of the water spray pipe 26 is very small, when the mixture of water and hydrogen enters the inner cavity of the water spray pipe 26 with a very small cross section from the larger mixing cavity 25, the flow rate of the mixture of water and hydrogen in the inner cavity of the water spray pipe 26 is reduced, but the pressure is increased, when the mixture of water and hydrogen is sprayed out from the outlet of the water spray pipe 26, the flow rate of the mixture of water and hydrogen is increased, the pressure is reduced, and at the moment, the mixture of water and hydrogen violently impacts on the inner wall of the mixing cavity 25 or the end face of the partition plate 24, so that the larger hydrogen bubbles are violently impacted and broken into smaller hydrogen bubbles, the hydrogen dissolving efficiency in water is effectively improved, and the hydrogen escape is reduced.

Further, a pressure gauge 28 and a pressure sensor 29 are connected in series on the pipeline 18 between the water outlet of the gas-liquid mixing device 4 and the third electromagnetic valve 17, and the pressure sensor 29 is electrically connected with the host machine 6. Utilize setting up of manometer 28 to make the user when using pressure scuttlebutt filling hydrogen-rich water, fill hydrogen-rich water in the pressure scuttlebutt, pressure sensor 29 detects and reaches preset pressure in the pipeline 18, pressure sensor 29 sends pressure signal for host computer 6, host computer 6 control third solenoid valve 17 closes, and then realize the function of the automatic filling of preset pressure, convenience of customers's in-service use, the user is using when using pressure scuttlebutt filling hydrogen-rich water in the setting of manometer 28, observe the filling pressure of pressure bucket cup more directly perceivedly, convenience of customers closes to observe filling pressure and filling use.

Further, the water tank cover of the electrolyte water tank 5 of the embodiment is provided with an air vent 30, and the anode of the electrolytic hydrogen production device 3 is communicated with the electrolyte water tank 5 through a pipeline 18. After the anode of the electrolytic hydrogen production device 3 is electrified to generate oxygen, the hydrogen produced by the anode of the electrolytic hydrogen production device 3 passes through the electrolyte water tank 5 and is discharged to the atmosphere through the air holes 30, the air holes 30 on the water tank cover of the electrolyte water tank 5 are hidden, and further the air holes 30 do not need to be additionally arranged on the outer surface of the machine body 1, so that the appearance of the whole machine is more attractive and complete.

Further, the button 20 and the pressure gauge 28 of the present embodiment are disposed on the front surface of the machine body 1, the water receiving table 31 is disposed on the front surface of the machine body 1, and the purified water receiving port 14 and the hydrogen-rich water receiving port 8 are located at the water receiving table 31. The water receiving table 31 is convenient for users to place the water cup on the water receiving table 31 for receiving water when receiving purified water or hydrogen-rich water, so that the water receiving table is convenient for users to use practically.

Further, the hydrogen-rich water filling port 9 of the present embodiment is a quick-connect plug. The quick connector is the most convenient plug-and-play connection mode, and particularly can embody the superiority of the quick connector in the occasions of difficult space where the connection of pipelines 18 is very inconvenient. Quick connector can be so that the user when using pressure scuttlebutt filling hydrogen-rich water, realizes realizing the quick plug of hydrogen-rich water filling mouth 9 and pressure scuttlebutt through pipeline 18, and then more convenient when making user's filling hydrogen-rich water, convenience of customers in-service use.

The above is only the preferred embodiment of the present invention, and not the scope of the present invention, all the equivalent structures or equivalent flow changes made by the contents of the specification and the drawings or the direct or indirect application in other related technical fields are included in the patent protection scope of the present invention.

Claims (9)

1. The utility model provides a liquid filling machine of gas-liquid mixture which characterized in that: comprises a machine body, wherein a reverse osmosis filter device, an electrolytic hydrogen production device, a gas-liquid mixing device, an electrolyte water tank and a host machine for controlling the orderly work of a system are arranged in the machine body, a tap water filling port, a hydrogen-rich water receiving port and a hydrogen-rich water filling port are arranged on the outer surface of the machine body, the reverse osmosis filter device is connected with a municipal tap water pipe through the tap water filling port, the reverse osmosis filter device is sequentially connected with a purified water tank, a heating tank, a first electromagnetic valve and a purified water receiving port through a first water pump, the purified water tank is connected with a water inlet of the gas-liquid mixing device through a second water pump, the water outlet of the gas-liquid mixing device is connected with a hydrogen-rich water receiving opening and a hydrogen-rich water filling opening through a second electromagnetic valve and a third electromagnetic valve respectively, the electrolyte water tank supplies water for the positive electrode and the negative electrode of the electrolytic hydrogen production device respectively through pipelines, hydrogen generated by the negative electrode of the electrolytic hydrogen production device is electrified and enters the water inlet, the positive electrode and the atmosphere of the second water pump through pipelines, the hydrogen and purified water are pumped into the gas-liquid mixing device by the second water pump to be mixed to prepare hydrogen-rich water, a display device and a button are arranged on the machine body, and the display device, the button, a heating tank, the electrolytic hydrogen production device, the first water pump, the second water pump, the first electromagnetic valve, the second electromagnetic valve and the third electromagnetic valve are electrically connected with a host.

2. A filling machine for gas-liquid mixture as defined in claim 1, wherein: the gas-liquid mixing device comprises a tank body which is of a hollow structure, the two ends of the tank body are respectively communicated with a water inlet pipe and a water outlet pipe, the inner cavity of the tank body is provided with at least one partition plate and is formed with two mixing cavities, the partition plate is provided with a water spray pipe which is staggered with the water inlet pipe and the water outlet pipe, an opposite-flushing gap is formed between the port of the water spray pipe and the inner wall of the corresponding mixing cavity, an opposite-flushing gap is formed between the port of the water inlet pipe and the port of the water outlet pipe and the end face of the corresponding partition plate, and the water inlet pipe is communicated with the water outlet pipe sequentially through the opposite-flushing gap, the mixing cavities and the water spray pipe.

3. A filling machine for gas-liquid mixing as defined in claim 1, wherein: the gas-liquid mixing device comprises a tank body with a hollow structure, when two partition plates are arranged in the inner cavity of the tank body, three mixing cavities are formed in the inner cavity of the tank body, water spraying pipes are arranged on the adjacent partition plates in a staggered mode, the water spraying pipes are arranged in a staggered mode with a water inlet pipe and a water outlet pipe, opposite-flushing gaps are formed between the ports of the water spraying pipes and the end faces of the corresponding mixing cavities and between the ports of the water inlet pipe and the water outlet pipe and the end faces of the corresponding partition plates, and opposite-flushing gaps are formed between the ports of the water inlet pipe and the water outlet pipe and the end faces of the corresponding partition plates.

4. A liquid-gas mixing filling machine as defined in claim 2 or 3, wherein: the height of the backlash is 0.1 mm to 5 mm.

5. A filling machine for gas-liquid mixing as defined in claim 2 or 3, wherein: the inner diameter of the water spray pipe is 0.5 mm to 10 mm.

6. A filling machine for gas-liquid mixture as defined in claim 1, wherein: and a pressure gauge and a pressure sensor are connected in series on a pipeline between a water outlet of the gas-liquid mixing device and the third electromagnetic valve, and the pressure sensor is electrically connected with the host.

7. A filling machine for gas-liquid mixture as defined in claim 1, wherein: the water tank cover of the electrolyte water tank is provided with air holes, the anode of the electrolytic hydrogen production device is communicated with the electrolyte water tank through a pipeline, and hydrogen produced by the anode of the electrolytic hydrogen production device penetrates through the electrolyte water tank and is discharged to the atmosphere through the air holes.

8. A filling machine for gas-liquid mixing as defined in claim 1, wherein: button and manometer set up in the front surface of organism, the front surface of organism is provided with the water receiving platform, pure water receiving mouth and hydrogen-rich water receiving mouth are located water receiving platform department.

9. A filling machine for gas-liquid mixing as defined in claim 1, wherein: the hydrogen-rich water filling port is a quick connector.

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