CN113912242A - Nano-scale fluid magnetization mixing bubble generator - Google Patents

Abstract

The invention discloses a nanoscale fluid magnetization mixed bubble generator which comprises a water inlet outer sleeve, a water outlet outer sleeve, a bubble increasing device plate, a magnetization mechanism, a spiral water flow guide column and an oxygen filtering mechanism, wherein the water inlet outer sleeve and the water outlet outer sleeve are arranged in front and at back and are fixedly connected, the bubble increasing device plate is arranged at a water outlet of the water outlet outer sleeve, the magnetization mechanism and the spiral water flow guide column are respectively arranged in the water inlet outer sleeve in front and at back, the magnetization mechanism is used for magnetizing water flow entering the water inlet outer sleeve, a spiral water tank is arranged on the outer side of the spiral water flow guide column, the spiral water tank is spirally arranged along the axial direction of the spiral water flow guide column, the spiral water tank is communicated with the water outlet outer sleeve, a pressure increasing air aeration port is arranged in the water outlet outer sleeve, and the pressure increasing air aeration port is communicated with an air outlet of the oxygen filtering mechanism. The bubble generator has simple and scientific structure, simple and convenient use, wide application range and high generation efficiency of nano-scale micro-bubbles, and solves the problem that the dual purposes of fluid magnetization and micro-bubble generation are simultaneously met in the industry.

Description

Nano-scale fluid magnetization mixing bubble generator

Technical Field

The invention relates to a bubble generator, in particular to a nanoscale fluid magnetization mixing bubble generator.

Background

In the current field of water treatment, bubble generators are gaining wide attention. Compared with a common bubble generator, the micro-nano bubble generator can generate micro bubbles with the diameter of 0.1-50 mu m, has obvious advantages in the aspects of concentration, size, uniformity and the like of the generated bubbles, and can achieve better using effect. However, the existing micro-nano bubble generator has single function and limited bubble breaking effect, the size of the generated bubbles cannot reach the nano level generally, the energy consumption is high, the efficiency is low, and the application of the micro-nano bubble generator in the field of water treatment is greatly limited.

Disclosure of Invention

The invention aims to solve the technical problem of providing a nanoscale fluid magnetization mixing bubble generator aiming at the defects of the prior art, the bubble generator has the advantages of simple and scientific structure, simple and convenient use, wide application range and high generation efficiency of nanoscale microbubbles, and solves the problem of meeting the dual purposes of fluid magnetization and microbubble generation in the industry.

The technical scheme adopted by the invention for solving the technical problems is as follows: the utility model provides a nanometer fluid magnetization mixes bubble generator, includes into water overcoat, play water overcoat, increases bubble device board, magnetization mechanism, spiral rivers guide post and oxygen filter mechanism, the overcoat of intaking with play water overcoat around set up and fixed connection, increase bubble device board set up the delivery port department of play water overcoat, magnetization mechanism with spiral rivers guide post around setting up respectively in the overcoat of intaking, magnetization mechanism be used for the magnetization process the water inlet of overcoat get into the rivers in the overcoat of intaking, the outside of spiral rivers guide post be provided with spiral water tank, spiral water tank along the axial of spiral rivers guide post be the heliciform setting, spiral water tank with play water overcoat communicate with each other, play water overcoat in be equipped with pressurization air exposure mouth, the pressurized air aeration opening is communicated with the air outlet of the oxygen filtering mechanism, and the oxygen filtering mechanism is used for sucking air, removing oxygen in the sucked air and guiding the air with the oxygen removed to the pressurized air aeration opening.

The working principle of the bubble generator of the invention is as follows: sewage enters the water inlet jacket through the water inlet of the water inlet jacket; the water flow entering the water inlet jacket is firstly magnetized by the magnetizing mechanism, so as to soften the water quality, kill partial microorganisms and degrade partial organic pollutants, and play a role in primarily purifying the sewage; the magnetized water flow is guided by the spiral water flow guide post and accelerated, and then flows through the spiral water tank on the spiral water flow guide post to form a vortex and then enters the water outlet jacket; the air is sucked by the oxygen filtering mechanism through the huge negative pressure generated when the high-speed water flow enters the water outlet jacket, the oxygen filtering mechanism removes oxygen in the sucked air and guides the air after the oxygen removal to the pressurizing air aeration port, the air after the oxygen removal and the flowing spiral accelerated high-speed water flow are fully and uniformly mixed under the vortex action through the pressurizing air aeration port to form nano-scale micro-bubbles, the nano-scale micro-bubbles can be efficiently generated and stably dissolved in the magnetized water, and the dissolved oxygen content in the obtained gas-liquid mixture is effectively controlled, so that the sewage eutrophication can be prevented and the growth of microorganisms can be restrained; when the gas-liquid mixture is discharged from the water outlet jacket, the gas-liquid mixture collides with the foam increasing device plate, and the generation efficiency of nano-scale micro bubbles is further improved.

Preferably, the magnetization mechanism include strong magnetism spacer sleeve and eight magnetic cores, strong magnetism spacer sleeve with the overcoat tight fit of intaking connect, the circumference of the lateral wall of strong magnetism spacer sleeve equally spaced apart and be equipped with four mounting grooves, every way the mounting groove in install two around the magnetic core, the position is relative twice the mounting groove in the magnetic core the S utmost point and the N utmost point of the magnetic core to setting up to the right side, the front side of spiral rivers guide post stretch into strong magnetism spacer sleeve with strong magnetism spacer sleeve tight fit connect, the rear side of spiral rivers guide post with the overcoat tight fit of intaking connect. Eight magnetic cores are arranged in the four directions in the mounting grooves, so that the magnetic induction lines can be completely densely distributed in the water inflow, and the magnetization effect on the water flow is ensured. In practical application, the number of the mounting grooves and the magnetic cores can be changed according to requirements.

Preferably, the oxygen filtering mechanism comprises an air filter, a first air pipe joint, an air pipe and a second air pipe joint which are sequentially connected, wherein a granular deoxidizer is filled in the air filter, an air inlet stud is installed on the side wall of the water outlet jacket, the second air pipe joint is in threaded connection with the air inlet stud, and an air outlet of the air inlet stud is communicated with the pressurized air aeration port.

Preferably, a diversion pressure increasing pipe is arranged in the water outlet jacket, the front side and the rear side of the diversion pressure increasing pipe are respectively communicated with the spiral water tank and the water outlet jacket, an annular gap is arranged between the rear end of the diversion pressure increasing pipe and the inner side wall of the water outlet jacket, the pressurized air aeration port is communicated with the annular gap, the pressurized air aeration port is arranged on the inner side wall of the water outlet jacket, the pressurized air aeration port is positioned on the outer side of the diversion pressure increasing pipe, and the air outlet of the air inlet stud is opposite to the pressurized air aeration port and is communicated with the pressurized air aeration port.

Preferably, the inner side wall of the front side of the diversion pressure charging pipe adopts a reducing cambered surface design with a large front part and a small back part, a bell mouth with a small front part and a large back part is arranged in the water outlet outer sleeve, the rear side of the diversion pressure charging pipe is communicated with the bell mouth, and the foam increasing device plate is arranged at the rear end of the bell mouth. The reducing cambered surface design of the inner side wall of the front side of the diversion pressure increasing pipe can further accelerate the water flow speed entering the water outlet jacket, and meanwhile, the bell mouth can increase the water pressure in unit area, improve the water flow speed flowing to the foam increasing device plate and increase the generation amount of nano-scale micro bubbles.

Preferably, the diversion pressure increasing pipe is a zirconium oxide diversion pressure increasing wear-resistant pipe, has good diversion, pressure increasing and wear-resistant effects, and is not easily worn by water flow.

Preferably, the foam increasing device plate is provided with a plurality of first taper holes with small front parts and large rear parts.

Preferably, the water inlet of the water inlet outer sleeve is provided with an energy-gathering guide plate. Sewage enters the water inlet jacket through the energy-gathering guide plates, and the energy-gathering guide plates are used for preliminarily forming bubbles and increasing the water inlet flow speed, so that the generation efficiency of nano-scale micro bubbles is further improved.

Preferably, the energy-gathering guide plate is provided with a plurality of second taper holes with big front and small back.

Preferably, the water inlet outer sleeve is in threaded connection with the water outlet outer sleeve.

Compared with the prior art, the invention has the following advantages: the nano-scale fluid magnetization mixing bubble generator has the advantages of simple and scientific structure, simple and convenient use, wide application range and high nano-scale micro-bubble generation efficiency, and solves the problem of meeting the dual purposes of fluid magnetization and micro-bubble generation in the industry at the same time. The bubble generator can ensure that air after oxygen is removed and flowing spiral accelerated high-speed water flow are fully and uniformly mixed under the vortex action to form nano-scale micro-bubbles, and the nano-scale micro-bubbles can be efficiently generated and stably dissolved in magnetized water, so that the dissolved oxygen content in the obtained gas-liquid mixture is effectively controlled, the eutrophication of sewage is prevented, and the growth of microorganisms is restrained.

Drawings

FIG. 1 is a schematic structural diagram of a nanoscale fluid magnetization mixing bubble generator in example 1;

FIG. 2 is an enlarged view of FIG. 1 at A;

FIG. 3 is a cross-sectional view B-B taken in FIG. 1, at a magnification of 3;

FIG. 4 is a schematic structural diagram of a nanoscale fluid magnetization mixing bubble generator in example 2;

FIG. 5 is an enlarged view at C of FIG. 4;

fig. 6 is a cross-sectional view taken along line D-D of fig. 4, enlarged 3 times.

Detailed Description

The invention is described in further detail below with reference to the accompanying examples.

The nanoscale fluid magnetization mixing bubble generator of embodiment 1, as shown in fig. 1 to fig. 3, comprises a water inlet jacket 1, a water outlet jacket 2, a bubble increasing device plate 3, a magnetization mechanism, a spiral water flow guide column 5 and an oxygen filtering mechanism, wherein the water inlet jacket 1 and the water outlet jacket 2 are arranged in front and at the back and are in threaded connection, the bubble increasing device plate 3 is provided with a plurality of first tapered holes 31 with small front and large back, the bubble increasing device plate 3 is arranged at a water outlet of the water outlet jacket 2, the magnetization mechanism and the spiral water flow guide column 5 are respectively arranged in the water inlet jacket 1 in front and at the back, the magnetization mechanism is used for magnetizing water flow in the water inlet jacket 1 through the water inlet of the water inlet jacket 1, the spiral water channel 51 is arranged outside the spiral water flow guide column 5, the spiral water channel 51 is spirally arranged along the axial direction of the spiral water flow guide column 5, the spiral water channel 51 is communicated with the water outlet jacket 2, a pressurizing air aeration port 21 is arranged in the water outlet jacket 2, the pressurized air aeration opening 21 is communicated with an air outlet of an oxygen filter mechanism, and the oxygen filter mechanism is used for sucking air, removing oxygen in the sucked air and guiding the air after removing the oxygen to the pressurized air aeration opening 21.

In embodiment 1, the magnetization mechanism includes strong magnetism spacer 61 and eight magnetic cores 62, strong magnetism spacer 61 is connected with 1 tight fit of overcoat that intakes, the equidistant interval in circumference of the lateral wall of strong magnetism spacer 61 is equipped with four mounting grooves 63, install two magnetic cores 62 around in every mounting groove 63, the S utmost point and the N utmost point of the magnetic core 62 in the two mounting grooves 63 that the position is relative are to setting up, the front side of spiral rivers guide post 5 stretches into strong magnetism spacer 61 and is connected with strong magnetism spacer 61 tight fit, the rear side and the 1 tight fit of overcoat that intakes of spiral rivers guide post 5 are connected.

In embodiment 1, the oxygen filtering mechanism includes an air filter 71, a first air pipe joint 72, an air pipe 73 and a second air pipe joint 74 which are connected in sequence, the air filter 71 is filled with a granular deoxidizer 75, in this embodiment, the granular deoxidizer 75 is a commercially available product, an air inlet stud 22 is installed on the side wall of the water outlet jacket 2, the second air pipe joint 74 is in threaded connection with the air inlet stud 22, and an air outlet of the air inlet stud 22 is communicated with the pressurized air aeration opening 21.

In embodiment 1, a diversion pressure increasing pipe 8 is arranged in the water outlet jacket 2, in this embodiment, the diversion pressure increasing pipe 8 is a zirconium oxide diversion pressure increasing wear-resistant pipe, the front side and the rear side of the diversion pressure increasing pipe 8 are respectively communicated with the spiral water tank 51 and the water outlet jacket 2, an annular gap 23 is arranged between the rear end of the diversion pressure increasing pipe 8 and the inner side wall of the water outlet jacket 2, a pressurized air aeration port 21 is communicated with the annular gap 23, the pressurized air aeration port 21 is arranged on the inner side wall of the water outlet jacket 2, the pressurized air aeration port 21 is positioned on the outer side of the diversion pressure increasing pipe 8, and the air outlet of the air inlet stud 22 is opposite to the pressurized air aeration port 21 and is communicated with the pressurized air aeration port 21; the inner side wall 81 of the front side of the diversion pressure increasing pipe 8 adopts a reducing cambered surface design with a large front part and a small back part, a bell mouth 24 with a small front part and a large back part is arranged in the water outlet outer sleeve 2, the back side of the diversion pressure increasing pipe 8 is communicated with the bell mouth 24, and the foam increasing device plate 3 is arranged at the back end of the bell mouth 24.

In the working process of the nano-scale fluid magnetization mixing bubble generator in the embodiment 1, sewage enters the water inlet outer sleeve 1 through the water inlet of the water inlet outer sleeve 1; the water flow entering the water inlet jacket 1 is firstly magnetized by the magnetizing mechanism, so as to soften the water quality, kill partial microorganisms and degrade partial organic pollutants, and play a role in primarily purifying the sewage; the magnetized water flow is guided and accelerated by the spiral water flow guide post 5, flows through the spiral water tank 51 on the spiral water flow guide post 5, enters the flow guide pressurizing pipe 8 to form a vortex, and then enters the water outlet jacket 2; the air is sucked by the oxygen filtering mechanism through the huge negative pressure generated when the high-speed water flow enters the water outlet jacket 2, the oxygen filtering mechanism removes oxygen in the sucked air and guides the air after removing the oxygen to the pressurized air aeration port 21, the air after removing the oxygen and the flowing spiral accelerated high-speed water flow are fully and uniformly mixed under the vortex action through the pressurized air aeration port 21 to form nano-scale micro-bubbles, the nano-scale micro-bubbles can be efficiently generated and stably dissolved in the magnetized water, and the dissolved oxygen content in the obtained gas-liquid mixture is effectively controlled, so that the sewage eutrophication can be prevented and the growth of microorganisms can be restrained; when the gas-liquid mixture is discharged from the bell mouth 24 in the water outlet jacket 2, the gas-liquid mixture collides with the foam increasing device plate 3, and the generation efficiency of nano-scale micro-bubbles is further improved.

The difference between the nanoscale fluid magnetization mixing bubble generator of embodiment 2 and embodiment 1 is that, in embodiment 2, as shown in fig. 4 to 6, an energy-gathering flow guide plate 4 is disposed at a water inlet of the water inlet jacket, and a plurality of second tapered holes 41 with a large front part and a small back part are formed in the energy-gathering flow guide plate 4. In the working process of the nanoscale fluid magnetization mixing bubble generator in the embodiment 2, sewage enters the water inlet jacket 1 through the energy-collecting guide plates 4, and the energy-collecting guide plates 4 can preliminarily form bubbles and increase the water inlet flow speed, so that the generation efficiency of nanoscale micro bubbles is further improved.

Claims (10)

1. A nanometer fluid magnetization mixing bubble generator is characterized by comprising a water inlet outer sleeve, a water outlet outer sleeve, a bubble increasing device plate, a magnetization mechanism, a spiral water flow guide column and an oxygen filtering mechanism, wherein the water inlet outer sleeve and the water outlet outer sleeve are arranged in the front and the back and are fixedly connected, the bubble increasing device plate is arranged at a water outlet of the water outlet outer sleeve, the magnetization mechanism and the spiral water flow guide column are respectively arranged in the water inlet outer sleeve in the front and the back, the magnetization mechanism is used for magnetizing water flow entering the water inlet outer sleeve through a water inlet of the water inlet outer sleeve, a spiral water channel is arranged on the outer side of the spiral water flow guide column, the spiral water channel is spirally arranged along the axial direction of the spiral water flow guide column, the spiral water channel is communicated with the water outlet outer sleeve, a pressurizing air aeration port is arranged in the water outlet outer sleeve, the pressurized air aeration opening is communicated with the air outlet of the oxygen filtering mechanism, and the oxygen filtering mechanism is used for sucking air, removing oxygen in the sucked air and guiding the air with the oxygen removed to the pressurized air aeration opening.

2. The nano-scale fluid magnetization mixing bubble generator according to claim 1, wherein the magnetization mechanism comprises a strong magnetic isolation sleeve and eight magnetic cores, the strong magnetic isolation sleeve is tightly fitted with the water inlet outer sleeve, four mounting grooves are formed in the outer side wall of the strong magnetic isolation sleeve in the circumferential direction at equal intervals, two magnetic cores are mounted in each mounting groove at the front and back, the S poles and the N poles of the magnetic cores in the two mounting grooves are oppositely arranged, the front side of the spiral water flow guide column extends into the strong magnetic isolation sleeve to be tightly fitted with the strong magnetic isolation sleeve, and the rear side of the spiral water flow guide column is tightly fitted with the water inlet outer sleeve.

3. The nano-scale fluid magnetization mixing bubble generator according to claim 1, wherein the oxygen filtering mechanism comprises an air filter, a first air pipe joint, an air pipe and a second air pipe joint which are sequentially connected, the air filter is filled with granular deoxidizer, an air inlet stud is installed on the side wall of the water outlet jacket, the second air pipe joint is in threaded connection with the air inlet stud, and an air outlet of the air inlet stud is communicated with the pressurized air aeration port.

4. The nano-scale fluid magnetization mixing bubble generator according to claim 3, wherein a flow guide pressurizing pipe is arranged in the water outlet jacket, the front side and the rear side of the flow guide pressurizing pipe are respectively communicated with the spiral water tank and the water outlet jacket, an annular gap is arranged between the rear end of the flow guide pressurizing pipe and the inner side wall of the water outlet jacket, the pressurized air aeration port is communicated with the annular gap, the pressurized air aeration port is arranged on the inner side wall of the water outlet jacket, the pressurized air aeration port is positioned outside the flow guide pressurizing pipe, and the air outlet of the air inlet stud is opposite to and communicated with the pressurized air aeration port.

5. The nanoscale fluid magnetization mixing bubble generator according to claim 4, wherein the inner side wall of the front side of the flow guide pressurizing pipe is designed to be a variable diameter arc surface with a large front part and a small back part, a bell mouth with a small front part and a large back part is arranged in the water outlet jacket, the back side of the flow guide pressurizing pipe is communicated with the bell mouth, and the bubble increasing device plate is arranged at the back end of the bell mouth.

6. The nano-scale fluid magnetization mixing bubble generator according to claim 4, wherein the flow guide pressurizing pipe is a zirconia flow guide pressurizing wear-resistant pipe.

7. The nano-scale fluid magnetization mixing bubble generator according to claim 1, wherein the bubble increasing device plate is provided with a plurality of first taper holes with small front parts and large rear parts.

8. The nano-scale fluid magnetization mixing bubble generator according to claim 1, wherein the water inlet of the water inlet jacket is provided with a energy-gathering flow guide plate.

9. The nanoscale fluid magnetization mixing bubble generator according to claim 8, wherein the energy-concentrating flow guide plate is provided with a plurality of second tapered holes with a large front part and a small back part.

10. The nano-scale fluid magnetization mixing bubble generator according to claim 1, wherein the water inlet outer sleeve is connected with the water outlet outer sleeve in a threaded manner.

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