CN212894010U - Micro-nano bubble generating device and air floatation device - Google Patents

Abstract

The utility model discloses a micro-nano bubble generating device and air supporting device. This micro-nano bubble generating device includes: the air bubble generating device comprises a frame, a micro-nano bubble generating assembly, a driving mechanism, an air compressor and an air pipe; the air pipe is provided with an air inlet hole and an air outlet hole; the gas compressor is connected with the gas inlet hole and is used for generating compressed gas and sending the compressed gas into the gas pipe through the gas inlet hole; the micro-nano bubble generation assembly comprises: the hollow shaft is provided with a cavity, and a plurality of microporous ceramic membranes and supports are sleeved on the hollow shaft, the microporous ceramic membranes are positioned between two adjacent supports, the microporous ceramic membranes and the cavity realize gas circulation, the hollow shaft is arranged on the frame, one end of the hollow shaft is connected with the gas outlet, and the other end of the hollow shaft is connected with the driving mechanism. The utility model discloses use the direct induced nanometer bubble that generates of micropore ceramic diaphragm, the bubble size degree of consistency is high.

Description

Micro-nano bubble generating device and air floatation device

Technical Field

The utility model relates to a double-phase mixing arrangement field of gas-liquid especially relates to a micro-nano bubble generating device and air supporting device.

Background

The micro-nano bubbles have the characteristics of small bubble size, large specific surface area, high adsorption efficiency, slow rising speed in water and the like. Micro-nano bubbles are introduced into water, so that solid impurities in water can be effectively separated, the oxygen concentration of a water body can be quickly improved, harmful bacteria in the water can be killed, and the friction coefficient of a solid-liquid interface can be reduced, therefore, compared with macro bubbles, the micro-nano bubble aeration water purification device has higher efficiency and wider application prospect in the fields of air floatation water purification, water body oxygenation, ozone water disinfection, micro-bubble drag reduction and the like. The bubble generator is the main equipment in the bubble manufacturing technology, the size, the quantity and the uniformity of generated bubbles are directly influenced by the performance of the bubble generator, and the existing methods for manufacturing micro bubbles are various, such as a physical cutting method, a pressurized dissolved air and gas release method, a water temperature difference method, an electric field method and the like. The micro-nano bubble generator based on the physical cutting method mainly cuts and breaks air through a porous filter medium, can cut and form micro-fine bubbles, has high efficiency, but also has the problems of low bubble homogenization degree and difficulty in meeting the requirement of large air charging quantity; the pressurized gas dissolving and releasing method has very low efficiency and high manufacturing cost; the water temperature difference method and the electric field method are complex in operation process, high in energy consumption and difficult to popularize in practical application.

Therefore, those skilled in the art are dedicated to research a novel micro-nano bubble generating device to solve the problems of low bubble homogenization degree, high energy consumption, complex operation, complex structure and the like in the existing method for manufacturing micro bubbles.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to solve above-mentioned problem, therefore provide a micro-nano bubble generating device that has that the aeration volume is big, the bubble diameter is little, the bubble size degree of consistency is high, the power consumption is few.

Specifically, the utility model provides a micro-nano bubble generating device, include: the air bubble generating device comprises a frame, a micro-nano bubble generating assembly, a driving mechanism, an air compressor and an air pipe;

the air pipe is provided with an air inlet hole and an air outlet hole;

the gas compressor is connected with the gas inlet hole and is used for generating compressed gas and sending the compressed gas into the gas pipe through the gas inlet hole;

the micro-nano bubble generation assembly comprises: the gas compressor comprises a hollow shaft with a cavity, a plurality of microporous ceramic membranes and supports, wherein the microporous ceramic membranes are sleeved on the hollow shaft, the microporous ceramic membranes are positioned between two adjacent supports, the microporous ceramic membranes realize gas circulation with the cavity, the hollow shaft is arranged on the frame, one end of the hollow shaft is connected with a gas outlet, and compressed gas entering the gas pipe can enter the cavity of the hollow shaft from the gas outlet and enter the microporous ceramic membranes;

the driving mechanism is connected with the other end of the hollow shaft, and the hollow shaft is driven to rotate through the driving mechanism, so that the microporous ceramic membrane is driven to rotate.

Further, the frame comprises a first mounting part and a second mounting part which are oppositely arranged, and a connecting piece for connecting the first mounting part and the second mounting part;

the hollow shaft penetrates through the first mounting part and the second mounting part, and the microporous ceramic membrane is located between the first mounting part and the second mounting part.

Further, the micro-nano bubble generating device further comprises:

a first seal for sealingly mounting the hollow shaft to the first mount; and/or

A second seal for sealingly mounting the hollow shaft to the second mount.

Further, the gas compressor is an air compressor; and/or

The compressed gas is fed into the gas pipe at a pressure of 1-2 bar; and/or

The rotating speed of the driving mechanism is 100-1000 rpm.

Furthermore, the both sides of micropore ceramic diaphragm are provided with and are used for with first sealing washer and second sealing washer of micropore ceramic diaphragm seal between two adjacent supports, be provided with on one of two adjacent supports with first sealing washer complex first holding tank, be provided with on another support with second sealing washer complex second holding tank.

Further, the hollow shaft is provided with a groove arranged along the circumferential direction of the hollow shaft, and when the microporous ceramic membrane is sleeved on the hollow shaft, the groove is opposite to the inner side wall of the microporous ceramic membrane;

and a second through hole is formed in the inner wall of the groove and communicated with the cavity of the hollow shaft, and compressed gas entering the cavity of the hollow shaft enters the microporous ceramic membrane through the second through hole.

Further, the hollow shaft has a baffle provided along a circumferential direction thereof, the baffle abutting against the bracket when the bracket is mounted to the hollow shaft.

Furthermore, the microporous ceramic membrane is provided with a third through hole for sleeving the hollow shaft, a plurality of airflow channels are arranged inside the microporous ceramic membrane, inlets of the airflow channels are communicated with the third through hole, and compressed gas enters the microporous ceramic membrane through the airflow channels.

Further, the diameter of the micro-nano bubbles generated by the microporous ceramic membrane is 30nm-100 μm; and/or

The distance between the adjacent microporous ceramic membranes is 1cm-5 cm.

The utility model also provides an air supporting device, include:

the container is used for containing liquid to be treated, the container is provided with a liquid inlet and a liquid outlet, the liquid to be treated enters the container from the liquid inlet, and the liquid to be treated flows out of the liquid outlet after being treated by the air floatation device;

the micro-nano bubble generating device is arranged on the container.

The utility model also provides a liquid treatment method, including following step:

1) providing the air floating device;

2) so that the liquid to be treated enters the container from the liquid inlet and flows out of the liquid outlet after being treated by the air floatation device.

Further, the liquid treatment comprises wastewater purification, water oxygenation, ozone water disinfection, river water purification or microbubble drag reduction.

The utility model provides a micro-nano bubble generating device, air supporting device and liquid processing method have following technological effect:

1. the utility model discloses a micro-nano bubble generating device develops and comes based on the rotating film technique, and the micropore ceramic diaphragm of use directly induces the generation nanometer bubble, need not to dissolve gas in aqueous, the utility model discloses a little, the bubble size degree of consistency of bubble diameter that micro-nano bubble generating device produced is high.

2. The utility model discloses a micro-nano bubble generating device subassembly is few, simple structure, easily installation, operation and maintenance, and area is minimum.

3. The utility model discloses a micropore ceramic diaphragm that air supporting device used is 600 multifold more than the surface area of traditional diffuser. The large gas-liquid interface combined with the slow rising bubble velocity produced by the low pressure enables higher gas transfer efficiency.

4. Use the utility model discloses micro-nano bubble generating device's air supporting device is through injecting compressed gas into the quill shaft with low pressure (1-2bar) to through in the micropore ceramic diaphragm pours into liquid into. At very low energy consumption (<0.05kWh/m³) Under the condition of (2), the nano-scale bubbles are generated, so that the energy is saved, and only a small amount of air is needed for low-pressure work. In addition, compare with traditional DAF (dissolved air flotation) system, the utility model discloses an air supporting device need not dissolve gas pitcher, circulating pump and nozzle, and the system is more reliable and produce bigger economic benefits.

5. The utility model discloses an air supporting device can use any kind of gas, and bubble size and quantity are adjustable, do not receive salinity, temperature and pH value to influence, and it is still reliable under extreme condition.

The conception, the specific structure and the technical effects of the present invention will be further described with reference to the accompanying drawings, so as to fully understand the objects, the features and the effects of the present invention.

Drawings

Fig. 1 is a schematic structural diagram of a preferred embodiment of the micro-nano bubble generating device of the present invention;

FIG. 2 is a schematic structural view of the hollow shaft of FIG. 1;

FIG. 3 is a schematic structural view of the microporous ceramic membrane of FIG. 1;

FIG. 4 is a schematic diagram of the structure of the microporous ceramic membrane of FIG. 1 engaged with a support;

FIG. 5 is a cross-sectional view of the microporous ceramic membrane of FIG. 1 mated with a support;

FIG. 6 is a schematic structural view of a microporous ceramic membrane in cooperation with a support showing yet another implementation of the support;

fig. 7 is a schematic structural diagram of an air floating device according to a preferred embodiment of the present invention.

The reference numbers illustrate: the micro-porous ceramic diaphragm comprises a driving mechanism 1, a hollow shaft 2, a groove 21, a second through hole 22, a cavity 23, a baffle 25, a micro-porous ceramic diaphragm 3, a third through hole 31, an inlet 32, an inner side wall 33 of the micro-porous ceramic diaphragm, a support 4, a fourth through hole 41, a tail 42, a first accommodating groove 43, a second accommodating groove 44, an air pipe 5, an air inlet 51, an air outlet 52, an air pipe joint 53, a connector 54, a first sealing piece 61, a second sealing piece 62, a frame 7, a first mounting piece 71, a second mounting piece 72, a connector 73, a gas compressor 8, a first sealing ring 91, a second sealing ring 92, a micro-nano bubble generating device 10, an air inlet 111, an air outlet 112, a scum pool 113, containers 114, 115, a scum baffle plate.

Detailed Description

The following description of the embodiments of the present invention is provided for illustrative purposes, and other advantages and effects of the present invention will be readily apparent to those skilled in the art from the disclosure herein. The present invention can also be implemented or applied through other different specific embodiments, and various details in the present specification can be modified or changed based on different viewpoints and applications without departing from the spirit of the present invention. It is to be noted that the features in the following embodiments and examples may be combined with each other without conflict.

It should be noted that the drawings provided in the following embodiments are only for illustrating the basic idea of the present invention, and the drawings only show the components related to the present invention rather than being drawn according to the number, shape and size of the components in actual implementation, and the form, amount and ratio of the components in actual implementation may be changed arbitrarily, and the layout of the components may be more complicated.

Embodiments of the present invention are described below with reference to the drawings. In the following drawings, like reference numerals are used for like parts. Although the embodiments are described using terms indicating directions such as "upper", "lower", "left", "right", etc., in the present invention, the terms are used herein for convenience of description only and are determined based on exemplary orientations shown in the drawings. Because the disclosed embodiments may be arranged in different orientations, these directional terms are used for descriptive purposes and are not to be construed as limiting.

Ordinal terms such as "first," "second," etc., used in the present application are used only for distinguishing and identifying, and do not have any other meanings, unless otherwise specified, and do not indicate a particular order or particular relevance. For example, the term "first via" does not itself imply the presence of "second via", nor does the term "second via" itself imply the presence of "first via".

Example 1

As shown in fig. 1-5, the micro-nano bubble generating device 10 of the present invention comprises a frame 7, a micro-nano bubble generating assembly, a driving mechanism 1, a gas compressor 8 and a gas pipe 5.

The air pipe 5 is provided with an air inlet hole 51 and an air outlet hole 52, and the air inlet hole 51 is connected with the air compressor 8 by using an air pipe joint 53. Micro-nano bubble takes place subassembly is located including quill shaft 2, a plurality of cover that have cavity 23 micropore ceramic diaphragm 3 and the support 4 of quill shaft 2, micropore ceramic diaphragm 3 is located between two adjacent supports 4, micropore ceramic diaphragm (3) with cavity (23) realize the gas circulation, and quill shaft 2 sets up in frame 7, and venthole 52 is connected to the one end of quill shaft 2, and the compressed gas that gets into trachea 5 can follow venthole 52 and get into cavity 23 of quill shaft 2 to go into micropore ceramic diaphragm 3. The driving mechanism 1 is connected with the other end of the hollow shaft 2, and the hollow shaft 2 is driven to rotate through the driving mechanism 1, so that the microporous ceramic membrane 3 on the hollow shaft 2 is driven to rotate.

The specific structure of the frame 7 is as shown in fig. 1, and comprises a first mounting part 71 and a second mounting part 72 which are oppositely arranged, and a connecting part 73 for connecting the first mounting part 71 and the second mounting part 72; the hollow shaft 2 penetrates the first mounting part 71 and the second mounting part 72, and the microporous ceramic membrane 3 is located between the first mounting part 71 and the second mounting part 72. In this embodiment, the first mounting part 71 and the second mounting part 72 are both mounting plates, the connecting part 73 is located between the first mounting part 71 and the second mounting part 72 and is fixedly connected with the first mounting part 71 and the second mounting part 72 respectively, and an accommodating space of the micro-nano bubble generating assembly is formed among the first mounting part 71, the second mounting part 72 and the connecting part 73. It should be understood that the frame 7 may also be in other forms as long as it can function as a carrier for the hollow shaft 2, housing the microporous ceramic membrane 3, and is not limited by the structure shown in fig. 1.

In order to make the hollow shaft 2 sealingly mounted to the first and second mounting parts 71, 72, so that the rotation of the hollow shaft 2 is more stable, a first seal 61 and a second seal 62 are also provided in the present example, the first seal 61 being used for sealingly mounting the hollow shaft 2 to the first mounting part 71, and the second seal 62 being used for sealingly mounting the hollow shaft 2 to the second mounting part 72.

The gas compressor 8 is used for generating compressed gas and sending the compressed gas into the air pipe 5 through the air inlet hole 51, the gas compressor 8 can be an air compressor, and then air enters the air pipe 5; the gas compressor 8 can also be a compressor of other gases, such as nitrogen, methane, oxygen, ozone, carbon dioxide, hydrogen, etc., and then into the gas pipe 5 is correspondingly nitrogen, methane, oxygen, ozone, carbon dioxide, hydrogen, etc. The specific gas compressor 8 is selected from which gas compressor, and the selection can be made according to actual conditions. In the utility model, the compressed gas can be sent into the gas pipe 5 at the pressure of 1-2bar, and the energy consumption is extremely low (<0.05kWh/m³) In the case of (2), nano-meter is generatedThe stage bubble is energy-saving, and only needs a small air quantity for low-pressure work.

The driving mechanism 1 can be a speed reducer, and the main purpose is to realize the rotation of the hollow shaft 2, so any power mechanism capable of realizing the rotation of the hollow shaft 2 is suitable, and the rotation speed of the driving mechanism 1 is preferably 100-.

The specific structure of the bracket 4 is shown in fig. 4-6, and includes a fourth through hole 41 for sleeving the hollow shaft 2. Fig. 4-5 show one implementation of the bracket 4. Fig. 6 shows another embodiment of the support 4, preferably with a tail 42 at the periphery of the support 4 to achieve the turbulent flow effect. The specific structure of the microporous ceramic membrane 3 is shown in fig. 3, and the microporous ceramic membrane 3 has an inner side wall 33 and a third through hole 31 for sleeving the hollow shaft 2, a plurality of airflow channels are arranged inside the microporous ceramic membrane 3, each airflow channel has an inlet 32, the inlets 32 are communicated with the third through hole 31, and the airflow channels are formed by extending the inlets 32 to the peripheral direction of the microporous ceramic membrane 3. The hollow shaft 2 has a specific structure as shown in fig. 2, and has a groove 21 disposed along its circumference, the inner wall of the groove 21 is provided with a second through hole 22, the second through hole 22 is communicated with a cavity 23 of the hollow shaft 2, the hollow shaft 2 further has a baffle 25 disposed along its circumference to limit the axial movement of the bracket 4, and one end of the hollow shaft 2 is connected with an air outlet 52 through a connector 54.

In order to realize the sealing between the microporous ceramic membrane 3 and the supports 4, in this embodiment, a first sealing ring 91 and a second sealing ring 92 are disposed on two sides of the microporous ceramic membrane 3, a first receiving groove 43 matched with the first sealing ring 91 is disposed on one support 4 of two adjacent supports 4, and a second receiving groove 44 matched with the second sealing ring 92 is disposed on the other support 4. By this design, the compressed gas entering the hollow shaft 2 will enter the microporous ceramic membrane 3 as far as possible without escaping to a place outside the support 4.

When the bracket 4 and the microporous ceramic membrane 3 are attached to the hollow shaft 2, one bracket 4 is first fitted to the hollow shaft 2, i.e., the bracket is fitted from the right end to the left end of the hollow shaft 2 until the bracket 4 abuts against the baffle 25, taking the direction of the hollow shaft 2 shown in fig. 2 as an example. After the first support 4 is installed, the sealing ring is placed into the accommodating groove of the support, the microporous ceramic membrane 3 is sleeved on the hollow shaft 2, the sealing ring and the second support 4 are sleeved on the hollow shaft 2, the inner side wall 33 of the microporous ceramic membrane 3 is opposite to the groove 21 of the hollow shaft 2, the microporous ceramic membrane 3 is located between every two adjacent supports 4, the microporous ceramic membrane 3 and the supports 4 are continuously installed in a repeated mode, the installation of the supports 4 and the microporous ceramic membrane 3 on the hollow shaft 2 can be completed, and after the installation is completed, the supports 4 are fixed by the fixing pieces to limit the axial movement of the supports 4.

The diameter of the micro-nano bubbles generated by the microporous ceramic membranes 3 in the implementation is 30nm-100 μm, and the distance between every two adjacent microporous ceramic membranes 3 is 1cm-5 cm.

When the micro-nano bubble generating device 10 is in operation, the compressed gas entering the cavity 23 of the hollow shaft 2 enters the microporous ceramic membrane 3 through the second through hole 22 on the hollow shaft 2 and the inlet 32 of the air flow channel, and escapes from the surface of the microporous ceramic membrane 3.

It should be understood that there are many other implementations of the hollow shaft 2 and the bracket 4, for example, the groove 21 on the hollow shaft 2 can be replaced by a protrusion along the axial or circumferential direction of the hollow shaft 2, and correspondingly, a recess is provided on the sidewall of the fourth through hole 41 of the bracket 4 to match with the groove; the shape of the cavity 23, the bracket 4 and the baffle 25 is cylindrical in this embodiment, and may be any shape in practice, and the present invention is not limited thereto.

Example 2

As shown in fig. 7, the air flotation device of the present invention includes a container 114 for containing the liquid to be treated and the micro-nano bubble generating device 10 in embodiment 1.

The container 114 is provided with a liquid inlet 111 and a liquid outlet 112, and liquid to be treated enters the container 114 from the liquid inlet 111 through a pump 117 and flows out from the liquid outlet 112 after being treated; the upper part of the container 114 can be provided with a scum pond 113 and a scum outlet 116 according to requirements, and the scum pond is not required to be designed if the liquid is only treated without generating scum, such as oxygenation of water.

The gas compressor 8 of the micro-nano bubble generating device 10 is arranged outside the container 114, the driving mechanism 1 can be arranged in the container 114 or outside the container 114, and other components such as the microporous ceramic membrane 3, the frame 7, the support 4, the gas pipe 5 and the like are arranged in the container 114.

A baffle plate 115 is arranged at the liquid inlet 111 of the container 114, and is particularly in a 7 shape, so that liquid entering from the liquid inlet 111 slowly and uniformly enters the container 114 from the bottom of the container 114.

Example 3

The utility model also provides a liquid treatment method, including following step:

1) providing the air flotation device of example 2;

2) so that the liquid to be treated enters the container 114 from the liquid inlet 111 and flows out from the liquid outlet 112 after the treatment is completed.

It should be understood that the liquid treatment in this embodiment includes, but is not limited to, wastewater purification, water oxygenation, ozonated water disinfection, river water purification, or micro-bubble drag reduction. Wherein the wastewater purification can be applied to the following industries: petroleum and natural gas, oil refining and petrochemicals, automotive and metal processing, food and beverages, and steel and aluminum production.

Example 4

The performance of the air flotation device in example 2 was tested.

a. Treating the industrial wastewater difficult to treat, wherein the size of the air floatation device is as follows: 1300mm 800m 1600mm, 1-5m³The treatment amount/h, the treatment results are shown in Table 1:

TABLE 1 results of Industrial wastewater treatment

The components contained in the sewage	Suspended solids content (ppm)	Oil content (ppm)
			Before treatment	456.52	7569.6
After treatment	3.29	15.4

As can be seen from Table 1, after the industrial wastewater is treated by the air floatation device, the removal rate of suspended solids is as high as more than 99%, and the removal rate of oil is as high as more than 99.5%. Therefore, the air floatation device achieves a very good treatment effect on industrial wastewater.

b. Carrying out oxygenation on 3 groups of water bodies, wherein the size of the air floatation device is as follows: 600 x 300mm, dissolved oxygen in the water body was measured during the treatment, and the results are shown in table 2:

TABLE 2 Water oxygenation treatment results

The above embodiments are merely illustrative of the principles and effects of the present invention, and are not to be construed as limiting the invention. Modifications and variations can be made to the above-described embodiments by those skilled in the art without departing from the spirit and scope of the present invention. Accordingly, it is intended that all equivalent modifications or changes which may be made by those skilled in the art without departing from the spirit and technical spirit of the present invention be covered by the claims of the present invention.

Claims (10)

1. A micro-nano bubble generating device is characterized by comprising: the air bubble generating device comprises a frame (7), a micro-nano bubble generating assembly, a driving mechanism (1), an air compressor (8) and an air pipe (5);

the air pipe (5) is provided with an air inlet hole (51) and an air outlet hole (52);

the gas compressor (8) is connected with the gas inlet hole (51), and the gas compressor (8) is used for generating compressed gas and sending the compressed gas into the gas pipe (5) through the gas inlet hole (51);

the micro-nano bubble generation assembly comprises: the gas compressor comprises a hollow shaft (2) with a cavity (23), a plurality of microporous ceramic membranes (3) and supports (4), wherein the microporous ceramic membranes (3) are sleeved on the hollow shaft (2), the microporous ceramic membranes (3) are positioned between two adjacent supports (4), the microporous ceramic membranes (3) and the cavity (23) realize gas circulation, the hollow shaft (2) is arranged on a frame (7), one end of the hollow shaft (2) is connected with a gas outlet hole (52), and compressed gas entering a gas pipe (5) can enter the cavity (23) of the hollow shaft (2) from the gas outlet hole (52) and enter the microporous ceramic membranes (3);

the driving mechanism (1) is connected with the other end of the hollow shaft (2), and the hollow shaft (2) is driven to rotate through the driving mechanism (1), so that the microporous ceramic membrane (3) is driven to rotate.

2. The micro-nano bubble generating device according to claim 1, wherein:

the frame (7) comprises a first mounting part (71) and a second mounting part (72) which are oppositely arranged, and a connecting part (73) for connecting the first mounting part (71) and the second mounting part (72);

the hollow shaft (2) penetrates through the first mounting part (71) and the second mounting part (72), and the microporous ceramic membrane (3) is located between the first mounting part (71) and the second mounting part (72).

3. The micro-nano bubble generating device according to claim 2, further comprising:

a first seal (61), said first seal (61) being for sealingly mounting said hollow shaft (2) to said first mounting (71); and/or

A second seal (62), the second seal (62) for sealingly mounting the hollow shaft (2) to the second mounting (72).

4. The micro-nano bubble generating device according to claim 1, wherein:

the gas compressor (8) is an air compressor; and/or

The rotating speed of the driving mechanism is 100-1000 rpm.

5. The micro-nano bubble generating device according to claim 4, wherein:

the both sides of micropore ceramic diaphragm (3) are provided with and are used for with micropore ceramic diaphragm (3) seal first sealing washer (91) and second sealing washer (92) between two adjacent supports (4), be provided with on one support (4) in two adjacent supports (4) with first sealing washer (91) complex first holding tank (43), be provided with on another support (4) with second sealing washer (92) complex second holding tank (44).

6. The micro-nano bubble generating device according to claim 5, wherein:

the hollow shaft (2) is provided with a groove (21) arranged along the circumferential direction of the hollow shaft, and when the microporous ceramic membrane (3) is sleeved on the hollow shaft (2), the groove (21) is opposite to the inner side wall (33) of the microporous ceramic membrane (3);

and a second through hole (22) is formed in the inner wall of the groove (21), the second through hole (22) is communicated with the cavity (23) of the hollow shaft (2), and compressed gas entering the cavity (23) of the hollow shaft (2) enters the microporous ceramic membrane (3) through the second through hole.

7. The micro-nano bubble generating device according to claim 6, wherein:

the hollow shaft (2) has a baffle (25) arranged along its circumference, the baffle (25) abutting the bracket (4) when the bracket (4) is mounted to the hollow shaft (2).

8. The micro-nano bubble generating device according to claim 7, wherein:

microporous ceramic diaphragm (3) have be used for the cover to locate the third through-hole (31) of quill shaft (2), the inside of microporous ceramic diaphragm (3) is equipped with a plurality of airflow channel, airflow channel's entry (32) with third through-hole (31) intercommunication, compressed gas passes through airflow channel gets into microporous ceramic diaphragm (3).

9. The micro-nano bubble generating device according to claim 7, wherein:

the diameter of the micro-nano bubbles generated by the microporous ceramic membrane (3) is 30nm-100 mu m; and/or

The distance between the adjacent microporous ceramic membranes (3) is 1cm-5 cm.

10. An air flotation device, comprising:

a container (114) for containing a liquid to be treated, wherein the container (114) is provided with a liquid inlet (111) and a liquid outlet (112), the liquid to be treated enters the container from the liquid inlet (111), and the liquid to be treated flows out from the liquid outlet (112) after being treated by the air flotation device;

the micro-nano bubble generating device according to any one of claims 1 to 9, disposed on the container (114).

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