CN217808828U - Protein separator and system - Google Patents

Abstract

The present disclosure provides a protein separator and system, comprising: a ultramicro nano bubble generating device and a separating mechanism; the separation mechanism comprises a main body and a foam-gathering device, the foam-gathering device is connected to the main body, and a reaction cavity is formed in the main body; the ultramicro nanometer bubble generating device is connected to the main body and used for mixing unpurified liquid and specified gas to form ultramicro nanometer bubble mixed liquid, and the ultramicro nanometer bubble mixed liquid at least comprises ultramicro nanometer bubbles; the ultramicro nanometer bubble generating device is used for conveying the ultramicro nanometer bubble mixed liquid to the reaction cavity; the main body is provided with a foam outlet, and when the ultramicro-nano bubbles adsorb free separated substances in the ultramicro-nano bubble mixed liquid to form froth, the foam outlet is used for allowing the froth to flow into the foam collector.

Description

Protein separator and system

Technical Field

The present disclosure relates to the field of separation equipment technology, and in particular, to a protein separator and system.

Background

At present, the method for separating protein and pollutants in a water body by using bubbles of a protein separator is an effective method for purifying the water body. Because the protein separator is mainly applied to seawater treatment and aquaculture industry, most of the protein separator to be treated is light suspended particles and organic matters, the existing protein separator has the problems of large bubble particle size, quick crushing, small bubble quantity and the like, so that the water body purification efficiency is low and the energy consumption is high.

Disclosure of Invention

The present disclosure provides a protein separator and system to at least solve the above technical problems in the prior art.

According to a first aspect of the present disclosure, there is provided a protein separator comprising: a ultramicro nano bubble generating device and a separating mechanism; the separation mechanism comprises a main body and a bubble-collecting device, wherein the bubble-collecting device is connected to the main body, and a reaction cavity is formed in the main body; the ultramicro nanometer bubble generating device is connected to the main body and is used for mixing unpurified liquid and specified gas to form ultramicro nanometer bubble mixed liquid, and the ultramicro nanometer bubble mixed liquid at least comprises ultramicro nanometer bubbles; the ultramicro nanometer bubble generating device is used for conveying the ultramicro nanometer bubble mixed liquid to the reaction cavity; the main body is provided with a foam outlet, and when the ultramicro-nano bubbles adsorb free separators in the ultramicro-nano bubble mixed solution to form froth, the foam outlet is used for allowing the froth in the reaction cavity to flow into the foam collecting device.

In an embodiment, the ultra-micro nano-bubble generating device is connected to an air inlet pipe, and the specified gas enters the ultra-micro nano-bubble generating device along the air inlet pipe.

In an embodiment, the air inlet pipe is connected with a filter, the filter is used for eliminating noise generated by the specified gas entering the air inlet pipe, and the filter is also used for filtering the specified gas passing through the filter.

In an implementation manner, the air inlet pipe is connected with an adjusting piece, and the adjusting piece is used for adjusting the flow of the specified gas entering the ultramicro nanometer bubble generating device.

In an embodiment, the main body is connected to a water outlet, and the water outlet is used for discharging purified liquid along the water outlet.

In an embodiment, the water outlet is connected to a regulating valve, the regulating valve is disposed between the water outlet and the reaction chamber, and the regulating valve is configured to regulate a size of the water outlet to regulate a water level of the unpurified liquid in the separation mechanism.

In one embodiment, a drain outlet is provided in the bubbler to discharge the ultra-micro nano-bubbles with the separated matter out of the bubbler.

In an implementation manner, a bubble diffusing bin is arranged between the ultramicro-nanobubble generating device and the reaction cavity, and the bubble diffusing bin is used for allowing the ultramicro-nanobubble mixed liquid to pass through so as to enable the ultramicro-nanobubbles to be uniformly distributed in the reaction cavity.

In one embodiment, the microbubble generator is configured to be disposed at a first location or a second location relative to the subject, the first location being configured to characterize an interior of the subject and the second location being configured to characterize an exterior of the subject.

According to a second aspect of the present disclosure, there is provided a system comprising at least one or more protein separators of any one of the preceding claims.

According to the protein separator and the protein separator system, designated gas and unpurified liquid are obtained through the ultramicro nanometer bubble generating device, the designated gas and the unpurified liquid are mixed to form ultramicro nanometer bubble mixed liquid, the ultramicro nanometer bubble generating device is connected to the main body of the separating mechanism, the ultramicro nanometer bubble mixed liquid is conveyed into the reaction cavity of the main body, so that ultramicro nanometer bubbles in the ultramicro nanometer bubble mixed liquid adsorb a separated matter in the unpurified liquid, ascend to the foam discharging port along the reaction cavity and are discharged from the foam discharging port, the ultramicro nanometer bubbles with the separated matter are gathered in the foam gathering device, and the purified liquid is retained in the reaction cavity.

It should be understood that the statements in this section do not necessarily identify key or critical features of the embodiments of the present disclosure, nor do they limit the scope of the present disclosure. Other features of the present disclosure will become apparent from the following description.

Drawings

The above and other objects, features and advantages of exemplary embodiments of the present disclosure will become readily apparent from the following detailed description read in conjunction with the accompanying drawings. Several embodiments of the present disclosure are illustrated by way of example, and not by way of limitation, in the figures of the accompanying drawings and in which:

in the drawings, the same or corresponding reference numerals indicate the same or corresponding parts.

FIG. 1 shows a first schematic diagram of a protein separator according to an embodiment of the present disclosure;

FIG. 2 shows a second schematic diagram of the structure of a protein separator according to an embodiment of the disclosure;

FIG. 3 shows a third schematic diagram of a protein separator according to an embodiment of the disclosure;

FIG. 4 shows a fourth schematic diagram of a protein separator according to an embodiment of the disclosure.

The reference numbers in the figures illustrate:

1. a water inlet pipe; 2. an ultra-micro nano-bubble generating device; 3. an air inlet pipe; 4. a filter; 5. a bubble diffusion bin; 6. a reaction chamber; 7. a bubble gathering device; 8. a water outlet; 9. adjusting a valve; 10. a sewage draining port; 11. an adjustment member; 12. a foam discharge port.

Detailed Description

In order to make the objects, features and advantages of the present disclosure more apparent and understandable, the technical solutions in the embodiments of the present disclosure will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present disclosure, and it is apparent that the described embodiments are only a part of the embodiments of the present disclosure, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments disclosed herein without making any creative effort, shall fall within the protection scope of the present disclosure.

FIG. 1 shows a first schematic diagram of a protein separator according to an embodiment of the disclosure; FIG. 2 shows a second schematic diagram of a protein separator according to an embodiment of the disclosure; FIG. 3 shows a third schematic diagram of a protein separator according to an embodiment of the disclosure; FIG. 4 shows a fourth schematic structural view of a protein separator according to an embodiment of the disclosure; please refer to fig. 1-4.

According to a first aspect of the present disclosure, there is provided a protein separator comprising: an ultramicro nanometer bubble generating device 2 and a separating mechanism; the separating mechanism comprises a main body and a bubble-collecting device 7, the bubble-collecting device 7 is connected on the main body, and a reaction cavity 6 is formed in the main body; the ultramicro nanometer bubble generating device 2 is connected to the main body, the ultramicro nanometer bubble generating device 2 is used for mixing unpurified liquid and specified gas to form ultramicro nanometer bubble mixed liquid, and the ultramicro nanometer bubble mixed liquid at least comprises ultramicro nanometer bubbles; the ultramicro-nano bubbles refer to bubbles with the size of 0.1 nanometer to 1000 micrometers; the ultramicro nanometer bubble generating device 2 is used for conveying the ultramicro nanometer bubble mixed liquid to the reaction cavity 6; the main body is provided with a foam outlet 12, and when the ultramicro-nano bubbles adsorb free separated substances in the ultramicro-nano bubble mixed liquid to form froth, the foam outlet 12 is used for allowing the froth in the reaction cavity to flow into the foam collector 7. The froth is formed in the reaction cavity 6 after the ultramicro nanometer bubbles absorb suspended matters and organic matters.

According to the protein separator and the protein separator system, the specified gas and the unpurified liquid are obtained through the ultramicro nanometer bubble generating device 2, the specified gas and the unpurified liquid are mixed to form an ultramicro nanometer bubble mixed solution, and the ultramicro nanometer bubble mixed solution at least comprises ultramicro nanometer bubbles; the ultramicro-nanometer bubble generating device 2 is connected to the main body of the separating mechanism, and the ultramicro-nanometer bubble mixed solution is conveyed into the reaction cavity 6 of the main body, so that the ultramicro-nanometer bubbles in the ultramicro-nanometer bubble mixed solution can absorb the separated substances in the unpurified liquid, rise to the foam discharge port 12 along the reaction cavity 6, and are discharged from the foam discharge port 12, thereby gathering the ultramicro-nanometer bubbles with the separated substances in the foam gathering device 7, and keeping the purified liquid in the reaction cavity 6.

In the embodiment of the present disclosure, the ultra micro nano bubble generating device 2 is disposed at a first position or a second position relative to the main body, the first position is used for representing the inside of the main body, and the second position is used for representing the outside of the main body, that is, the ultra micro nano bubble generating device 2 may be disposed inside the separating mechanism or disposed outside the separating mechanism, so as to adapt to different working environments. The microbubble generator 2 is a device for generating microbubbles. The separating mechanism comprises a main body and a foam collector 7, wherein the main body is the main part of the separating mechanism, and a reaction cavity 6 is formed in the main body; when the ultramicro nanometer bubble generating device 2 receives the appointed gas through the air inlet pipe 3 and absorbs the unpurified liquid through the driving part, the ultramicro nanometer bubble generating device 2 mixes and cuts the appointed gas and the unpurified liquid to form ultramicro nanometer bubble mixed liquid with ultramicro nanometer bubbles, and the ultramicro nanometer bubble mixed liquid passes through the bubble diffusion bin 5 by arranging the bubble diffusion bin 5 between the ultramicro nanometer bubble generating device 2 and the reaction cavity 6 so as to uniformly distribute the ultramicro nanometer bubbles in the ultramicro nanometer bubble mixed liquid. A plurality of through holes are formed on the bubble diffusion bin 5 for the ultramicro nano bubble mixed liquid to pass through. When the ultramicro nanometer bubble mixed solution passes through the through hole, the bubble diffusion bin 5 has a partial blocking effect on the nanometer bubble mixed solution, so that the ultramicro nanometer bubbles are more stably fused in the reaction cavity 6.

When the ultramicro-nano bubble mixed liquid is contained in the reaction cavity 6, the ultramicro-nano bubbles absorb the separated substances dissociating in the ultramicro-nano bubble mixed liquid, and carry the separated substances to rise along the reaction cavity 6 under the action of buoyancy force so as to reach the foam discharge port 12 and be discharged into the foam collector 7, thereby realizing protein separation. Wherein the isolate comprises at least: high molecular organic substances such as protein, saccharide, lipid colloid, etc.

In addition, a semicircular upper cover can be arranged above the foam discharge port 12, when cleaning agents are input through the water inlet pipe 1, the cleaning agents enter the foam collecting device 7 along the lower surface of the upper cover in an annular mode, the foam collecting device can be washed in a larger area, and the reaction cavity 6 and the foam collecting device 7 can be cleaned.

In the application, the specific surface area of the generated ultramicro nano bubbles is increased by a plurality of times compared with that of the common bubbles, so that the adsorption area is increased, organic matters can be more effectively adsorbed, and the purification efficiency of the protein separator is improved. The surface of the air bubble reaches the micro-nano level and is provided with negative charges, the ultra-micro nano air bubbles cannot be fused into large air bubbles due to the charge, and the negative charges on the surface can effectively adsorb micro separators, bacteria and organic matters in water to enable the micro separators, the bacteria and the organic matters to be polymerized into particles and float to the water surface, so that the protein separator can purify the water more thoroughly. The diameter of the ultramicro-nano bubble is very small, the compression action of the surface tension of the ultramicro-nano bubble on the surface of the bubble enables the diameter of the bubble to be continuously reduced and self-compressed, and finally the ultramicro-nano bubble bursts in water to generate a large amount of hydroxyl radicals. The hydroxyl free radicals have strong oxidizing property, can decompose ammonia nitrogen, organic matters and the like in water, and have more types and more thoroughness of cleanable sewage compared with the traditional protein separator. After the ultramicro nano bubble generation module is adopted, a large amount of bubbles can be generated without a high-power water pump, and the energy consumption of the protein separator in the use process is reduced. When realizing quality of water purification with the protein separation ware after the module combination takes place for the super little nanometer bubble, can improve the internal dissolved oxygen of water rapidly, compare with traditional protein separation ware when as quality of water clarification plant, can also regard as oxygen equipments, improve aquatic dissolved oxygen concentration greatly, when being applied to in the aquaculture field, when promoting quality of water, can improve aquaculture output, survival rate, support time temporarily. The ultramicro nanometer bubble generation module can use air as an air source, can also select to be introduced with other air sources, ozone, oxygen and the like, can improve the purification effect of the protein separator if ozone is introduced, and can disinfect and sterilize the water body, oxidize ammonia nitrogen and nitrite, enhance the transparency of the water body and further improve the water quality. The dissolved oxygen concentration in the water can be rapidly increased by introducing pure oxygen, and the aquaculture yield, the survival rate and the temporary culture time in the aquaculture process can be greatly increased. The ultramicro nano bubbles can be automatically compressed to generate crushing and breaking while being adsorbed, so that a large amount of surrounding hydroxyl free radicals are excited, and the ultrahigh temperature and the high pressure generated by breaking are generated, so that the adsorbed bacteria and viruses are killed, and the water quality of the protein separator is more thoroughly purified.

In one embodiment, the microbubble generator 2 is connected to an inlet 3, and the specified gas enters the microbubble generator along the inlet 3.

In the present disclosure, the ultramicro-nanobubble generating device 2 is connected with an air inlet tube 3, and obtains specified gas through the air inlet tube 3, wherein the specified gas includes but is not limited to ozone and oxygen. In intake pipe 3, be provided with filter 4, filter 4 is used for eliminating the noise that appointed gas got into intake pipe 3 and produces to noise when reducing equipment uses avoids producing noise pollution. When the predetermined gas passes through the filter 4, the filter 4 is also used to filter the predetermined gas, thereby eliminating impurities in the predetermined gas and increasing the service life of the ultra-fine nano-bubble generating device 2. The air inlet pipe 3 is connected with an adjusting piece 11, and the adjusting piece 11 is used for adjusting the flow of the specified gas entering the ultramicro nanometer bubble generating device 2. The air inlet pipe 3 is connected with an adjusting part 11, and the adjusting part 11 refers to an air quantity adjusting part.

In an implementation manner, the main body is connected with a water outlet 8, the water outlet 8 is used for discharging purified liquid along the water outlet 8, so as to discharge the purified liquid, thereby realizing the purification of a water source, and further, if a plurality of protein separators exist, the protein separators can be connected in series or in parallel by connecting the water outlet 8 with the water inlet; wherein, the series connection can realize the purification of water source many times, and the parallel connection can increase the handling capacity. The delivery port 8 is connected with the governing valve 9, specifically can be for water regulating valve 9, and governing valve 9 sets up between delivery port 8 and reaction chamber 6, and governing valve 9 is used for adjusting the size of delivery port 8, and the size of delivery port 8 refers to the size of delivery port 8, the size that is used for the area that supplies rivers to pass through to adjust the water level of unpurified liquid in separating mechanism. Further, governing valve 9 can be mobilizable separation blade, through the height of adjusting the separation blade to the realization is to 8 size regulation of delivery port, thereby under the unchangeable condition of the rate of intaking, adjusts the water level in the reaction chamber 6, thereby realizes discharging the super little nanometer bubble that has the separator. Further, be provided with drain 10 in the polybubble ware 7 to the ultramicro nanometer bubble that will have the separator discharges polybubble ware 7, the bottom of polybubble ware 7 is equipped with drain 10 for the superficial foam that the separator was adsorbed in the evacuation, in order to prevent bacterial growing. Further, the bubble gathering device 7 can be disassembled to clean and sterilize the bubble gathering device 7.

According to a second aspect of the present disclosure, there is provided a system, the separation system comprising at least one or more protein separators of any one of.

In the disclosed embodiment, a plurality of protein separators can be connected in parallel or in series, and the most effective purification mode is provided for different scenes and different unpurified liquids.

It should be understood that various forms of the flows shown above may be used, with steps reordered, added, or deleted. For example, the steps described in the present disclosure may be executed in parallel, sequentially, or in different orders, as long as the desired results of the technical solutions disclosed in the present disclosure can be achieved, and the present disclosure is not limited herein.

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, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present disclosure, "a plurality" means two or more unless specifically limited otherwise.

The above description is only for the specific embodiments of the present disclosure, but the scope of the present disclosure is not limited thereto, and any person skilled in the art can easily think of the changes or substitutions within the technical scope of the present disclosure, and shall cover the scope of the present disclosure. Therefore, the protection scope of the present disclosure shall be subject to the protection scope of the claims.

Claims (10)

1. A protein separator, comprising: an ultramicro nano bubble generating device (2) and a separating mechanism;

the separation mechanism comprises a main body and a bubble-gathering device (7), wherein the bubble-gathering device (7) is connected to the main body, and a reaction cavity (6) is formed in the main body;

the ultramicro nanometer bubble generating device (2) is connected to the main body, the ultramicro nanometer bubble generating device (2) is used for mixing unpurified liquid and specified gas to form ultramicro nanometer bubble mixed liquid, and the ultramicro nanometer bubble mixed liquid at least comprises ultramicro nanometer bubbles; the ultramicro nanometer bubble generating device (2) is used for conveying the ultramicro nanometer bubble mixed solution to the reaction cavity (6);

the main body is provided with a foam outlet (12), and when the ultramicro-nano bubbles adsorb free separated substances in the ultramicro-nano bubble mixed solution to form froth, the foam outlet (12) is used for allowing the froth in the reaction cavity to flow into the foam collector (7).

2. The protein separator according to claim 1, wherein the ultramicro nanobubble generating device (2) is connected to an air inlet pipe (3), and the specified gas enters the ultramicro nanobubble generating device (2) along the air inlet pipe (3).

3. Protein separator according to claim 2, characterized in that a filter (4) is connected to the inlet pipe (3), said filter (4) being adapted to eliminate noise generated by the inlet of the designated gas into the inlet pipe (3), said filter (4) being further adapted to filter the designated gas passing through said filter.

4. Protein separator according to claim 2, characterized in that the inlet pipe (3) is connected with a regulating member (11), and the regulating member (11) is used for regulating the flow of the specified gas into the ultramicro-nanobubble generating device (2).

5. The protein separator according to claim 1, wherein a water outlet (8) is connected to the body, said water outlet (8) being adapted for discharging purified liquid along said water outlet (8).

6. The protein separator according to claim 5, characterized in that a regulating valve (9) is connected to the water outlet (8), said regulating valve (9) being arranged between the water outlet (8) and the reaction chamber (6), said regulating valve (9) being adapted to regulate the size of the water outlet (8) for regulating the level of the raw liquid in the separation mechanism.

7. Protein separator according to claim 1, characterized in that a drain (10) is arranged in the bubbler (7) for draining the froth out of the bubbler (7).

8. The protein separator according to claim 1, wherein a bubble diffusion chamber (5) is disposed between the ultramicro-nanobubble generating device (2) and the reaction chamber (6), and the bubble diffusion chamber (5) is used for allowing the ultramicro-nanobubble mixed liquid to pass through so as to uniformly distribute the ultramicro-nanobubbles in the reaction chamber (6).

9. Protein separator according to claim 1, characterized in that said ultramicro-nanobubble generating means (2) are arranged in a first position or in a second position with respect to said body, said first position being intended to characterize the inside of said body and said second position being intended to characterize the outside of said body.

10. A system, wherein the separation system comprises at least one or more protein separators according to any one of claims 1 to 9.

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