CN220099012U - Microorganism in-situ repair underwater expansion culture system - Google Patents

Abstract

The utility model provides an in-situ microorganism repairing underwater expanding culture system, which comprises an expanding culture box and a microorganism culture body; an electric control mechanism is arranged above the bottom surface of the expanding culture box, and an impurity sucking mechanism is arranged below the bottom surface; a drainage mechanism is arranged at one side of the expansion culture box; the water stirring assembly can stir up impurities in water, the impurities are screened and crushed by the screening assembly, and are sucked by the water absorbing assembly and discharged into the expanding culture box, so that solid pollutants in a water body are reduced, the solid pollutants are supplied to microorganisms to absorb nutrients, expanding culture of the microorganisms is promoted, and cost and labor cost are reduced; meanwhile, the drainage mechanism is arranged in the culture expansion box, so that microorganisms can be regularly turned on and turned off to be discharged into the polluted water body, and the workload of manually putting strain liquid is saved.

Description

Microorganism in-situ repair underwater expansion culture system

Technical Field

The utility model relates to the technical field of water body restoration, in particular to an underwater expansion culture system for in-situ restoration of microorganisms.

Background

The microorganism in-situ water body restoration technology utilizes specific microorganisms to absorb, convert, remove or degrade pollutants such as nitrogen and phosphorus in water body, realizes in-situ water body restoration, and has the advantages of low investment, good treatment effect, small side effect and the like.

The existing microorganism expanding culture device for in-situ water body restoration is generally provided with only one expanding culture box for culturing microorganisms, and when the device is used, strains are required to be added into the expanding culture box periodically, and after expanding culture, liquid containing the strains is poured into polluted water body, so that the strain cost and the manual operation cost are high; meanwhile, the simple microorganism culture expansion tank does not have other in-situ water body restoration functions, for example, solid pollutants such as silt, putrefying plant leaves and the like in the water body cannot be treated at the same time, and the in-situ water body restoration capability is limited.

Therefore, an improvement on the existing microorganism culture device is needed to reduce the use cost and improve the in-situ water restoration capacity.

Disclosure of Invention

One problem to be solved by the utility model is: the microorganism in-situ repair underwater propagation system is low in cost of adding strains and low in manual operation cost;

another problem to be solved by the present utility model is: the microorganism in-situ remediation underwater propagation system can simultaneously treat solid pollutants in a water body.

The utility model solves the problems by adopting the following technical scheme: an underwater microorganism in-situ repair expanding culture system comprises an expanding culture box floating on the water surface and a microorganism culture body arranged in the expanding culture box; an electric control mechanism is arranged above the bottom surface of the expanding culture box, and an impurity sucking mechanism controlled by the electric control mechanism is arranged below the bottom surface and used for sucking impurities in water to expand culture microorganisms; and one side of the expansion culture box is provided with a drainage mechanism controlled by the electric control mechanism and used for draining water with microorganisms in the expansion culture box.

Compared with the prior art, the utility model has the advantages that the impurity sucking mechanism controlled by the electric control mechanism is arranged in the expanding culture box, the water stirring assembly stirs up impurities in water, the impurities are screened and smashed by the screening assembly, the impurities with larger particles or the impurities which cannot be smashed are screened out, the impurities with smaller particles or the impurities which can be smashed are sucked by the water sucking assembly and discharged into the expanding culture box, so that solid pollutants in water are reduced, in-situ restoration is carried out, the solid pollutants are supplied for microorganisms to absorb nutrients, expanding culture of microorganisms is promoted, the adding amount of strains is reduced, and the workload of manually adding the strains is also saved; meanwhile, the water draining mechanism controlled by the electric control mechanism is arranged in the expansion culture box, so that the expansion culture box can be periodically opened and closed, and the microorganisms after expansion culture are discharged into the polluted water body along the water flow in the expansion culture box, so that the workload of manually putting strain liquid is saved.

Preferably, the impurity sucking mechanism comprises a connecting pipe; the upper end of the connecting pipe is communicated with the expanding culture box; a water pumping channel is arranged in the connecting pipe and used for conveying water containing impurities to the expanding culture box; the upper end of the water pumping channel is provided with a multi-way joint; the multi-way joint is provided with a hose; the hose orifice can be detachably connected with a filter bag for collecting impurities absorbed by the water absorbing component.

Preferably, the electric control mechanism comprises a solar panel, a control module integrally arranged below the solar panel and a mounting column; the mounting column is fixedly connected above the connecting pipe; the solar cell panel is arranged above the mounting column to collect solar energy.

Preferably, four hoses are arranged on the multi-way joint; the four hoses penetrate out of the side wall of the mounting column at an angle of 90 degrees, so that the filter bags are uniformly distributed in the expanding culture box, and the microbial culture bodies distributed in the expanding culture box can uniformly draw nutrients in impurities.

Preferably, the drainage mechanism comprises a drainage pipe; the drain pipe penetrates through the side wall arranged at one side of the expanding culture box; the drain pipe is provided with a switch valve, and the switch valve is connected with the control module through a wire so as to control the periodic switch of the switch valve.

Preferably, one side of the lower end of the connecting pipe is provided with a water stirring component, and the other side of the lower end is provided with a water absorbing component; a screening component is communicated below the water absorption component; the opening of the screening component faces the water stirring component, so that impurities stirred by the water stirring component are sucked by the suction mechanism.

Preferably, the screening assembly comprises a screening cavity and a water absorbing cavity which are communicated with each other; when the water absorbing assembly rotates, negative pressure is generated in the water absorbing cavity; the opening of the screening cavity faces the water stirring assembly, and impurities stirred by the water stirring assembly are sucked through negative pressure; two relatively rotating crushing rollers are arranged in the screening cavity; the two stirring rollers are synchronously driven by the water stirring assembly; the screening cavity below be equipped with the screening mouth for the impurity that the discharge can't pass through two stirring garrulous rollers.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

FIG. 2 is a top view of the present utility model;

FIG. 3 is a cross-sectional view of the structure of the expansion tank;

fig. 4 is a cross-sectional view of the lower end of the impurity extraction mechanism;

fig. 5 is a schematic view of a screen assembly.

In the figure, a culture expansion box 1, a microorganism culture body 2, an impurity sucking mechanism 3, an electric control mechanism 4 and a drainage mechanism 5; a connecting pipe 31, a water stirring assembly 32, a water absorbing assembly 33 and a screening assembly 34; a solar panel 41, a control module 42, and a mounting post 43; a drain pipe 51 and a switch valve 52; pumping channel 311, multi-way fitting 312, hose 313, filter bag 314; screening chamber 341, suction chamber 342, crushing roller 343, screening opening 344.

Detailed Description

Embodiments of the present utility model are further described below with reference to the accompanying drawings.

Before use, a control program is required to be introduced into the control module 42, and the control program is used for controlling the module 42 to cooperatively operate the solar panel 41, the water stirring assembly 32, the water absorbing assembly 33 and the switch valve 52 so as to realize periodic extraction, stirring and filtration of impurity pollutants in water, and the switch valve 52 is periodically opened to drain water containing bacterial liquid into a water body; for example, the impurity sucking mechanism is operated for 3 hours every day to supplement impurities and a water source for the expanding culture box 1, nutrients are added for microorganism expansion culture, the on-off valve 52 is opened once every two days, and the microorganisms expanded in the expanding culture box 1 are discharged into the water body along with water flow, so that in-situ water body restoration is realized.

Before use, the utility model also needs to put a plurality of microorganism culture bodies 2 into the expansion culture box 1.

Referring to fig. 1, the in-situ microorganism repairing underwater propagation system of the present utility model comprises a propagation box 1 floating on the water surface, and a microorganism culture body 2 arranged in the propagation box 1; an electric control mechanism 4 is arranged above the bottom surface of the expanding culture box 1, and an impurity sucking mechanism 3 controlled by the electric control mechanism 4 is arranged below the bottom surface and used for sucking impurities in water to expand culture microorganisms; one side of the culture expansion tank 1 is provided with a water draining mechanism 5 controlled by an electric control mechanism 4 for draining the water with microorganisms in the culture expansion tank 1.

When the device is used, the impurity sucking mechanism 3 controlled by the electric control mechanism 4 is arranged in the expanding culture box 1, wherein the water stirring component 32 stirs up impurities in water, the impurities are screened and smashed by the screening component 34, the impurities with larger particles or the impurities which cannot be smashed are screened out, the impurities with smaller particles or the impurities which can be smashed are sucked and sucked by the water sucking component 33, and are discharged into the expanding culture box 1, so that solid pollutants in water are reduced, in-situ restoration is carried out, the solid pollutants are supplied to microorganisms for absorbing nutrients, expanding culture of microorganisms is promoted, the adding amount of strains is reduced, and the workload of manually adding the strains is also saved; meanwhile, the water draining mechanism controlled by the electric control mechanism 4 is arranged in the expansion culture box 1, so that the water draining mechanism can be periodically turned on and turned off, and the microorganisms after expansion culture are drained into the polluted water body along the water flow in the expansion culture box 4, so that the workload of manually putting strain liquid is saved.

Referring to fig. 3, the impurity sucking mechanism 3 includes a connection pipe 31; the upper end of the connecting pipe 31 is communicated with the expanding culture box 1; a water pumping channel 311 is arranged in the connecting pipe 31 and is used for conveying water containing impurities to the expanding culture box 1; the upper end of the water pumping channel 311 is provided with a multi-way joint 312; the multi-way joint 312 is provided with a hose 313; the mouth of the hose 313 is detachably connected with a filter bag 314 for collecting impurities sucked by the water suction assembly 33, the impurities are filtered by the filter bag 314 and are concentrated and piled in the filter bag 314, the filtered clear water is left in the culture expansion tank 1 for expanding and cultivating microorganisms, and the microorganisms in the microorganism culture body 2 can absorb the nutrients of the impurities in the filter bag 314 because the filter bag 314 is soaked in the culture expansion tank 1; after a period of use, when the filter bag 314 is filled with foreign substances, the user can detach the filter bag 314 from the nozzle of the hose 313, uniformly treat the foreign substances accumulated inside, and attach a new filter bag 314 to the nozzle of the hose 313.

Referring to fig. 3, the electric control mechanism 4 includes a solar panel 41, a control module 42 integrally disposed under the solar panel 41, and a mounting post 43; the mounting post 43 is fixedly connected above the connection pipe 31; in use, the solar panel 41 is positioned above the mounting posts 43 at a location above the height of the incubator 1 to facilitate collection of solar energy and power the control module 42, the water agitation assembly 32, the water suction assembly 33, and the screen assembly 34.

With continued reference to fig. 2 and 3, the multi-way connector 312 is provided with four hoses 313; four hoses 313 are mutually 90 degrees and pass out from the side wall of the mounting column 43 so as to ensure that the filter bags 314 are uniformly distributed in the expanding culture box 1, so that microorganism culture bodies 2 distributed in the expanding culture box 1 can uniformly draw nutrients of impurities, the four hoses 313 can be connected with the 4 filter bags 314, and the impurity bearing capacity of the expanding culture box 1 is increased, thereby avoiding frequent manual replacement of the filter bags 314.

Referring further to fig. 2 and 3, the drainage mechanism 5 includes a drain pipe 51; the drain pipe 51 penetrates through the side wall arranged at one side of the culture expansion tank 1; the drain pipe 51 is provided with a switch valve 52, and the switch valve 52 is connected with the control module 42 through a wire; in use, the control module 42 periodically controls the on-off valve 52 to open, for example, once every two days for 10 minutes and to close for the rest of the time, and when opened, the microorganisms spread in the spreading box 1 are discharged from the drain pipe 51 into the contaminated water body along the water flow.

Referring to fig. 4, a water stirring assembly 32 is disposed at one side of the lower end of the connecting tube 31, and a water absorbing assembly 33 is disposed at the other side of the lower end; a screening component 34 is communicated below the water absorbing component 33; the openings of the screening assemblies 34 face the water stirring assemblies 32, so that impurities stirred up by the water stirring assemblies 32 are sucked by the suction mechanisms 3, and the effect of purifying solid pollutants in the water body is achieved.

With continued reference to fig. 4 and 5, screen assembly 34 includes a screen chamber 341 and a suction chamber 342 in communication with one another; the suction assembly 33 generates a negative pressure in the suction chamber 342 when rotated; the opening of the sieving chamber 341 faces the water stirring assembly 32, and impurities stirred up by the water stirring assembly 32 are sucked in through negative pressure; two relatively rotating crushing rollers 343 are arranged in the screening cavity 341; the two stirring rollers 343 are synchronously driven by the water stirring assembly 32; a screen opening 344 is provided below the screening chamber 341 for discharging impurities that cannot pass through the two crushing rollers 343.

The foregoing is illustrative of the preferred embodiments of the present utility model and is not to be construed as limiting the claims. The present utility model is not limited to the above embodiments, and the specific structure thereof is allowed to vary. All changes which come within the meaning and range of equivalency of the claims are to be embraced within their scope.

Claims (7)

1. An underwater microorganism in-situ repair and culture expanding system comprises a culture expanding box (1) floating on the water surface and a microorganism culture body (2) arranged in the culture expanding box (1); the method is characterized in that: an electric control mechanism (4) is arranged above the bottom surface of the expanding culture box (1), and an impurity sucking mechanism (3) controlled by the electric control mechanism (4) is arranged below the bottom surface and used for sucking impurities in water to expand culture microorganisms; one side of the expansion culture box (1) is provided with a drainage mechanism (5) controlled by the electric control mechanism (4) for draining water with microorganisms in the expansion culture box (1).

2. The microbial in situ remediation underwater propagation system of claim 1 wherein: the impurity sucking mechanism (3) comprises a connecting pipe (31); the upper end of the connecting pipe (31) is communicated with the expanding culture box (1); a water pumping channel (311) is arranged in the connecting pipe (31) and is used for conveying water containing impurities to the expanding culture box (1); the upper end of the water pumping channel (311) is provided with a multi-way joint (312); a hose (313) is arranged on the multi-way joint (312); the mouth of the hose (313) is detachably connected with a filter bag (314) for collecting impurities sucked by the water suction component (33).

3. The microbial in situ remediation underwater propagation system of claim 2 wherein: the electric control mechanism (4) comprises a solar panel (41), a control module (42) integrally arranged below the solar panel (41), and a mounting column (43); the mounting column (43) is fixedly connected above the connecting pipe (31); the solar panel (41) is arranged above the mounting column (43) to collect solar energy.

4. A microbial in situ remediation underwater propagation system according to claim 3 wherein: four hoses (313) are arranged on the multi-way joint (312); the four hoses (313) penetrate out of the side wall of the mounting column (43) at 90 degrees to ensure that the filter bags (314) are uniformly distributed in the expanding culture box (1).

5. A microbial in situ remediation underwater propagation system according to claim 3 wherein: the drainage mechanism (5) comprises a drainage pipe (51); the drain pipe (51) is communicated with the side wall arranged at one side of the expanding culture box (1); the drain pipe (51) is provided with a switch valve (52), and the switch valve (52) is connected with the control module (42) through a lead so as to control the periodic switching of the switch valve (52).

6. The microbial in situ remediation underwater propagation system of claim 2 wherein: one side of the lower end of the connecting pipe (31) is provided with a water stirring component (32), and the other side of the lower end is provided with a water absorbing component (33); a screening component (34) is communicated below the water absorbing component (33); the opening of the screening component (34) faces the water stirring component (32) so that impurities stirred up by the water stirring component (32) are sucked by the suction mechanism (3).

7. The microbial in situ remediation underwater propagation system of claim 6 wherein: the screening component (34) comprises a screening cavity (341) and a water absorbing cavity (342) which are communicated with each other; the water absorbing component (33) generates negative pressure in the water absorbing cavity (342) when rotating; the opening of the sieving cavity (341) faces the water stirring assembly (32), and impurities stirred up by the water stirring assembly (32) are sucked in through negative pressure; two relatively rotating stirring rollers (343) are arranged in the screening cavity (341); the two stirring rollers (343) are synchronously driven by the water stirring assembly (32); a screening opening (344) is arranged below the screening cavity (341) and is used for discharging impurities which cannot pass through the two crushing rollers (343).