CN117756271A

CN117756271A - Multifunctional aeration equipment

Info

Publication number: CN117756271A
Application number: CN202410170895.7A
Authority: CN
Inventors: 刘彦光; 何耀武; 张严
Original assignee: Guangdong Jubang Ecological Environment Technology Co ltd
Current assignee: Guangdong Jubang Ecological Environment Technology Co ltd
Priority date: 2024-02-06
Filing date: 2024-02-06
Publication date: 2024-03-26

Abstract

The invention discloses multifunctional aeration equipment which comprises a frame body, a plurality of microorganism stuffing boxes, a magnetic force generator, a nano air pump, an ion generation and small molecule generator, wherein the water outlet directions of at least two of a first bending pipe, a second bending pipe, a third bending pipe, a fourth bending pipe, a fifth bending pipe and a sixth bending pipe of the frame body are different, so that the sprayed water body flows in a ring shape. Through the mode, the aeration equipment disclosed by the invention has multiple functions, can spray out magnetic water, small molecular water, micro-nano bubbles and ionic gas, can quickly increase oxygen, improve the biochemical rate of microbial degradation pollutants, can enable water in an aerobic tank to circularly flow, has no dead angle in oxygen increasing, is uniformly mixed, extracts water from the center of a microbial stuffing box by utilizing a water pump, and pushes the water through 45-degree windmill rotation, so that the water continuously enters into the stuffing to be fully contacted with microorganisms, and the contact oxidation of the organisms is more sufficient.

Description

Multifunctional aeration equipment

Technical Field

The invention relates to the technical field of aquaculture, in particular to multifunctional aeration equipment.

Background

The tail water refers to a polluted water body caused by residual baits and feces in the aquaculture process, and ammonia nitrogen, nitrite nitrogen, nitrate nitrogen, organic matters, phosphorus and harmful microorganisms can be generated in the aquaculture tail water, so that if the aquaculture tail water cannot be treated effectively in time, the environment of an aquaculture water area can be deteriorated, and outbreak diseases such as fishes, shrimps and crabs and the like and even large-area death can be caused, and the quality and the yield of aquaculture products are directly reduced and the environment is polluted.

For the treatment of tail water, the conventional mode is to discharge the tail water into an aerobic tank for chemical and physical conventional treatment, and in order to enable the treatment of the tail water in the aerobic tank to be accelerated, an aeration device is often arranged in the aerobic tank so as to degrade or precipitate the tail water in the aerobic tank by spraying bubbles through the aeration device, however, in the conventional mode, the function of the aeration device on the market is single, only single bubbles can be sprayed, and the high quality requirement of a user cannot be met.

Disclosure of Invention

(one) solving the technical problems

Aiming at the defects of the prior art, the invention provides multifunctional aeration equipment for solving the technical problems.

(II) technical scheme

In order to solve the technical problems, the invention provides the following technical scheme: a multifunctional aeration apparatus, comprising: the frame body is rectangular and comprises a rectangular body bottom surface, a first body side surface vertically arranged at a first edge of the body bottom surface, a second body side surface vertically arranged at a second edge of the body bottom surface, a third body side surface vertically arranged at a third edge of the body bottom surface and a fourth body side surface vertically arranged at a fourth edge of the body bottom surface, wherein rectangular accommodating cavities are formed in the body bottom surface, the first body side surface, the second body side surface, the third body side surface and the fourth body side surface; the microbial stuffing boxes are closely connected and arranged in the accommodating cavity; the first vertical pipe body is arranged at the joint of the side surface of the first body and the side surface of the second body along the vertical direction, a first water pump is arranged in the first vertical pipe body, and a first bending pipe positioned on the water surface is arranged at the top end of the first vertical pipe body in an extending manner; the second vertical pipe body is arranged at the center of the side surface of the second body along the vertical direction, a second water pump is arranged in the second vertical pipe body, and a second bending pipe positioned on the water surface is arranged at the top end of the second vertical pipe body in an extending manner; the third vertical pipe body is arranged at the joint of the side surface of the second body and the side surface of the third body along the vertical direction, a third water pump is arranged in the third vertical pipe body, and a third bending pipe positioned on the water surface is arranged at the top end of the third vertical pipe body in an extending manner; the fourth vertical pipe body is arranged at the joint of the side surface of the third body and the side surface of the fourth body along the vertical direction, a fourth water pump is arranged in the fourth vertical pipe body, and a fourth bending pipe is arranged at the top end of the fourth vertical pipe body in an extending mode; the fifth vertical pipe body is arranged at the center of the side surface of the fourth body along the vertical direction, a fifth water pump is arranged in the fifth vertical pipe body, and a fifth bending pipe positioned on the water surface is arranged at the top end of the fifth vertical pipe body in an extending mode; the sixth vertical pipe body is arranged at the joint of the side surface of the fourth body and the side surface of the first body along the vertical direction, a sixth water pump is arranged in the sixth vertical pipe body, and a sixth bending pipe positioned on the water surface is arranged at the top end of the sixth vertical pipe body in an extending manner; the magnetic force generator is positioned in the microorganism stuffing box of the accommodating cavity and is used for enabling a water body to enter a high-strength magnetic force cutting channel to be magnetized so as to form magnetic water, wherein the output ports of the magnetic force generator are connected with the other end of the first vertical pipe body and the other end of the sixth vertical pipe body, so that the magnetic water generated by the magnetic force generator is conveyed into the first vertical pipe body and the sixth vertical pipe body; the nanometer air pump is arranged at the top end of the frame body, the output ports of the nanometer air pump are connected with the second bending pipe and the fifth bending pipe, the water outlet end of the second bending pipe is provided with a first nanometer aerator, and the water outlet end of the fifth bending pipe is provided with a second nanometer aerator; the ion generator is used for generating ion gas and is arranged at the top end of the frame body, and an output port of the ion generator is arranged closely adjacent to the first nano aerator and/or the second nano aerator; the small molecule generator is used for generating small molecule water with strong permeability and is positioned in the microorganism stuffing box of the accommodating cavity, wherein the output port of the small molecule generator is connected with the other end of the third vertical pipe body and the other end of the fourth vertical pipe body, so that the small molecule water generated by the small molecule generator is conveyed into the third vertical pipe body and the fourth vertical pipe body; the bottom surface of the body, the side surface of the first body, the side surface of the second body, the side surface of the third body and the side surface of the fourth body are all composed of stainless steel wire meshes, and at least two of the first bending pipe, the second bending pipe, the third bending pipe, the fourth bending pipe, the fifth bending pipe and the sixth bending pipe are different in water outlet direction, so that the sprayed water body flows in a ring shape.

Further, the included angle between the first bending tube and the side surface of the first body is 45 degrees, the included angle between the second bending tube and the side surface of the first body is 45 degrees, the included angle between the third bending tube and the side surface of the third body is 45 degrees, the included angle between the fourth bending tube and the side surface of the fourth body is 45 degrees, the included angle between the fifth bending tube and the side surface of the fourth body is 45 degrees, and the included angle between the sixth bending tube and the side surface of the first body is 45 degrees.

Further, the output port of the nano air pump is connected with a first horizontal pipe body, one end of the first horizontal pipe body is connected with the second bending pipe, the other end of the second horizontal pipe body is connected with the fifth bending pipe, the output port of the ionizer is connected with a first extending pipe body, and one end of the first extending pipe body is closely adjacent to the first nano aerator and/or the second nano aerator;

further, the output port of the magnetic force generator is connected with a second horizontal pipe body in the microbial stuffing box of the accommodating cavity, one end of the second horizontal pipe body is connected with a third horizontal pipe body, one end of the second horizontal pipe body is connected with the middle part of the third horizontal pipe body, one end of the third horizontal pipe body is connected with the other end of the first vertical pipe body, and the other end of the third horizontal pipe body is connected with the other end of the sixth vertical pipe body.

Further, the output port of the small molecule generator is connected with a fourth horizontal pipe body in the microbial stuffing box of the accommodating cavity, one end of the fourth horizontal pipe body is connected with a fifth horizontal pipe body, one end of the fourth horizontal pipe body is connected with the middle part of the fifth horizontal pipe body, one end of the fifth horizontal pipe body is connected with the other end of the third vertical pipe body, and the other end of the fifth horizontal pipe body is connected with the other end of the fourth vertical pipe body.

Further, the other end of the second horizontal pipe body is connected with a first threaded hose, a first perforated pipe is arranged outside the first threaded hose, a first water blocking net is further arranged outside the first perforated pipe, the other end of the fourth horizontal pipe body is connected with a second threaded hose, a second perforated pipe is arranged outside the second threaded hose, and a second water blocking net is further arranged outside the second perforated pipe.

Further, the second bending tube is rotatably arranged on the second vertical tube, the fifth bending tube is rotatably arranged on the fifth vertical tube, the first horizontal tube is slidably arranged, a first control mechanism is arranged at the top end of the frame body and is connected with the first horizontal tube, and the first control mechanism drives the first horizontal tube to slide so as to synchronously drive the second bending tube and the fifth bending tube to rotate through the first horizontal tube.

Further, the top end of the first body side surface, the top end of the second body side surface, the top end of the third body side surface and the top end of the fourth body side surface are all provided with floating pieces which enable the aeration equipment to float in the aerobic tank along the length direction.

Further, the top of the plurality of microbial stuffing boxes is provided with a plant layer.

(III) beneficial effects

Compared with the prior art, the invention provides the multifunctional aeration equipment, which has the following beneficial effects:

1. the sprayed water body can enable the water body in the aerobic tank to circularly flow, oxygenation is free of dead angles, the water body is uniformly mixed, the water body is extracted from the center of the microbial stuffing box by a water pump, and the water body is pushed by windmill rotation at an angle of 45 degrees, so that the water body continuously enters the stuffing to be fully contacted with microorganisms, and the contact oxidation of the organisms is more sufficient;

2. the water inlet is provided with a perforated pipe, a water retaining net is added for easy water passing, and garbage cannot enter the center of the microbial stuffing box, so that the water can be pumped into the water pump for never blocking, and the biochemical rate of water quality treatment is effectively improved;

4. plant layers are planted on the top of the microbial stuffing box, so that the environment is more attractive and environment-friendly;

6. the multifunctional aeration is realized in the same aerobic tank, magnetic water, small molecular water, micro-nano bubbles and ionic gas can be sprayed out simultaneously, the magnetic water and the small molecular water have strong water permeability, so that the stay time of the micro-bubbles is increased by more than 15 times, the oxygenation is rapid, the strong permeability of the magnetic water and the small molecular water is beneficial to digestion of sludge and replacement of dredging, and the effect of improving the biochemical rate of degrading pollutants by microorganisms is achieved; the ionic gas enables the ionic gas to be dissolved in tail water, the ions generate charges and polarities to enable pollutants to be bonded and precipitated, and microorganisms are activated to enable the biochemical rate to be improved by more than 23%, so that the effects of effectively degrading the pollutants and recovering ecological chains are achieved; the residence time of micro-nano gas bubbles is long, the micro-bubbles are easier to dissolve in water, and ionic gas enters the water to generate charges so as to precipitate pollutants and activate microorganisms to improve the biochemical rate.

Drawings

FIG. 1 is a first schematic structural view of a multifunctional aeration apparatus according to the present invention;

fig. 2 is a second structural schematic view of the multifunctional aeration apparatus of the present invention;

fig. 3 is a first partial structural schematic view of the multifunctional aeration apparatus of the present invention;

FIG. 4 is a schematic view showing a second partial structure of the multifunctional aeration apparatus of the present invention;

fig. 5 is a schematic view showing a third partial structure of the multifunctional aeration apparatus of the present invention.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

As shown in fig. 1 to 5, the present invention provides a multifunctional aeration apparatus including a frame body 30, a plurality of microbial stuffing boxes 31, a first vertical pipe 11, a second vertical pipe 12, a third vertical pipe 13, a fourth vertical pipe 14, a fifth vertical pipe 15, a sixth vertical pipe 16, a magnetic force generator 17, a nano air pump 18, an ionizer 19, and a small molecule generator 20.

The frame body 30 is rectangular, wherein a plurality of supporting feet are arranged at the bottom of the frame body 30.

In the present embodiment, the frame body 30 includes a rectangular body bottom surface 300, a first body side surface 301 vertically disposed at a first edge of the body bottom surface 300, a second body side surface 302 vertically disposed at a second edge of the body bottom surface 300, a third body side surface 303 vertically disposed at a third edge of the body bottom surface 300, and a fourth body side surface 304 vertically disposed at a fourth edge of the body bottom surface 300. It should be appreciated that the first body side 301, the second body side 302, the third body side 303, and the fourth body side 304 are all rectangular in shape.

Preferably, the body bottom surface 300, the first body side surface 301, the second body side surface 302, the third body side surface 303, and the fourth body side surface 304 are formed with rectangular receiving cavities.

In the present embodiment, the body bottom surface 300, the first body side surface 301, the second body side surface 302, the third body side surface 303, and the fourth body side surface 304 are each composed of a stainless steel wire net, so that the body bottom surface 300, the first body side surface 301, the second body side surface 302, the third body side surface 303, and the fourth body side surface 304 each have a filtering function, and are capable of filtering large particulate impurities and the like. It should be understood that the frame body 30 is accommodated in an aerobic tank, the aerobic tank is used for accommodating tail water discharged from the fish pond, and the frame body 30 is formed by a stainless steel wire mesh, so that the frame body has a filtering effect, and the tail water in the aerobic tank enters the accommodating cavity of the frame body 30 after being filtered by the stainless steel wire mesh.

Further, in some examples, the top end of the first body side 301, the top end of the second body side 302, the top end of the third body side 303, and the top end of the fourth body side 304 are each provided with a float that floats the aeration apparatus in the aerobic tank along the length thereof. That is, the buoyancy of the body of water to the float is greater than the weight of the entire aeration apparatus. Specifically, the floating member is in a long strip shape, wherein the floating member includes a first floating member provided at the top end of the first body side 301, a second floating member provided at the top end of the second body side 302, a third floating member provided at the top end of the third body side 303, and a fourth floating member provided at the top end of the fourth body side 304, and the first floating member, the second floating member, the third floating member, and the fourth floating member are each in a long strip cylinder shape, and the length of the top end of the first body side 301 is equal to the length of the first floating member, the length of the top end of the second body side 302 is equal to the length of the second floating member, the length of the top end of the third body side 303 is equal to the length of the third floating member, and the length of the top end of the fourth body side 304 is equal to the length of the fourth floating member.

A plurality of microbial stuffing boxes 31 are closely connected and disposed within the receiving chamber. It should be understood that the plurality of microbial stuffing boxes 31 are filled in the housing cavity, i.e., the area formed by the plurality of microbial stuffing boxes 31 is equal to the area of the housing cavity, and the microbial stuffing boxes 31 are filled with microbial stuffing materials, which degrade and precipitate the tail water.

Preferably, the height of the microbial stuffing box 31 is equal to the depth of the receiving cavity.

In this embodiment, the top of the plurality of microbial stuffing boxes 31 is provided with a plant layer, which makes the environment more attractive and environmentally friendly.

The first vertical pipe 11 is disposed at a connection portion between the first body side 301 and the second body side 302 along a vertical direction, wherein the first water pump 110 is disposed in the first vertical pipe 11, and a first bending pipe 111 disposed on a water surface extends from a top end of the first vertical pipe 11. It should be understood that the bottom end of the first vertical pipe 11 is located in the housing cavity, so that the water in the housing cavity can be pumped into the first bending pipe 111 by the first water pump 110, so that the water sprayed from the first bending pipe 111 returns to the aerobic tank.

The second vertical pipe body 12 is arranged at the center of the side surface 302 of the second body along the vertical direction, wherein a second water pump 120 is arranged in the second vertical pipe body 12, and a second bending pipe 121 on the water surface is arranged at the top end of the second vertical pipe body 12 in an extending manner. It will be appreciated that the bottom end of the second vertical pipe body 12 is located within the receiving cavity so that the body of water within the receiving cavity can be pumped into the second bend pipe 121 by the second water pump 120 so that the body of water ejected from the second bend pipe 121 is returned to the aerobic tank.

The third vertical pipe 13 is disposed at the connection between the second body side 302 and the third body side 303 along the vertical direction, wherein a third water pump 130 is disposed in the third vertical pipe 13, and a third bending pipe 131 disposed on the water surface extends from the top end of the third vertical pipe 13. It should be understood that the bottom end of the third vertical pipe 13 is located in the accommodating cavity, so that the water in the accommodating cavity can be pumped into the third bending pipe 131 by the third water pump 130, so that the water sprayed from the third bending pipe 131 returns to the aerobic tank.

The fourth vertical pipe 14 is disposed at the connection between the third body side 303 and the fourth body side 304 along the vertical direction, wherein a fourth water pump 140 is disposed in the fourth vertical pipe 14, and a fourth bending pipe 141 disposed on the water surface extends from the top end of the fourth vertical pipe 14. It should be understood that the bottom end of the fourth vertical pipe 14 is located in the housing cavity, so that the water in the housing cavity can be pumped into the fourth bending pipe 141 by the fourth water pump 140, so that the water sprayed from the fourth bending pipe 141 returns to the aerobic tank.

The fifth vertical pipe 15 is disposed at the center of the side 304 of the fourth body along the vertical direction, wherein a fifth water pump 150 is disposed in the fifth vertical pipe 15, and a fifth bending pipe 151 is disposed at the top end of the fifth vertical pipe 15 in an extending manner. It should be understood that the bottom end of the fifth vertical pipe 15 is located in the accommodating cavity, so that the water in the accommodating cavity can be pumped into the fifth bending pipe 151 by the fifth water pump 150, so that the water sprayed from the fifth bending pipe 151 returns to the aerobic tank.

The sixth vertical pipe 16 is disposed at the connection between the fourth body side 304 and the first body side 301 along the vertical direction, wherein a sixth water pump 160 is disposed in the sixth vertical pipe 16, and a sixth bending pipe 161 is disposed at the top end of the sixth vertical pipe 16 in an extending manner. It will be appreciated that the bottom end of the sixth vertical pipe 16 is located within the receiving chamber such that the body of water within the receiving chamber can be pumped into the sixth curved pipe 161 by the sixth water pump 160 such that the body of water ejected from the sixth curved pipe 161 is returned to the aerobic tank.

The magnetic force generator 17 is positioned in the microbial stuffing box 31 of the accommodating cavity, wherein the magnetic force generator 17 is used for allowing a water body to enter a high-strength magnetic force cutting channel for magnetization so as to form magnetic water. It will be appreciated that the magnetic water produced by the magnetic force generator 17 is highly permeable, enabling the residence time of the microbubbles to be doubled.

In the present embodiment, the output ports of the magnetic force generator 17 are connected to the other end of the first vertical pipe 11 and the other end of the sixth vertical pipe 16, so that the magnetic water generated by the magnetic force generator 17 is transferred into the first vertical pipe 11 and the sixth vertical pipe 16.

Further, the output port of the magnetic force generator 17 is connected with a second horizontal tube 171 in the microbial stuffing box 31 of the accommodating cavity, one end of the second horizontal tube 171 is connected with a third horizontal tube 172, wherein one end of the second horizontal tube 171 is connected with the middle part of the third horizontal tube 172, one end of the third horizontal tube 172 is connected with the other end of the first vertical tube 11, and the other end of the third horizontal tube 172 is connected with the other end of the sixth vertical tube 16.

The nano air pump 18 is disposed at the top end of the frame body 30, wherein the output ports of the nano air pump 18 are connected with the second bending tube 121 and the fifth bending tube 151, the water outlet end of the second bending tube 121 is provided with the first nano aerator 181, and the water outlet end of the fifth bending tube 151 is provided with the second nano aerator 182, so that the water body sprayed from the second bending tube 121 and the fifth bending tube 151 has micro-nano bubbles for prolonging the residence time of oxygen.

Further, the output port of the nano air pump 18 is connected with a first horizontal tube 183, wherein one end of the first horizontal tube 183 is connected with the second bending tube 121, and the other end of the second horizontal tube 183 is connected with the fifth bending tube 151, so that the nano air output by the nano air pump 18 is conveyed into the second bending tube 121 and the fifth bending tube 151 through the first horizontal tube 183.

Further, a sixth horizontal pipe 184 is further disposed in the microbial stuffing box 31 for accommodating the cavity, one end of the sixth horizontal pipe 184 is connected to the other end of the second vertical pipe 12, the other end of the sixth horizontal pipe 184 is connected to the other end of the fifth vertical pipe 15, and a water inlet is disposed in the middle of the sixth horizontal pipe 184, so that water in the accommodating cavity enters the sixth horizontal pipe 184 from the water inlet.

The ion generator 19 is used for generating ion gas, wherein the ion generator 19 is disposed at the top end of the frame body 30, and the output port of the ion generator 19 is disposed closely adjacent to the first nano-aerator 181 and/or the second nano-aerator 182, so that the ion gas generated by the ion generator 19 is mixed with the water body ejected from the second bending tube 121 and the fifth bending tube 151. Preferably, the output ports of the ionizer 19 are provided in the second bend 121 and the fifth bend 151 so that the ion gas is more uniformly mixed with the water body.

Further, the output port of the ion generator 19 is connected to a first extension pipe 191, where one end of the first extension pipe 191 is disposed closely adjacent to the first nano-aerator 181 and/or the second nano-aerator 182, so that the ion gas generated by the ion generator 19 is mixed with the gas sprayed from the second bending pipe 121 and/or the fifth bending pipe 151.

The small molecule generator 20 is used for generating small molecule water with strong permeability, wherein the small molecule generator 20 is positioned in the microorganism stuffing box 31 of the accommodating cavity. It should be appreciated that the small molecule water produced by the small molecule generator 20 can allow the microbubbles to stay in the oxygen in the water for a longer period of time.

In this embodiment, the output ports of the small molecule generator 20 are connected to the other end of the third vertical pipe 13 and the other end of the fourth vertical pipe 14, so that the small molecule water generated by the small molecule generator 20 is transported into the third vertical pipe 13 and the fourth vertical pipe 14.

Further, the output port of the small molecule generator 20 is connected with a fourth horizontal pipe 201 in the microbial stuffing box 31 of the accommodating cavity, one end of the fourth horizontal pipe 201 is connected with a fifth horizontal pipe 202, wherein one end of the fourth horizontal pipe 201 is connected with the middle part of the fifth horizontal pipe 202, one end of the fifth horizontal pipe 202 is connected with the other end of the third vertical pipe 13, and the other end of the fifth horizontal pipe 202 is connected with the other end of the fourth vertical pipe 14.

It should be understood that the aeration device of this embodiment can spray out magnetic water, small molecular water, micro-nano bubbles and ionic gas at the same time, and the magnetic water and the small molecular water have strong water permeability, so that the residence time of oxygen in the micro-bubbles is increased by more than 15 times, the oxygenation is rapid, and the strong permeability of the magnetic water and the small molecular water is beneficial to digestion of sludge and replacement of dredging, so as to achieve the effect of improving the biochemical rate of degrading pollutants by microorganisms; the ionic gas enables the ionic gas to be dissolved in tail water, the ions generate charges and polarities to enable pollutants to be bonded and precipitated, and microorganisms are activated to enable the biochemical rate to be improved by more than 23%, so that the effects of effectively degrading the pollutants and recovering ecological chains are achieved; the micro-nano gas bubbles can also enable the oxygen to stay for a long time, the micro-bubbles are easier to dissolve in water, and the ionic gas enters the water to generate charges so as to enable pollutants to precipitate and activate microorganisms to improve the biochemical rate.

In the present embodiment, at least two of the first bending tube 111, the second bending tube 121, the third bending tube 131, the fourth bending tube 141, the fifth bending tube 151, and the sixth bending tube 161 have different water outlet directions, so that the ejected water body flows in a ring shape. That is, the water spraying directions of the first, second, third, fourth, fifth and sixth bending pipes 111, 121, 131, 141, 151 and 161 are set clockwise around the aeration apparatus so that the sprayed water circulates, the aeration is free from dead angles, and the water is uniformly mixed.

Preferably, the angle between the first bending tube 111 and the first body side 301 is 45 degrees, the angle between the second bending tube 121 and the first body side 301 is 45 degrees, the angle between the third bending tube 131 and the third body side 303 is 45 degrees, the angle between the fourth bending tube 141 and the fourth body side 304 is 45 degrees, the angle between the fifth bending tube 151 and the fourth body side 304 is 45 degrees, and the angle between the sixth bending tube 161 and the first body side 301 is 45 degrees.

Further, the other end of the second horizontal tube 171 is connected with a first threaded tube, a first perforated tube is arranged outside the first threaded tube, a first water retaining net 1711 is arranged outside the first perforated tube, further, the other end of the fourth horizontal tube 201 is connected with a second threaded tube, a second perforated tube is arranged outside the second threaded tube, and a second water retaining net 2011 is arranged outside the second perforated tube. Further, a third perforated pipe is arranged outside the water inlet hole in the middle of the sixth horizontal pipe 184, and a third water blocking net 1841 is arranged outside the third perforated pipe. It should be understood that the water bodies ejected from the first bending tube 111, the second bending tube 121, the third bending tube 131, the fourth bending tube 141, the fifth bending tube 151 and the sixth bending tube 161 of the present embodiment are all water bodies extracted from the filler center of the microbial stuffing box 31 after being filtered by the stainless steel wire mesh and then treated by the microbial filler and finally filtered by the water blocking net and the perforated tube.

In addition, in some embodiments, the second bending pipe 121 is rotatably disposed on the second vertical pipe body 12, and the fifth bending pipe 151 is rotatably disposed on the fifth vertical pipe body 15, so that the water spray direction of the second bending pipe 121 and the fifth bending pipe 151 can be controlled as needed. Further, the first horizontal tube 183 is slidably disposed, and since the two ends of the first horizontal tube 183 are connected to the second bending tube 121 and the fifth bending tube 151, the second bending tube 121 and the fifth bending tube 151 are synchronously driven to rotate when the first horizontal tube 183 slides.

Further, a first control mechanism is disposed at the top end of the frame body 30, wherein the first control mechanism is connected with the first horizontal tube 183, so as to drive the first horizontal tube 183 to slide through the first control mechanism, so as to synchronously drive the second bending tube 121 and the fifth bending tube 151 to rotate through the first horizontal tube 183. Specifically, the first control mechanism is a first telescopic cylinder, and the housing of the first telescopic cylinder is disposed at the top end of the frame body 30, and the telescopic rod of the first telescopic cylinder is connected with the first horizontal tube 183, so that the telescopic rod of the first telescopic cylinder drives the first horizontal tube 183 to slide, and preferably, the telescopic direction of the telescopic rod of the first telescopic cylinder is parallel to or in the same straight line with the sliding direction of the first horizontal tube 183.

Of course, in other embodiments, in order to better control the water spray direction, not only the second bending pipe 121 and the fifth bending pipe 151 are rotatably disposed, but also the first bending pipe 111 is rotatably disposed on the first vertical pipe body 11, the third bending pipe 131 is rotatably disposed on the third vertical pipe body 13, the fourth bending pipe 141 is rotatably disposed on the fourth vertical pipe body 141, and the sixth bending pipe 161 is rotatably disposed on the sixth vertical pipe body 16, so that the water spray directions of the first bending pipe 111, the second bending pipe 121, the third bending pipe 131, the fourth bending pipe 141, the fifth bending pipe 151, and the sixth bending pipe 161 can be controlled as needed.

Further, a second control mechanism is further arranged at the top end of the frame body 30, and the second control mechanism is a second telescopic cylinder, wherein a first driving rod is fixedly connected with a telescopic rod of the second telescopic cylinder, so that the first driving rod is driven to slide through the second telescopic cylinder. Further, one end of the first driving rod is connected with the first bending tube 111, and the other end of the first driving rod is connected with the sixth bending tube 161, so that when the first driving rod slides, the first bending tube 111 and the sixth bending tube 161 can be synchronously driven to rotate by the first driving rod, and the water spraying direction of the first bending tube 111 and the sixth bending tube 161 can be adjusted.

Further, a third control mechanism is further arranged at the top end of the frame body 30, and the third control mechanism is a third telescopic cylinder, wherein a second driving rod is fixedly connected with a telescopic rod of the third telescopic cylinder, so that the second driving rod is driven to slide through the third telescopic cylinder. Further, one end of the second driving rod is connected with the third bending tube 131, and the other end of the second driving rod is connected with the fourth bending tube 141, so that when the second driving rod slides, the second driving rod can synchronously drive the third bending tube 131 and the fourth bending tube 141 to rotate, so as to adjust the water spraying direction of the third bending tube 31 and the fourth bending tube 141.

In addition, for better flexible control, the top end of the frame body 30 is respectively provided with six control units, and the six control units are independently connected with the first bending tube 111, the second bending tube 121, the third bending tube 131, the fourth bending tube 141, the fifth bending tube 151 and the sixth bending tube 161, so that the first bending tube 111, the second bending tube 121, the third bending tube 131, the fourth bending tube 141, the fifth bending tube 151 and the sixth bending tube 161 are independently controlled to rotate by the six control units, and the control units can be driving motors, the rotating shafts of the driving motors are provided with first gears, and second gears meshed with the first gears are arranged outside the bending tubes, so that the driving motors drive the bending tubes to rotate when rotating. Specifically, when the aeration apparatus needs to be controlled to move in the first direction in the aerobic tank, the six control units uniformly control the water spraying directions of the first bending pipe 111, the second bending pipe 121, the third bending pipe 131, the fourth bending pipe 141, the fifth bending pipe 151 and the sixth bending pipe 161 to be the same direction, so that the sprayed water body is consistent to push the aeration apparatus to move in the first direction, and when the aeration apparatus is detected to move to the edge of the aerobic tank, the six control units uniformly control the first bending pipe 111, the second bending pipe 121, the third bending pipe 131, the fourth bending pipe 141, the fifth bending pipe 151 and the sixth bending pipe 161 to be reversed, so that the sprayed water body is opposite to the first direction, so that the aeration apparatus is pushed again to move in the second direction, wherein the first direction is opposite to the second direction.

It should be noted that the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising one … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element.

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

Claims

1. A multifunctional aeration apparatus, comprising:

the frame body is rectangular and comprises a rectangular body bottom surface, a first body side surface vertically arranged at a first edge of the body bottom surface, a second body side surface vertically arranged at a second edge of the body bottom surface, a third body side surface vertically arranged at a third edge of the body bottom surface and a fourth body side surface vertically arranged at a fourth edge of the body bottom surface, wherein rectangular accommodating cavities are formed in the body bottom surface, the first body side surface, the second body side surface, the third body side surface and the fourth body side surface;

the microbial stuffing boxes are closely connected and arranged in the accommodating cavity;

the first vertical pipe body is arranged at the joint of the side surface of the first body and the side surface of the second body along the vertical direction, a first water pump is arranged in the first vertical pipe body, and a first bending pipe positioned on the water surface is arranged at the top end of the first vertical pipe body in an extending manner;

the second vertical pipe body is arranged at the center of the side surface of the second body along the vertical direction, a second water pump is arranged in the second vertical pipe body, and a second bending pipe positioned on the water surface is arranged at the top end of the second vertical pipe body in an extending manner;

the third vertical pipe body is arranged at the joint of the side surface of the second body and the side surface of the third body along the vertical direction, a third water pump is arranged in the third vertical pipe body, and a third bending pipe positioned on the water surface is arranged at the top end of the third vertical pipe body in an extending manner;

the fourth vertical pipe body is arranged at the joint of the side surface of the third body and the side surface of the fourth body along the vertical direction, a fourth water pump is arranged in the fourth vertical pipe body, and a fourth bending pipe is arranged at the top end of the fourth vertical pipe body in an extending mode;

the fifth vertical pipe body is arranged at the center of the side surface of the fourth body along the vertical direction, a fifth water pump is arranged in the fifth vertical pipe body, and a fifth bending pipe positioned on the water surface is arranged at the top end of the fifth vertical pipe body in an extending mode;

the sixth vertical pipe body is arranged at the joint of the side surface of the fourth body and the side surface of the first body along the vertical direction, a sixth water pump is arranged in the sixth vertical pipe body, and a sixth bending pipe positioned on the water surface is arranged at the top end of the sixth vertical pipe body in an extending manner;

the magnetic force generator is positioned in the microorganism stuffing box of the accommodating cavity and is used for enabling a water body to enter a high-strength magnetic force cutting channel to be magnetized so as to form magnetic water, wherein the output ports of the magnetic force generator are connected with the other end of the first vertical pipe body and the other end of the sixth vertical pipe body, so that the magnetic water generated by the magnetic force generator is conveyed into the first vertical pipe body and the sixth vertical pipe body;

the nanometer air pump is arranged at the top end of the frame body, the output ports of the nanometer air pump are connected with the second bending pipe and the fifth bending pipe, the water outlet end of the second bending pipe is provided with a first nanometer aerator, and the water outlet end of the fifth bending pipe is provided with a second nanometer aerator;

the ion generator is used for generating ion gas and is arranged at the top end of the frame body, and an output port of the ion generator is arranged closely adjacent to the first nano aerator and/or the second nano aerator;

the small molecule generator is used for generating small molecule water with strong permeability and is positioned in the microorganism stuffing box of the accommodating cavity, wherein the output port of the small molecule generator is connected with the other end of the third vertical pipe body and the other end of the fourth vertical pipe body, so that the small molecule water generated by the small molecule generator is conveyed into the third vertical pipe body and the fourth vertical pipe body;

the bottom surface of the body, the side surface of the first body, the side surface of the second body, the side surface of the third body and the side surface of the fourth body are all composed of stainless steel wire meshes, and at least two of the first bending pipe, the second bending pipe, the third bending pipe, the fourth bending pipe, the fifth bending pipe and the sixth bending pipe are different in water outlet direction, so that the sprayed water body flows in a ring shape.

2. A multifunctional aeration device according to claim 1, wherein the angle between the first bending tube and the first body side is 45 degrees, the angle between the second bending tube and the first body side is 45 degrees, the angle between the third bending tube and the third body side is 45 degrees, the angle between the fourth bending tube and the fourth body side is 45 degrees, the angle between the fifth bending tube and the fourth body side is 45 degrees, and the angle between the sixth bending tube and the first body side is 45 degrees.

3. A multifunctional aeration device according to claim 1, wherein the output port of the nano air pump is connected with a first horizontal pipe body, wherein one end of the first horizontal pipe body is connected with the second bending pipe, the other end of the second horizontal pipe body is connected with the fifth bending pipe, and the output port of the ionizer is connected with a first extension pipe body, wherein one end of the first extension pipe body is arranged closely adjacent to the first nano aerator and/or the second nano aerator.

4. A multi-functional aeration apparatus according to claim 3, wherein the output port of the magnetic force generator is connected with a second horizontal pipe body in the microbial stuffing box of the accommodating cavity, one end of the second horizontal pipe body is connected with a third horizontal pipe body, one end of the second horizontal pipe body is connected with the middle part of the third horizontal pipe body, one end of the third horizontal pipe body is connected with the other end of the first vertical pipe body, and the other end of the third horizontal pipe body is connected with the other end of the sixth vertical pipe body.

5. A multi-functional aeration device according to claim 4, wherein the output port of the small molecule generator is connected with a fourth horizontal pipe body in the microbial stuffing box of the accommodating cavity, one end of the fourth horizontal pipe body is connected with a fifth horizontal pipe body, one end of the fourth horizontal pipe body is connected with the middle part of the fifth horizontal pipe body, one end of the fifth horizontal pipe body is connected with the other end of the third vertical pipe body, and the other end of the fifth horizontal pipe body is connected with the other end of the fourth vertical pipe body.

6. A multi-functional aeration device according to claim 5, wherein the other end of the second horizontal tube is connected with a first threaded hose, a first perforated tube is arranged outside the first threaded hose, a first water blocking net is arranged outside the first perforated tube, the other end of the fourth horizontal tube is connected with a second threaded hose, a second perforated tube is arranged outside the second threaded hose, and a second water blocking net is arranged outside the second perforated tube.

7. A multi-functional aeration device according to claim 3, wherein the second bending tube is rotatably disposed on the second vertical tube, the fifth bending tube is rotatably disposed on the fifth vertical tube, wherein the first horizontal tube is slidably disposed, a first control mechanism is disposed at a top end of the frame body, and the first control mechanism is connected to the first horizontal tube, so that the first horizontal tube is slidably driven by the first control mechanism, so that the second bending tube and the fifth bending tube are synchronously driven to rotate by the first horizontal tube.

8. A multifunctional aeration device according to claim 1, wherein the top end of the first body side, the top end of the second body side, the top end of the third body side and the top end of the fourth body side are each provided with a float member for floating the aeration device in an aerobic tank along the length direction thereof.

9. A multi-function aeration device according to claim 1, wherein the tops of the plurality of microbial stuffing boxes are provided with a plant layer.