CN215783075U - High-efficient microbubble machine - Google Patents

Abstract

The utility model relates to the technical field of micro bubble machines and discloses a high-efficiency micro bubble machine which comprises a bottom shell, a processor, a hydrogen production device, a tank body, a mixing cavity, a water inlet pipe and a valve mechanism, wherein the top of the hydrogen production device is communicated with a conveying pipe; the micro-bubble machine can generate smaller bubbles, further enhances the effects of the micro-bubble machine in the aspects of disinfection, sterilization, deep cleaning and the like, simultaneously can improve the production efficiency, obviously improves the concentration and the solubility of micro-bubbles, nano-bubbles and hydrogen micro-nano-bubbles, and solves the problems that the existing micro-bubble machine generates larger bubbles, has short retention time in water, causes poor cleaning effect, cannot produce a large amount of water containing micro-bubbles in a short time and influences the production efficiency.

Description

High-efficient microbubble machine

Technical Field

The utility model relates to the technical field of micro bubble machines, in particular to a high-efficiency micro bubble machine.

Background

The hydrogen micro-nano bubble machine is a micro-bubble machine for short, the micro-bubble machine can produce very small bubbles with the size less than 0.001 mm, the bubbles are very small in size and have negative charges, so that the bubbles can absorb positive charges of foreign matters and float on the water surface. Referred to as invisible, non-disappearing bubbles.

The bubbles that some existing microbubble machines produced are great, and the time of staying in water is short, leads to clean effect not good enough, and can't produce the water that contains the microbubble in a large number in the short time, influences production efficiency, for this we propose one kind can produce littleer bubble, and further strengthen the effect in aspects such as disinfection, sterilization, degree of depth clean, the more efficient microbubble machine solves this problem.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a high-efficiency micro-bubble machine to solve the problems in the background technology.

In order to achieve the purpose, the utility model provides the following technical scheme: a high-efficiency micro-bubble machine comprises a bottom shell, a processor, a hydrogen production device, a tank body, a mixing cavity, a water inlet pipe and a valve mechanism, wherein the top of the hydrogen production device is communicated with a conveying pipe, vertical pipes are arranged on two sides of the inner part of the tank body, the top ends of the vertical pipes are communicated with the conveying pipe, the surface of each vertical pipe is communicated with a plurality of air nozzles, a top shell is bolted at the top of the mixing cavity, a driving motor is arranged inside the top shell, a rotating rod is fixedly connected with an output shaft of the driving motor, stirring blades are arranged on two sides of the rotating rod, a first water pump is arranged on the surface of the water inlet pipe, one end of the water inlet pipe penetrates into the inner part of the tank body, a water conveying pipe is communicated on the right side of the tank body, the other end of the water conveying pipe penetrates into the inner part of the mixing cavity, a second water pump is arranged on the surface of the water conveying pipe, and an air pump is arranged on the right side of the inner part of the bottom shell, the gas outlet intercommunication of air pump has the gas-supply pipe, and the other end of gas-supply pipe runs through to the inside of hybrid chamber, the right side of hybrid chamber is passed through the connecting pipe intercommunication and is had miniature flow controller.

Preferably, the valve mechanism comprises a first electromagnetic valve, a second electromagnetic valve, a first check valve and a second check valve, the first electromagnetic valve is installed on the surface of the water inlet pipe, the second electromagnetic valve is installed on the surface of the conveying pipe, the first check valve is installed on the surface of the water conveying pipe, and the second check valve is installed on the surface of the air conveying pipe.

Preferably, the surface of conveyer pipe just is located the right side of first water pump and installs the liquid flow meter, the surface of gas-supply pipe just is located the below of second check valve and installs the electron manometer.

Preferably, the output ends of the liquid flow meter and the electronic pressure meter are all in one-way electric connection with the input end of the processor, and the output end of the processor is respectively in one-way electric connection with the input ends of the first water pump, the second water pump, the air pump, the first electromagnetic valve, the second electromagnetic valve and the driving motor.

Preferably, a hydrogen concentration sensor is installed above the inside of the hydrogen production device, and the output end of the hydrogen concentration sensor is in one-way electric connection with the input end of the processor.

Preferably, the stirring leaves are distributed at equal intervals from top to bottom, and gaps exist between the stirring leaves and the vertical pipe.

Compared with the prior art, the utility model has the following beneficial effects:

the micro-bubble machine can generate smaller bubbles, further enhances the effects of the micro-bubble machine in the aspects of disinfection, sterilization, deep cleaning and the like, simultaneously can improve the production efficiency, obviously improves the concentration and the solubility of micro-bubbles, nano-bubbles and hydrogen micro-nano-bubbles, and solves the problems that the existing micro-bubble machine generates larger bubbles, has short retention time in water, causes poor cleaning effect, cannot produce a large amount of water containing micro-bubbles in a short time and influences the production efficiency.

Drawings

FIG. 1 is an elevational, cross-sectional view of the structure of the present invention;

FIG. 2 is a left side view of a partial structure of the present invention;

FIG. 3 is a perspective view of a portion of the present invention;

fig. 4 is a schematic block diagram of the system of the present invention.

In the figure: 1. a bottom case; 2. a processor; 3. a hydrogen production unit; 4. a tank body; 5. a mixing chamber; 6. a delivery pipe; 7. a vertical tube; 8. an air tap; 9. a top shell; 10. a drive motor; 11. a rotating rod; 12. stirring blades; 13. a water inlet pipe; 14. a valve mechanism; 141. a first solenoid valve; 142. a second solenoid valve; 143. a first check valve; 144. a second check valve; 15. a first water pump; 16. a water delivery pipe; 17. a second water pump; 18. an air pump; 19. a gas delivery pipe; 20. a micro restrictor; 21. a liquid flow meter; 22. an electronic pressure gauge; 23. a hydrogen concentration sensor.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-4, a high-efficiency micro-bubble machine includes a bottom case 1, a processor 2, a hydrogen production device 3, a tank 4, a mixing chamber 5, a water inlet pipe 13 and a valve mechanism 14, wherein the top of the hydrogen production device 3 is communicated with a delivery pipe 6, vertical pipes 7 are installed on both sides of the inside of the tank 4, the top ends of the vertical pipes 7 are communicated with the delivery pipe 6, the surface of each vertical pipe 7 is communicated with a plurality of air nozzles 8, a top case 9 is bolted on the top of the mixing chamber 5, a driving motor 10 is installed inside the top case 9, an output shaft of the driving motor 10 is fixedly connected with a rotating rod 11, stirring blades 12 are installed on both sides of the rotating rod 11, a first water pump 15 is installed on the surface of the water inlet pipe 13, one end of the water inlet pipe 13 penetrates into the inside of the tank 4, a water pipe 16 is communicated on the right side of the tank 4, the other end of the water pipe 16 penetrates into the mixing chamber 5, a second water pump 17 is installed on the surface of the water pipe 16, air pump 18 is installed on the inside right side of drain pan 1, air pump 18's gas outlet intercommunication has air-supply pipe 19, and air-supply pipe 19's the other end runs through to the inside of hybrid chamber 5, the right side of hybrid chamber 5 has miniature flow controller 20 through the connecting pipe intercommunication, this microbubble machine can produce littleer bubble, further strengthen this microbubble machine in the disinfection, disinfect, the effect of the aspect such as degree of depth cleanness, can promote production efficiency simultaneously, and make the micron bubble, the concentration and the solubility of nanometer bubble and the micro-nanometer bubble of hydrogen are showing and are promoting, it is great to have solved the bubble that a little current microbubble machine produced, it is shorter to be detained in the time of water, lead to clean effect not good enough, and can't produce the water that contains the microbubble in the short time in large quantities, influence production efficiency's problem.

Referring to fig. 1, the valve mechanism 14 includes a first electromagnetic valve 141, a second electromagnetic valve 142, a first check valve 143, and a second check valve 144, the first electromagnetic valve 141 is installed on the surface of the water inlet pipe 13, the second electromagnetic valve 142 is installed on the surface of the delivery pipe 6, the first check valve 143 is installed on the surface of the water delivery pipe 16, and the second check valve 144 is installed on the surface of the air delivery pipe 19, by the arrangement of the first electromagnetic valve 141, the second electromagnetic valve 142, the first check valve 143, and the second check valve 144, the first electromagnetic valve 141 and the second electromagnetic valve 142 can respectively control the opening and closing of the water inlet pipe 13 and the delivery pipe 6, and at the same time, because high-pressure gas exists inside the mixing chamber 5, the first check valve 143 and the second check valve 144 can prevent backflow.

Referring to fig. 1, a liquid flow meter 21 is installed on the surface of the delivery pipe 6 and on the right side of the first water pump 15, an electronic pressure gauge 22 is installed on the surface of the air delivery pipe 19 and below the second check valve 144, the liquid flow meter 21 can monitor the water flow inside the water inlet pipe 13 through the arrangement of the liquid flow meter 21 and the electronic pressure gauge 22, and the electronic pressure gauge 22 can monitor the pressure of the air inside the air delivery pipe 19.

Referring to fig. 4, the output terminals of the liquid flow meter 21 and the electronic pressure meter 22 are all in one-way electrical connection with the input terminal of the processor 2, and the output terminal of the processor 2 is respectively in one-way electrical connection with the input terminals of the first water pump 15, the second water pump 17, the air pump 18, the first electromagnetic valve 141, the second electromagnetic valve 142 and the driving motor 10, so that the liquid flow meter 21 and the electronic pressure meter 22 can transmit the monitored values to the processor 2, when the water amount is too low, the liquid flow meter 21 transmits a signal to the processor 2, then the processor 2 turns off the working power supply, if the air pressure is too high, the signal is transmitted to the processor 2 through the electronic pressure meter 22, and then the processor 2 turns off the working power supply.

Referring to fig. 1 and 4, a hydrogen concentration sensor 23 is installed above the inside of the hydrogen production device 3, and an output end of the hydrogen concentration sensor 23 is electrically connected to an input end of the processor 2 in a unidirectional manner, and the hydrogen concentration sensor 23 is capable of monitoring the hydrogen concentration produced by the hydrogen production device 3 and transmitting the monitored concentration value to the processor 2.

Referring to fig. 1, the stirring blades 12 are arranged from top to bottom at equal intervals, and there is a gap between the stirring blades 12 and the vertical pipe 7, so that the stirring blades 12 can be prevented from touching the vertical pipe 7 during the rotation process.

The working principle is as follows: when the hydrogen production device works, hydrogen produced by the hydrogen production device 3 enters the conveying pipe 6, the driving motor 10, the first water pump 15 and the first electromagnetic valve 141 are simultaneously started, the first water pump 15 enables water to enter the tank 4 through the water inlet pipe 13, the driving motor 10 drives the rotating rod 11 and the stirring blades 12 to start rotating, meanwhile, the second electromagnetic valve 142 is started, the hydrogen reaches the interior of the vertical pipe 7 through the conveying pipe 6, then the hydrogen is discharged from the air nozzle 8, as the air nozzles 8 are provided with a plurality of air nozzles 8 from top to bottom, the hydrogen can be dissolved in water with different depths, the stirring blades 12 start stirring the water in the tank 4, the hydrogen and the water are more fully fused, then the second water pump 17 is started, at the moment, the water containing the hydrogen enters the interior of the mixing cavity 5 through the water conveying pipe 16, the air pump 18 is simultaneously started, the air is compressed, and the compressed air enters the interior of the mixing cavity 5 through the air conveying pipe 19, the more the compressed air is accumulated in the mixing cavity 5, the water with hydrogen is sprayed out through the miniature throttler 20 under the action of the compressed air, and under the action of the specially designed miniature throttling hole, the water flow is compressed, collided and cut to release a large amount of micron-scale and nanometer-scale hydrogen water, and further release a large amount of foggy micron-scale bubbles and micron-scale bubbles, and the foggy bubbles have certain effects on cleaning and sterilization.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a high-efficient little bubble machine, includes drain pan (1), treater (2), hydrogen plant (3), jar body (4), hybrid chamber (5), inlet tube (13) and valve mechanism (14), its characterized in that: the top intercommunication of hydrogen plant (3) has conveyer pipe (6), standpipe (7) are all installed to the inside both sides of the jar body (4), and the top and conveyer pipe (6) of standpipe (7) communicate each other, the surface intercommunication of standpipe (7) has a plurality of air cock (8), the top bolt of hybrid chamber (5) has connect top shell (9), the internally mounted of top shell (9) has driving motor (10), the output shaft fixedly connected with bull stick (11) of driving motor (10), stirring vane (12) are all installed to the both sides of bull stick (11), the surface mounting of inlet tube (13) has first water pump (15), the one end of inlet tube (13) runs through to the inside of the jar body (4), the right side intercommunication of the jar body (4) has raceway (16), the other end of raceway (16) runs through to the inside of hybrid chamber (5), the surface mounting of raceway (16) has second water pump (17), air pump (18) are installed on the inside right side of drain pan (1), the gas outlet intercommunication of air pump (18) has gas-supply pipe (19), and the other end of gas-supply pipe (19) runs through to the inside of hybrid chamber (5), the right side of hybrid chamber (5) is through connecting pipe intercommunication have miniature flow controller (20).

2. The high-efficiency micro-bubble machine according to claim 1, wherein: the valve mechanism (14) comprises a first electromagnetic valve (141), a second electromagnetic valve (142), a first check valve (143) and a second check valve (144), the first electromagnetic valve (141) is installed on the surface of the water inlet pipe (13), the second electromagnetic valve (142) is installed on the surface of the conveying pipe (6), the first check valve (143) is installed on the surface of the water conveying pipe (16), and the second check valve (144) is installed on the surface of the air conveying pipe (19).

3. The high-efficiency micro-bubble machine according to claim 2, wherein: the surface of conveyer pipe (6) just is located the right side of first water pump (15) and installs liquid flow meter (21), electronic pressure table (22) are installed to the surface of gas-supply pipe (19) just is located the below of second check valve (144).

4. A high efficiency micro bubble machine according to claim 3, wherein: the output ends of the liquid flow meter (21) and the electronic pressure meter (22) are all in one-way electric connection with the input end of the processor (2), and the output end of the processor (2) is respectively in one-way electric connection with the input ends of the first water pump (15), the second water pump (17), the air pump (18), the first electromagnetic valve (141), the second electromagnetic valve (142) and the driving motor (10).

5. The high-efficiency micro-bubble machine according to claim 1, wherein: and a hydrogen concentration sensor (23) is arranged above the inside of the hydrogen production device (3), and the output end of the hydrogen concentration sensor (23) is in one-way electric connection with the input end of the processor (2).

6. The high-efficiency micro-bubble machine according to claim 1, wherein: stirring leaf (12) are from last to equidistant distribution down, and have the clearance between stirring leaf (12) and standpipe (7).

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