CN116081748A

CN116081748A - Water treatment equipment

Info

Publication number: CN116081748A
Application number: CN202211596226.3A
Authority: CN
Inventors: 曾庆东; 王世友; 刘灵芝; 张朝波; 艾红霞; 刘彦光
Original assignee: Guangzhou Lanqing Environmental Engineering Co ltd; Guangdong Modern Agricultural Equipment Research Institute
Current assignee: Guangzhou Lanqing Environmental Engineering Co ltd; Guangdong Modern Agricultural Equipment Research Institute
Priority date: 2022-12-13
Filing date: 2022-12-13
Publication date: 2023-05-09

Abstract

The application discloses a water treatment device. The equipment consists of a multifunctional submersible pump, a protein separator, a plug flow aeration tank, a magnetic device and an ion device. The aeration is supplied by a permanent magnet fan, and the triangular columns of the rotary mixing aeration disc crush the gas and form directional plug flow through a plug flow box body so that the whole water area flows. The submerged pump sucks water from the far lower layer to realize the level displacement of water, and sucks air, microorganisms and ion gas from the air intake method of the air in the middle of the narrow pipe position with the fastest flow speed of the pump body which is continuously thinned. The invention has the remarkable effects that the water body is changed into magnetic water with strong oxygen gathering property and permeability through magnetic cutting, and microorganisms are easier to enter the sludge to realize mud-water simultaneous treatment. The water passes through a protein separator to separate and collect organic pollutants, and the water is discharged from the top of the pipe in a falling mode to realize cooling and blue algae prevention, ions generate charges and polarities, so that the pollutants are precipitated, the biochemical rate is increased, microorganisms are activated to recover ecological chains, and the water body is clear.

Description

Water treatment equipment

Technical Field

The invention relates to the field of water environment and aquaculture water quality improving and purifying equipment, in particular to water treatment equipment.

Background

In river and lake water environment treatment and aquaculture processes, water or aquaculture water quality is usually required to be lifted and purified.

The general protein separator device that uses includes the jar body, jar body bottom sets up the inlet tube, jar body one side sets up the air compressor intake pipe, water and gas are mixed after getting into the jar body separately, utilize the surface tension and the electrostatic interaction of tiny bubble to adsorb the organic matter (including dissolved state thing such as biological floc, organic matter and protein and granule form organic impurity generally) that mixes in water, blow and hold in the separation from water with the tiny bubble that has adsorbed organic matter again, the clean water after the separation is discharged by the outlet through the aqueduct, the organic matter after the separation is discharged through the separation discharge port on jar body top, the whole separation effect of protein separator device of above-mentioned mode is relatively poor, there is the improvement space.

Disclosure of Invention

In order to enhance the mixing effect of water and air in a protein separator, the present application provides a water treatment apparatus.

The application provides a water treatment facilities adopts following technical scheme:

the water treatment equipment comprises a protein separator, a main tank of the equipment and an auxiliary tank fixedly arranged at the bottom of an inner cavity of the main tank of the equipment, wherein the top end of the auxiliary tank is provided with an opening, and the top end of the main tank of the equipment is provided with a separation outlet for discharging organic matters and proteins and an air pressure balancing port for balancing air pressure;

the multifunctional diving aeration pump can be used for pumping air and water to be treated into the protein separator only by using the pump and mixing gas and liquid;

the liquid inlet pipe is used for communicating the multifunctional diving aeration pump and the protein separator, and one end of the liquid inlet pipe, which is away from the multifunctional diving aeration pump, extends into the auxiliary tank and is bent downwards to form an extension pipe section;

a drainage conduit communicated with the bottom of the protein separator and used for draining the purified water in the protein separator;

the plug flow box is positioned at one side of the protein separator, provided with a drainage conduit, and is used for carrying out directional plug flow aeration on the surrounding water body;

the frame is used for bearing the protein separator, the multifunctional diving aeration pump, the liquid inlet pipe, the drainage conduit and the push flow box, and the frame is provided with a floating strip.

By adopting the technical scheme, the multifunctional submersible aeration pump fully mixes air and water to be treated before entering the protein separator, so that the mixing effect of the air and the water is improved, and the air and the water enter the main tank of the protein separator through the same pipeline, so that an air compressor is directly omitted; the air and the water to be treated enter the liquid inlet pipe under the action of the multifunctional diving aeration pump, then enter the auxiliary tank through the port of the downward extending pipe section, and continuously move downwards for a certain distance after the water and the air are mixed and enter the auxiliary tank, so that the water to be treated and the air are further fully mixed in the inner cavity of the auxiliary tank, the mixing effect of the water and the air is further improved, the gas and the liquid can be fully mixed, and organic matters and proteins in the water are adsorbed on the surface of micro bubbles in the mixing process; due to the arrangement of the auxiliary tank, the mixing space of water, air and the air is reduced, the collision points are increased, the adhesion of organic substances and proteins in the water to the surfaces of the micro bubbles is facilitated, and the mixing effect is further improved; because the density of air is less than that of water, the bubbles continuously float upwards, evenly flow into the main tank of the equipment through the top opening of the auxiliary tank until the bubbles attached with organic matters and proteins are gradually extruded to the separation outlet at the top end of the protein separator to be discharged, and the purified water is discharged through the drainage conduit communicated with the bottom of the protein separator, so that the effect of water quality treatment is achieved, the mixing effect of water and air is gradually improved through the arrangement of the multifunctional submerged aeration pump, the extension pipe section and the auxiliary tank, more organic matters and proteins are attached to the bubbles, the separation effect of the organic matters and proteins in the water to be treated is further improved, and the problem that the cultured fish and shrimp eliminate foam degradation ammonia nitrogen and nitrite nitrogen is solved.

Preferably, the multifunctional submersible aeration pump comprises a shell, an air inlet pipe and a water pump assembly positioned in the inner cavity of the shell;

the one end intercommunication that the shell deviates from the feed liquor pipe has the inlet tube, the one end that the shell is close to the feed liquor pipe is the toper setting that the cross-sectional area reduces gradually and communicates with the feed liquor pipe, the intake pipe level sets up the horizontal segment in the shell and is used for the air inlet section with the outer intercommunication of horizontal segment and shell, the one end that the horizontal segment deviates from the air inlet section stretches into in the part that the shell is the toper setting to coincide with the axis.

By adopting the technical scheme, the cross-sectional area of the conical part of the shell is reduced, so that the water flow speed at the position is increased, the air inflow is increased, the adsorption of organic substances and proteins in water to be treated is facilitated, the circulation mode of the water bag air is adopted, the air inflow of the air bag air inlet method of the air bag positioned in the middle of the water pipe is large, the full mixing of air and water flow is facilitated, the air inflow of the air is greatly improved, the air inflow of the air can be increased by using a submersible pump with smaller power, and the energy loss is reduced.

Preferably, one end of the liquid inlet pipe is inserted into the inner cavity of the multifunctional diving aeration pump.

By adopting the technical scheme, because the water flow velocity in the liquid inlet pipe is greater than the water flow velocity in the multifunctional diving aeration pump, the air inflow is further increased, so that the air introduced into the multifunctional diving aeration pump is fully mixed with the water in the liquid inlet pipe, the mixing effect of the water and the air is improved, and the adsorption of organic substances and proteins in the water to be treated is facilitated.

Preferably, the air inlet section is a vertical section, and one end of the vertical section, which is away from the horizontal section, extends out of the inner cavity of the shell.

By adopting the technical scheme, the air inlet path of the air is shortened, and the air inlet time of the air is further shortened, so that the air inlet amount of the air in unit time is increased.

Preferably, one end of the shell, which is far away from the liquid inlet pipe, is communicated with a water pipe for introducing magnetic water into the multifunctional submersible aeration pump.

By adopting the technical scheme, as the magnetic water has oxygen gathering property, the surface tension of bubbles is reduced, the possibility of bubble breakage is reduced, the residence time of the bubbles in the water is further prolonged, the bubbles adsorbing organic substances and proteins are facilitated, and the organic substances and the proteins are separated from water.

Preferably, the separation outlet is communicated with an inclined separation pipe which is arranged obliquely downwards.

By adopting the technical scheme, the bubbles attached with organic matters and proteins are conveniently discharged and collected into the appointed container.

Preferably, the drainage conduit comprises a drainage pipe communicated with the protein separator, the drainage pipe comprises a transverse pipe extending into the protein separator and a vertical pipe communicated with one end of the transverse pipe, which is positioned outside the protein separator, an exhaust port is arranged at the top end of the vertical pipe, and a connecting pipe for discharging purified water is communicated with the vertical pipe.

By adopting the technical scheme, the purified water in the protein separator is discharged outside the protein separator through the drain pipe and the connecting pipe, and bubbles in the purified water are discharged through the exhaust port at the top end of the vertical pipe.

Preferably, the transverse pipe penetrates through the auxiliary tank, drain holes positioned at two sides of the auxiliary tank are formed in the transverse pipe, and the drain holes are positioned at the outer side of the auxiliary tank.

By adopting the technical scheme, the drain hole is arranged at the outer side of the auxiliary tank, so that purified water enters the main tank of the equipment through the auxiliary tank and then enters the drain pipe to be discharged, the flow path of the water is prolonged, and the purification effect of the water quality is improved; after the air and the water are fully mixed in the auxiliary tank, the air bubbles are gushed to the upper part of the main tank of the equipment to form an upward floating zone, and the water is gushed to the lower part of the main tank of the equipment to form a drainage zone, so that the separation of the air bubbles is facilitated.

Preferably, the drain hole horizontally penetrates through the transverse pipe.

By adopting the technical scheme, the water purifier is beneficial for water to enter the drain pipe from the two sides of the transverse pipe.

Preferably, the plug flow box comprises a box body fixedly arranged on the frame, an aeration disc arranged in the box body and an air supply pipe for supplying air to the aeration disc, wherein the air supply pipe is connected with second magnetic equipment, and a fan is connected to the air supply pipe.

By adopting the technical scheme, the air is supplied by the fan, and the aeration disc is used for breaking bubbles and then rising to form stronger directional airflow plug flow aeration.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the water pump is a multifunctional submersible pump, so that the gas and the liquid are mixed uniformly, and the effect is better. The multifunctional submersible pump sucks water from a distance, magnetic water with oxygen gathering property and strong permeability is introduced through the water guide pipe, mud water is treated simultaneously, organic matters are separated and collected through the protein separator, and purified water discharged from the protein separator is cooled in a falling mode, so that blue algae propagation is effectively inhibited.

2. The multifunctional submerged pump sucks ion gas or microorganisms from the air inlet pipe according to the requirement, the ions generate charges and polarities, pollutants are precipitated, the biochemical rate is increased, the microorganisms are activated, the ecological chain is recovered, and the water body is clear.

3. 8 push flow aeration devices are used for supplying air, bubbles are crushed by a triangular column of a rotary mixing aeration disc and then rise from a push flow box to form stronger directional push flow aeration, water flows, the upper layer and the lower layer of the water body are fully replaced, and compared with a conventional 1.5kw fishpond aerator, each push flow aeration device has the advantages that the aeration quantity is increased by more than 3 times, the electricity consumption is reduced by 90%, and the purposes of low energy consumption and good aeration effect are really achieved.

4. The air compressor and the slag scraping machine which are needed by air floatation are eliminated, the height of one third of the main tank of the air floatation device can be reduced, and the device not only plays the role of a protein separator, but also plays the role of the air floatation device.

Drawings

Fig. 1 is a schematic view showing the overall structure of a water treatment apparatus in an embodiment.

Fig. 2 is a schematic cross-sectional view showing a water treatment apparatus in an embodiment.

Fig. 3 is a schematic view showing a partial structure of the water treatment apparatus in the embodiment.

Fig. 4 is a partial structural schematic diagram showing the structure of the push box in the embodiment.

Fig. 5 is a schematic cross-sectional view showing the position of a triangular column in the embodiment.

Reference numerals illustrate:

1. a protein separator; 11. a main tank of the device; 111. a vertical separator tube; 112. tilting the separating tube; 12. a sub tank;

2. multifunctional diving aeration pump; 21. a housing; 211. a water inlet pipe; 212. a water pipe; 2121. a first magnetic device; 22. a water pump assembly; 221. a pump head; 222. a power motor; 23. an air inlet pipe; 231. a horizontal section; 232. a vertical section; 233. a guide tube; 234. a reducing joint; 24. an ion generator; 25. a fungus throwing tank;

3. a liquid inlet pipe; 31. an extension pipe section;

4. a drainage conduit; 41. a drain pipe; 411. a transverse tube; 4111. a drain hole; 412. a standpipe; 4121. an exhaust pipe; 42. a control valve; 43. and (5) connecting pipes.

5. A push flow box; 51. a case; 511. a baffle; 52. an aeration disc; 521. triangular columns; 53. an air supply pipe; 531. a bottom tube; 532. an epitaxial tube; 54. a second magnetic device;

6. a frame; 61. and (5) floating strips.

Detailed Description

The present application is described in further detail below in conjunction with figures 1-5.

The embodiment of the application discloses water treatment equipment.

Referring to fig. 1, a water treatment apparatus includes a protein separator 1, a multifunctional submersible aeration pump 2 provided at one side of the protein separator 1, a liquid inlet pipe 3 for communicating the multifunctional submersible aeration pump 2 with the protein separator 1, a separation outlet and an air pressure balance port provided at the top of the protein separator 1, a drainage pipe 4 provided at the other side of the protein separator 1 near the bottom, a plug flow box 5 for carrying out directional plug flow aeration on the water flow around, and a frame 6 for carrying each member, wherein floating strips 61 are fixed at both sides of the frame 6.

The multifunctional submersible aeration pump 2 is used for introducing water and air to be treated into the protein separator 1 through the liquid inlet pipe 3, the air and the water to be treated are fully mixed, a plurality of tiny bubbles are formed in the water to be treated, organic substances and proteins are adsorbed on the surfaces of the tiny bubbles, the bubbles attached with the organic substances and the proteins are gradually extruded to a separation outlet at the top end of the protein separator 1 to be discharged, and purified water is discharged through the water discharge pipe 4, so that the effect of water quality treatment is achieved.

Referring to fig. 1 and 2, the protein separator 1 comprises a main tank 11 and an auxiliary tank 12 coaxially arranged in the inner cavity of the main tank 11, a distance is reserved between the outer wall of the auxiliary tank 12 and the inner wall of the main tank 11, the bottom end of the auxiliary tank 12 is fixed on the bottom wall of the main tank 11, the top end of the auxiliary tank 12 is provided with an opening, and the top end of the auxiliary tank 12 is lower than half of the whole height of the main tank 11.

The top end of the equipment main tank 11 is in a cone shape with gradually reduced cross-sectional area, a vertical separation pipe 111 coaxial with the equipment main tank 11 is communicated with the center position of the top end of the equipment main tank 11, and the top end opening of the vertical separation pipe 111 is an air pressure balance port for balancing air pressure; one side of the vertical separation tube 111 is communicated with an inclined separation tube 112 which is inclined downwards, and one end port of the inclined separation tube 112, which is away from the vertical separation tube 111, is a separation outlet, in this embodiment, the inclined separation tube 112 is a reducer tube with a reduced diameter, and the inclined angle of the inclined separation tube 112 is preferably 45 degrees, so that bubbles are discharged through the inclined separation tube 112.

The multifunctional submerged aeration pump 2 is communicated with the main tank 11 of the equipment through a liquid inlet pipe 3, one end of the liquid inlet pipe 3 is inserted into the output end of the multifunctional submerged aeration pump 2, and the other end of the liquid inlet pipe 3 sequentially penetrates through the side walls of the main tank 11 and the auxiliary tank 12 of the equipment to extend into the inner cavity of the auxiliary tank 12; one end of the liquid inlet pipe 3 extending into the inner cavity of the auxiliary tank 12 is bent downwards to form an extension pipe section 31, the extension pipe section 31 and the liquid inlet pipe 3 are in arc transition, the extension pipe section 31 and the auxiliary tank 12 are coaxially arranged, and the end face of one end of the extension pipe section 31, which is away from the liquid inlet pipe 3, is located below one half of the height of the auxiliary tank 12.

The water and air to be treated are introduced into the liquid inlet pipe 3 under the action of the multifunctional diving aeration pump 2, then enter the auxiliary tank 12 through the port of the extension pipe section 31, the water and air to be treated entering the auxiliary tank 12 continuously move downwards for a certain distance, so that the water and air to be treated are fully mixed, then flow into the main tank 11 of the equipment through the opening at the top end of the auxiliary tank 12, the moving path of the water and air to be treated when entering the tank body is prolonged, the mixing time of the water and air to be treated is prolonged, and the mixing space of the water and air is reduced due to the smaller space of the inner cavity of the auxiliary tank 12, the collision point is increased, organic matters and proteins in the water are more beneficial to be attached to the surface of the micro air bubbles, and the mixing effect of the water and air to be treated is further improved.

The multifunctional submersible aeration pump 2 comprises a shell 21, a water pump assembly 22 arranged in the inner cavity of the shell 21 and an air inlet pipe 23 arranged in the shell 21.

The cross section shape of the shell 21 is circular, one end of the shell 21 close to the liquid inlet pipe 3 is in a conical arrangement with gradually reduced cross section area, and one end of the shell 21 close to the liquid inlet pipe 3 is wrapped and sleeved on the outer side of the liquid inlet pipe 3.

The air inlet pipe 23 is communicated with an ion generator 24 and a bacteria feeding tank 25, ion gas or microorganisms are sucked from the inlet of the air inlet pipe 23 according to the requirement, the ions generate electric charges, pollutants are precipitated, the biochemical rate is increased, the microorganisms are activated, the ecological chain is restored, and the water body is clear.

The air inlet pipe 23 comprises a vertical section 232 and a horizontal section 231, the horizontal section 231 is coaxially arranged with the shell 21, one end of the horizontal section 231 is communicated with the vertical section 232, the other end of the horizontal section 231 extends into the liquid inlet pipe 3, and a distance is reserved between the outer wall of the horizontal section 231 and the inner wall of the liquid inlet pipe 3; the vertical section 232 is positioned on the front side of the water pump assembly 22, and the top end of the vertical section 232 extends out of the inner cavity of the housing 21 through the housing 21.

In order to facilitate air entering the air inlet pipe 23, the top end of the vertical section 232 is also communicated with a guide pipe 233, the guide pipe 233 and the vertical section 232 of the air inlet pipe 23 are coaxially arranged, and the inner diameter of the guide pipe 233 is larger than that of the vertical section 232. The top end of the guiding pipe 233 is communicated with a reducing joint 234 for further expanding the pipe diameter.

One end of the shell 21, which is away from the liquid inlet pipe 3, is communicated with a water inlet pipe 211, and the water inlet pipe 211, the shell 21 and the liquid inlet pipe 3 are coaxial.

The water inlet pipe 211 is communicated with a water inlet pipe 212 for introducing magnetic water into the multifunctional diving aeration pump 2, the water inlet pipe 212 is arranged in an L shape, the part of the water inlet pipe 211, which is positioned in the water inlet pipe 212, is coaxial with the water inlet pipe 211, and one end of the water inlet pipe 212, which is positioned outside the water inlet pipe 211, is used for being communicated with the first magnetic equipment 2121. The magnetic water acted by the first magnetic device 2121 is introduced into the multifunctional diving aeration pump 2 through the water-introducing pipe 212, and because of the oxygen gathering property of the magnetism, the surface tension of bubbles is reduced, the possibility of bubble breakage is reduced, the residence time of the bubbles is further prolonged, and the bubbles which adsorb organic substances and proteins are favorable for separating the organic substances and proteins from water.

The water pump assembly 22 includes a pump head 221 and a power motor 222 for driving the pump head 221, and the pump head 221 and the power motor 222 are all of the prior art and are not described herein.

The drain pipe 4 includes a drain pipe 41, a control valve 42 provided in the drain pipe 41, and a connection pipe 43 communicating with the drain pipe 41.

The drain pipe 41 comprises a transverse pipe 411 and a vertical pipe 412, one end of the transverse pipe 411 extends into the inner cavity at the bottom of the protein separator 1, and the other end of the transverse pipe 411 is positioned outside the protein separator 1 and communicated with the vertical pipe 412.

Referring to fig. 2 and 3, the portion of the transverse tube 411 located in the protein separator 1 is disposed through the auxiliary tank 12, the transverse tube 411 is provided with drainage holes 4111 located at two sides of the auxiliary tank 12, the drainage holes 4111 are located between the outer wall of the auxiliary tank 12 and the inner wall of the main tank 11, and in this embodiment, the drainage holes 4111 horizontally penetrate through the transverse tube 411.

The control valve 42 is disposed on the standpipe 412 for controlling the water level in the protein separator 1, the top end of the standpipe 412 is tapered with a gradually decreasing cross-sectional area, a coaxial exhaust pipe 4121 is connected to the center of the top end of the standpipe 412, and an end of the exhaust pipe 4121 facing away from the standpipe 412 is provided as an exhaust port.

The connecting pipe 43 is connected to one side of the upper part of the standpipe 412, one end of the connecting pipe 43, which is away from the standpipe 412, is a water outlet, and clean water discharged through the water outlet is cooled in a falling mode.

Referring to fig. 1, 4 and 5, the impeller 5 is fixed on a side of the frame 6 facing away from the multifunctional submersible aerator pump 2, and the impeller 5 includes a box 51, a plurality of aeration discs 52, an air supply pipe 53, and a fan connected to an air inlet end of the air supply pipe 53.

The box 51 is fixed on the frame 6, the opening of the box 51 gradually increases from one side close to the protein separator 1 to the other side, the bottom wall of the inner cavity of the box 51 is a plane, the top wall is an inclined plane, and the top of the larger end of the box 51 is provided with a baffle 511.

The aeration discs 52 are arranged on the bottom wall of the inner cavity of the box body 51 in a rectangular array, and a plurality of triangular posts 521 for puncturing bubbles are arranged on the outer cambered surface of the aeration discs 52 and the top wall of the inner cavity of the box body 51.

The air supply pipe 53 is used for supplying air to the aeration discs 52, the air supply pipe 53 comprises a bottom pipe 531 which is communicated with a plurality of aeration discs one by one and an extension pipe 532 which extends out of the outer side of the box body 51, the extension pipe 532 is communicated with the bottom pipe 531, and the variable frequency fan is arranged at a port of one end of the extension pipe 532, which is away from the bottom pipe 531. The epitaxial tube 532 is in communication with a second magnetic device 54, the second magnetic device 54 being configured to condition the gas in the epitaxial tube 532 as a magnetic gas.

The variable frequency fan supplies air through the air supply pipe 53, and bubbles are broken through the aeration disc 52 and then rise to form stronger directional plug flow aeration.

The multifunctional submersible aeration pump 2 is output after gas and liquid are mixed, the flow speed is continuously accelerated by utilizing the continuously thinned outlet, air is sucked in the middle of the pipe position with the fastest flow speed by utilizing the principle that the faster the flow speed is, the air quantity of the air entering from the water-in-water gas inlet method in the middle of the thin pipe is larger, the multifunctional submersible aeration pump 2 can be respectively connected with gas, bacteria, medicine, magnetic water and ion equipment according to the requirement, the liquid inlet pipe 3 can be respectively conveyed to the protein separator 1 according to the requirement, the port of the extension pipe section 31 faces downwards to the auxiliary tank 12, so that the gas and liquid are more uniformly mixed, and the folded aeration, microbial filler contact oxidation column, contact oxidation bed, suspended filler aeration tank and the like are combined into water environment ecological restoration equipment with different functions to remove pollutants, so that the water quality treatment effect is improved, the operation procedure is simplified, the energy can be saved, and the operation cost is reduced.

The implementation principle of the water treatment equipment in the embodiment of the application is as follows:

the water to be treated is introduced from the water inlet pipe 211, the magnetic water is introduced from the water inlet pipe 212, the ion gas or microorganism is sucked from the air inlet pipe 23 as required, the ions generate electric charge, the pollutants are precipitated, the biochemical rate is increased, the microorganism is activated, the ecological chain is recovered, and the water body is clear;

the multifunctional submersible aeration pump 2 fully mixes air and water to be treated before entering the protein separator 1, the air and the water to be treated enter the liquid inlet pipe 3 under the action of the multifunctional submersible aeration pump 2, then enter the auxiliary tank 12 through the port of the downward extending pipe section 31 and continuously move downwards for a certain distance to fully mix, organic substances and proteins in the water are adsorbed on the surfaces of micro bubbles, and the mixing space of the air and the water is reduced due to the smaller space of the inner cavity of the auxiliary tank 12, so that the collision point is increased, and the adhesion of the organic substances and the proteins in the water to the surfaces of the micro bubbles is facilitated; because the density of the air is smaller than that of the water, the bubbles attached with organic matters and protein continuously float upwards and flow into the main tank 11 of the equipment through the top opening of the auxiliary tank 12 until the bubbles attached with the organic matters and protein are gradually extruded to the separation outlet at the top end of the protein separator 1 to be discharged, and the purified water enters the drain pipe 41 and the connecting pipe 43 through the drain hole 4111 to be discharged, so that the effect of water quality treatment is achieved;

meanwhile, the variable frequency fan supplies air through the air supply pipe, and bubbles rise to form stronger directional plug flow aeration after being broken by the aeration disc.

The foregoing are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in any way, therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims

1. The water treatment equipment is characterized by comprising a protein separator (1), a main equipment tank (11) and an auxiliary tank (12) fixedly arranged at the bottom of the inner cavity of the main equipment tank (11), wherein the top end of the auxiliary tank (12) is open, and the top end of the main equipment tank (11) is provided with a separation outlet for discharging organic substances and proteins and an air pressure balancing port for balancing air pressure;

the multifunctional diving aeration pump (2) is used for pumping air and water to be treated into the protein separator (1);

the liquid inlet pipe (3) is used for communicating the multifunctional submerged aeration pump (2) and the protein separator (1), and one end of the liquid inlet pipe (3) deviating from the multifunctional submerged aeration pump (2) extends into the auxiliary tank (12) and is bent downwards to form an extension pipe section (31);

a drainage conduit (4) communicated with the bottom of the protein separator (1) and used for draining the purified water in the protein separator (1);

the plug flow box (5) is positioned at one side of the protein separator (1) provided with the drainage conduit (4) and is used for carrying out directional plug flow aeration on the surrounding water body;

the frame (6) is used for bearing the protein separator (1), the multifunctional submersible aeration pump (2), the liquid inlet pipe (3), the drainage guide pipe (4) and the plug-flow box (5), and the frame (6) is provided with a floating strip (61).

2. A water treatment apparatus according to claim 1, wherein: the multifunctional submersible aeration pump (2) comprises a shell (21), an air inlet pipe (23) and a water pump assembly (22) positioned in the inner cavity of the shell (21);

the utility model discloses a liquid inlet pipe, including shell (21), inlet tube (211) has been deviate from to the one end intercommunication of feed liquor pipe (3), the one end that shell (21) is close to feed liquor pipe (3) is the toper setting that the cross-sectional area reduces gradually and communicates with feed liquor pipe (3), intake pipe (23) are including the level setting in shell (21) horizontal segment (231) and be used for with the air inlet section of the outside intercommunication of horizontal segment (231) and shell (21), the one end that horizontal segment (231) deviate from the air inlet section stretches into in the part that shell (21) are the toper setting.

3. A water treatment apparatus according to claim 2, wherein: one end of the liquid inlet pipe (3) is inserted into the inner cavity of the multifunctional diving aeration pump (2), and one end of the horizontal section (231) deviating from the air inlet section stretches into the liquid inlet pipe (3).

4. A water treatment apparatus according to claim 2, wherein: the air inlet section is a vertical section (232), and one end of the vertical section (232) deviating from the horizontal section (231) extends out of the inner cavity of the shell (21).

5. A water treatment apparatus according to claim 2, wherein: one end of the shell (21) deviating from the liquid inlet pipe (3) is communicated with a water pipe (212) for introducing magnetic water into the multifunctional diving aeration pump (2).

6. A water treatment apparatus according to claim 1, wherein: the separation outlet is communicated with an inclined separation pipe (112) which is arranged obliquely downwards.

7. A water treatment apparatus according to claim 1, wherein: the drainage pipe (4) comprises a drainage pipe (41) communicated with the protein separator (1), the drainage pipe (41) comprises a transverse pipe (411) extending into the protein separator (1) and a vertical pipe (412) communicated with one end of the transverse pipe (411) positioned outside the protein separator (1), an exhaust port is arranged at the top end of the vertical pipe (412), and a connecting pipe (43) for discharging purified water is communicated with the vertical pipe (412).

8. A water treatment apparatus according to claim 7, wherein: the transverse pipe (411) penetrates through the auxiliary tank (12), drain holes (4111) are formed in the transverse pipe (411) and are located at two sides of the auxiliary tank (12), and the drain holes (4111) are located at the outer side of the auxiliary tank (12).

9. A water treatment apparatus according to claim 8, wherein: the drain hole (4111) horizontally penetrates through the transverse pipe (411).

10. A water treatment apparatus according to claim 1, wherein: the plug flow box (5) comprises a box body (51) fixedly arranged on the frame (6), an aeration disc (52) arranged in the box body (51) and an air supply pipe (53) for supplying air to the aeration disc (52), wherein the air supply pipe (53) is connected with a second magnetic device (54), and the air supply pipe (53) is connected with a variable-frequency fan.