CN113529674A - Adjustable side channel for treating algae pollution of water body - Google Patents

Abstract

The invention provides an adjustable bypass for treating algae pollution in a water body, which comprises a diversion purification wall and a monitoring control frame; the guide purification walls are arranged oppositely, and a monitoring control frame is connected between the guide purification walls. According to the invention, the guide purification wall and the monitoring control frame which are hollow inside are arranged, the monitoring control frame is utilized to monitor the pollution condition in the water body, the polluted water is guided into the guide purification wall for separation and purification, and then is discharged into the water system again, so that the purification cycle of the water quality is completed; the diversion channel is arranged in the diversion purification wall and comprises the sieve plate, the first drainage pipe and the second drainage pipe, so that the polluted water surface layer can be subjected to classified screening purification by utilizing structures such as sieve pores on the surfaces of the sieve plate, the first drainage pipe and the second drainage pipe, and the purification efficiency is improved; through set up the blowdown axle in two blowdown pipes, utilize the auger delivery axle structure, can discharge pulpiness algae pollutant smoothly to the preliminary treatment groove in carry out processing such as fermentation, stack retting, realize the cyclic utilization of resource.

Description

Adjustable side channel for treating algae pollution of water body

Technical Field

The invention relates to an adjustable bypass channel for water body algae pollution treatment, and belongs to the technical field of water environment treatment.

Background

In recent years, with the increase of industrial level, discharge of sewage and the like in industrial production process is increasing, and if the sewage is directly discharged to a water system without treatment, the water body is eutrophicated, and algae in the water is likely to flood.

In inland water systems, the more common algae pollution of water bodies is blue algae pollution, which seriously affects fresh water and drinking water resources and even causes shortage; therefore, people should increase the efforts to treat the situation, and one of the means of treatment is to purify the polluted water body. The existing algae pollutant treatment method is usually chemical agent or manual salvage, which not only consumes a large amount of manpower and material resources, but also can cause secondary pollution to water; therefore, in order to avoid the situation, a water body purification treatment scheme different from a manual salvage and chemical agent decontamination mode is designed, and a method of trimming a bypass channel is utilized to purify and treat the polluted water body.

Disclosure of Invention

In order to solve the technical problems, the invention provides an adjustable bypass for water body algae pollution treatment, which solves the problems that the existing chemical agents and manual fishing methods waste manpower and material resources and easily cause secondary pollution to water bodies.

The invention is realized by the following technical scheme.

The invention provides an adjustable bypass for treating algae pollution in a water body, which comprises a diversion purification wall and a monitoring control frame; the guide purification walls are oppositely arranged, and a monitoring control frame is connected between the guide purification walls; the inner side wall of the flow guide purification wall is provided with a water inlet and a water outlet, and the water inlet and the water outlet are bolted with an isolation screen plate; a diversion channel is arranged in the diversion purification wall, and two ends of the diversion channel are respectively communicated with the water inlet and the water outlet; a sieve plate is arranged in the flow guide channel, the sieve plate divides the flow guide channel into a primary chamber and a secondary chamber, a transmission cavity is arranged on one side of the primary chamber, a sewage discharge motor is arranged on one side of the transmission cavity, and a pretreatment groove is arranged on one side of the secondary chamber; a first sewage discharge pipe and a second sewage discharge pipe are mutually communicated and poured in the secondary chamber, a first sewage discharge shaft is connected to the inner wall of the first sewage discharge pipe in a bolted mode, and a second sewage discharge shaft is connected to the inner wall of the second sewage discharge pipe in a bolted mode; one ends of the first sewage discharging shaft and the second sewage discharging shaft extend into the transmission cavity, and the second sewage discharging shaft is bolted with an output shaft of the sewage discharging motor; the primary separation chamber is bolted with a drainage paddle and a motor which is in bolted connection with the drainage paddle, and the drainage paddle is positioned at the water inlet end.

And the first sewage discharging shaft and the second sewage discharging shaft are both in spiral conveying shaft structures.

And a chain is connected between the first sewage discharging shaft and the second sewage discharging shaft.

The sieve mesh has all been seted up to the bottom of first blow off pipe and second blow off pipe, communicates each other through the sieve mesh between first blow off pipe and the second blow off pipe.

The primary chamber and the secondary chamber are both in a trapezoidal cavity structure, the primary chamber is communicated with the water inlet, and the secondary chamber is communicated with the water outlet.

The opening height of the primary chamber is higher than that of the secondary chamber.

The monitoring control frame comprises a mounting shaft, a plurality of mounting rods are arranged on the mounting shaft, and sliding grooves are formed in two sides of the surface of each mounting rod; an absorption monitor is clamped between two adjacent mounting rods through a sliding groove, and the absorption monitor is in sliding fit with the sliding groove.

Keep apart one side of otter board and articulate there is the water conservancy diversion apron, has seted up the spacing groove on the water conservancy diversion apron, keeps apart the opposite side of otter board and installs electronic hydraulic stem, and electronic hydraulic stem's one end and spacing groove joint, electronic hydraulic stem and spacing groove sliding fit.

The absorption monitor is of a hollow sphere structure, a plurality of through holes are formed in the surface of the sphere, and an adsorbent is filled in the sphere.

The surface of the mounting rod is provided with a waterproof switch, and the mounting rod is electrically connected with the electric hydraulic rod and the sewage discharge motor through the waterproof switch.

The invention has the beneficial effects that: the water quality purification device is characterized in that a hollow diversion purification wall and a monitoring control frame are arranged, the monitoring control frame is used for monitoring the pollution condition in the water body, the polluted water is drained into the diversion purification wall for separation and purification, and then is discharged into a water system again, so that the purification cycle of the water quality is completed; the diversion channel is arranged in the diversion purification wall and comprises the sieve plate, the first drainage pipe and the second drainage pipe, so that the polluted water surface layer can be subjected to classified screening purification by utilizing structures such as sieve pores on the surfaces of the sieve plate, the first drainage pipe and the second drainage pipe, and the purification efficiency is improved; through set up the blowdown axle in two blowdown pipes, utilize the auger delivery axle structure, can discharge pulpiness algae pollutant smoothly to the preliminary treatment groove in carry out processing such as fermentation, stack retting, realize the cyclic utilization of resource.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a top view of the present invention;

FIG. 3 is a schematic structural view of section A-A of FIG. 2;

FIG. 4 is a schematic structural view of section B-B of FIG. 3;

FIG. 5 is a partial display view of portion C of FIG. 4;

FIG. 6 is a schematic structural view of section D-D in FIG. 4;

FIG. 7 is a partial display view of portion E of FIG. 6;

in the figure: 1-a diversion purification wall, 2-a monitoring control frame, 103-a diversion channel, 1031-a sieve plate, 1032-a first sewage discharge pipe, 1033-a second sewage discharge pipe, 1034-a first sewage discharge shaft, 1035-a second sewage discharge shaft, 104-a pretreatment groove, 105-a transmission cavity, 106-a sewage discharge motor, 1036-a drainage paddle, 101-an isolation screen plate, 102-a diversion cover plate, 107-an electric hydraulic rod, 1021-a limiting groove, 201-an installation shaft, 202-an installation rod, 2021-a chute and 203-an absorption monitor.

Detailed Description

The technical solution of the present invention is further described below, but the scope of the claimed invention is not limited to the described.

In the description of the present invention, it is to be understood that the terms "upper", "middle", "outer", "inner", and the like, indicate orientations or positional relationships, are used for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the referenced components or elements must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

Example 1

As shown in fig. 1 to 7, an adjustable bypass for algae pollution abatement in a water body comprises a diversion purification wall 1 and a monitoring control frame 2; the guide purification walls 1 are oppositely arranged, and a monitoring control frame 2 is connected between the guide purification walls 1; a water inlet and a water outlet are formed in the inner side wall of the flow guide purification wall 1, and the water inlet and the water outlet are bolted with an isolation screen plate 101; a flow guide channel 103 is arranged in the flow guide purification wall 1, and two ends of the flow guide channel 103 are respectively communicated with the water inlet and the water outlet; a sieve plate 1031 is arranged in the flow guide channel 103, the sieve plate 1031 divides the flow guide channel 103 into a primary chamber and a secondary chamber, a transmission cavity 105 is arranged on one side of the primary chamber, a sewage discharge motor 106 is arranged on one side of the transmission cavity 105, and a pretreatment groove 104 is arranged on one side of the secondary chamber; a first sewage discharge pipe 1032 and a second sewage discharge pipe 1033 which are mutually communicated are poured in the secondary chamber, a first sewage discharge shaft 1034 is bolted on the inner wall of the first sewage discharge pipe 1032, and a second sewage discharge shaft 1035 is bolted on the inner wall of the second sewage discharge pipe 1033; one end of each of the first sewage discharge shaft 1034 and the second sewage discharge shaft 1035 extends into the transmission cavity 105, and the second sewage discharge shaft 1035 is bolted with the output shaft of the sewage discharge motor 106; a drainage paddle 1036 and a motor bolted with the drainage paddle 1036 are bolted in the primary separation chamber, and the drainage paddle 1036 is positioned at the water inlet end.

Example 2

The protocol of example 1 was followed and: the first and second blowdown shafts 1034 and 1035 are both screw conveying shaft structures.

Example 3

The protocol of example 1 was followed and: a chain is connected between the first and second sewage discharge shafts 1034 and 1035.

Example 4

The protocol of example 1 was followed and: the sieve mesh has all been seted up to first blow off pipe 1032 and second blow off pipe 1033's bottom, communicates each other through the sieve mesh between first blow off pipe 1032 and the second blow off pipe 1033.

Example 5

The protocol of example 1 was followed and: the primary chamber and the secondary chamber are both in a trapezoidal cavity structure, the primary chamber is communicated with the water inlet, and the secondary chamber is communicated with the water outlet.

Example 6

The protocol of example 1 was followed and: the opening height of the primary chamber is higher than that of the secondary chamber.

Example 7

The protocol of example 1 was followed and: the monitoring control frame 2 comprises a mounting shaft 201, a plurality of mounting rods 202 are arranged on the mounting shaft 201, and sliding grooves 2021 are formed in two sides of the surface of each mounting rod 202; an absorption monitor 203 is clamped between two adjacent mounting rods 202 through a sliding groove 2021, and the absorption monitor 203 is in sliding fit with the sliding groove 2021.

Example 8

The protocol of example 1 was followed and: one side of the isolation screen plate 101 is hinged with a flow guide cover plate 102, a limit groove 1021 is formed in the flow guide cover plate 102, an electric hydraulic rod 107 is installed on the other side of the isolation screen plate 101, one end of the electric hydraulic rod 107 is clamped with the limit groove 1021, and the electric hydraulic rod 107 is in sliding fit with the limit groove 1021.

Example 9

The protocol of example 7 was followed and: the absorption monitor 203 is a hollow sphere structure, a plurality of through holes are formed in the surface of the sphere, and an adsorbent is filled in the sphere.

Example 10

The protocol of example 7 was followed and: the surface of the mounting rod 202 is provided with a waterproof switch, and the mounting rod 202 is electrically connected with the electric hydraulic rod 107 and the sewage discharge motor 106 through the waterproof switch.

Example 10

Based on the above embodiment, specifically:

an adjustable by-pass channel for algae pollution treatment of a water body comprises a diversion purification wall 1 and a monitoring control frame 2, wherein the diversion purification wall 1 is built on a water bank of the water body to be treated, and a wall body is used as a by-pass channel structure for treating the water environment; the monitoring control frame 2 is arranged between the two opposite diversion purification walls 1, so that the specification of the monitoring control frame 2 can be selected and customized according to the specific water body or river scale;

as shown in fig. 3, a water inlet and a water outlet are formed on one side surface of the diversion purification wall 1, a diversion channel 103 is formed inside the diversion purification wall 1, and two opposite ends of the diversion channel 103 are respectively communicated to the outside of the diversion purification wall 1 through the water inlet and the water outlet, so that water can be introduced into the diversion channel 103 from the water inlet and then discharged into a water system through the water outlet; a sieve plate 1031 is bolted on the inner surface of the flow guide channel 103, a primary chamber and a secondary chamber are respectively arranged in the flow guide channel 103 through the sieve plate 1031, and sewage entering the flow guide channel 103 can be primarily separated and filtered through the sieve plate 1031;

a first sewage discharge pipe 1032 and a second sewage discharge pipe 1033 are cast on the inner surface of the secondary chamber, a pretreatment groove 104 is formed in the diversion purification wall 1 and is communicated with the first sewage discharge pipe 1032 and the second sewage discharge pipe 1033, and the two sewage discharge pipes can discharge pollutants such as filtered algae into the pretreatment groove 104; a first sewage discharge shaft 1034 is bolted on the inner surface of the first sewage discharge pipe 1032, a second sewage discharge shaft 1035 is bolted on the inner surface of the second sewage discharge pipe 1033, and the first sewage discharge shaft 1034 and the second sewage discharge shaft 1035 are both of spiral conveying shaft structures, so that the spiral conveying shaft is beneficial to conveying slurry pollutants;

a transmission cavity 105 is formed in the diversion purification wall 1, and the first sewage discharge shaft 1034 and the second sewage discharge shaft 1035 both extend into the transmission cavity 105; a chain is arranged between the first blowdown shaft 1034 and the second blowdown shaft 1035; the inside of the diversion purification wall 1 is provided with the sewage discharge motor 106, and the output shaft of the sewage discharge motor 106 is bolted with the second sewage discharge shaft 1035, so that the sewage discharge motor 106 can be used for driving the two sewage discharge shafts to work simultaneously, and the sewage discharge efficiency is improved.

Preferably, the bottom surfaces of the first and second drain pipes 1032, 1033 are provided with sieve holes, and the first and second drain pipes 1032, 1033 are communicated with each other through the sieve holes, so that sewage is subjected to multi-layer classification screening in the diversion channel 103, and the water quality is further improved.

Preferably, the primary chamber and the secondary chamber are both in a trapezoidal cavity structure, the primary chamber is communicated with the water inlet, and the secondary chamber is communicated with the water outlet; the opening height of the primary chamber is higher than that of the secondary chamber; the inner surface of the primary chamber is bolted with a drainage paddle 1036 and is driven by a motor, and when sewage passes through a water inlet, the inflow of the sewage can be accelerated by the main force of the drainage paddle 1036; the position of the water discharge paddle 1036 corresponds to the water inlet.

As shown in fig. 1, the surfaces of the water inlet and the water outlet are bolted with an isolation screen 101 to prevent large-volume sundries or organisms in the water from entering the diversion channel 103 by mistake to form blockage; a flow guide cover plate 102 is hinged to one side surface of the flow guide purification wall 1; the electric hydraulic rod 107 is arranged on the side surface of the guide purification wall 1, and the limiting groove 1021 is formed in the inner surface of the guide cover plate 102; one end of the electric hydraulic rod 107 is clamped with the limiting groove 1021 and is in sliding fit with the limiting groove 1021; the deflector plate 102 is used to cover the water inlet and guide the sewage when purifying the sewage.

As shown in fig. 4-6, the monitoring control frame 2 includes an installation shaft 201 and an installation rod 202, two opposite end faces of the installation shaft 201 are bolted to the diversion purification wall 1, and the whole monitoring control frame 2 is rotationally matched with the diversion purification wall 1 through the installation shaft 201; one side surface of the mounting shaft 201 is welded with a plurality of mounting rods 202, two opposite side surfaces of the mounting rods 202 are respectively provided with a sliding groove 2021, an absorption monitor 203 is clamped between two adjacent mounting rods 202 through the sliding grooves 2021, and the absorption monitor 203 is in sliding fit with the sliding grooves 2021; the absorption monitor 203 is a hollow sphere structure, the surface of which is provided with a plurality of through holes, and the interior of the sphere is filled with an adsorbent; the surface of the mounting rod 202 is provided with a waterproof switch, and the mounting rod 202 is electrically connected with the electric hydraulic rod 107 and the sewage discharge motor 106 through the waterproof switch; the absorption monitor 203 adsorbs algae pollutants on the water surface by using an internal adsorbent, the weight of the absorption monitor 203 is increased, the algae pollutants exceed the buoyancy of water to the sphere and then sink, the water-proof switch is touched and started, and then the driving motors of the electric hydraulic rod 107, the sewage discharge motor 106 and the drainage paddle 1036 are started to perform the sewage purification and separation and sewage discharge processes.

It should be further noted that in the present invention, the sewage discharging motor 106 is a YE2 three-phase asynchronous motor, the electro-hydraulic rod 107 is a DYTZ electro-hydraulic push rod, wherein the installation rod 202 and the surface-mounted waterproof switch thereof are both waterproof structures, the waterproof switch is a touch switch, when the absorption monitor 203 uses the internal adsorbent (including activated carbon and other substances) to adsorb algae pollutants on the water surface, the weight of the absorption monitor 203 is increased, the algae pollutants sink after exceeding the buoyancy of water to the sphere, and the water is touched to start the waterproof switch, so as to start the driving motors of the electro-hydraulic rod 107, the sewage discharging motor 106 and the drainage paddle 1036, the electro-hydraulic rod 107 pushes to open the diversion cover plate 102, and the sewage is drained into the diversion channel 103; meanwhile, a driving motor of the drainage paddle 1036 is started, and drainage is accelerated by the drainage paddle 1036; in the flowing process, sewage flows through the primary chamber, the sieve plate 1031, the first sewage discharge pipe 1032, the second sewage discharge pipe 1033 and the secondary chambers in sequence, and finally flows back to a water body through the water outlet to complete circulation; at this time, the sewage discharging motor 106 is simultaneously started, and the two sewage discharging shafts of the spiral conveying shaft structure are used for discharging the separated pollutants such as algae slurry to the pretreatment tank 104 for subsequent utilization.

In summary, the present invention includes the guiding purification walls and the monitoring control frame, the monitoring control frame is installed between the two opposite guiding purification walls and is rotatably engaged with the guiding purification walls, the guiding purification walls are internally provided with guiding channels, and the opposite ends of the guiding purification walls are communicated to the outside of the guiding purification walls. According to the invention, the guide purification wall and the monitoring control frame which are hollow inside are arranged, the monitoring control frame is utilized to monitor the pollution condition in the water body, the polluted water is guided into the guide purification wall for separation and purification, and then is discharged into the water system again, so that the purification cycle of the water quality is completed; wherein through at inside water conservancy diversion channel that sets up of water conservancy diversion purifying wall, contain sieve, first blow off pipe and second blow off pipe, can utilize the sieve mesh isotructure on three surface to carry out the hierarchical sieve on the water top layer after polluting and strain the purification, improve purification efficiency.

Furthermore, in the description herein, reference to the description of "one embodiment," "an example," "a specific example" or the like means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The preferred embodiments of the invention disclosed above are intended to be illustrative only. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise embodiments disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best utilize the invention. The invention is limited only by the claims and their full scope and equivalents.

Claims (10)

1. The utility model provides an adjustable by-pass for water body algae pollution abatement, includes water conservancy diversion purifying wall (1) and monitoring control frame (2), its characterized in that: the guide purification walls (1) are oppositely arranged, and monitoring control frames (2) are connected between the guide purification walls (1); a water inlet and a water outlet are formed in the inner side wall of the flow guide purification wall (1), and the water inlet and the water outlet are bolted with an isolation screen plate (101); a flow guide channel (103) is arranged in the flow guide purification wall (1), and two ends of the flow guide channel (103) are respectively communicated with the water inlet and the water outlet; a sieve plate (1031) is arranged in the flow guide channel (103), the sieve plate (1031) divides the flow guide channel (103) into a primary chamber and a secondary chamber, a transmission cavity (105) is arranged on one side of the primary chamber, a sewage discharge motor (106) is arranged on one side of the transmission cavity (105), and a pretreatment groove (104) is arranged on one side of the secondary chamber; a first sewage discharge pipe (1032) and a second sewage discharge pipe (1033) which are mutually communicated are poured in the secondary chamber, a first sewage discharge shaft (1034) is bolted on the inner wall of the first sewage discharge pipe (1032), and a second sewage discharge shaft (1035) is bolted on the inner wall of the second sewage discharge pipe (1033); one end of each of the first sewage discharging shaft (1034) and the second sewage discharging shaft (1035) extends into the transmission cavity (105), and the second sewage discharging shaft (1035) is bolted with an output shaft of the sewage discharging motor (106); the water discharge paddle (1036) and a motor in bolted connection with the water discharge paddle (1036) are bolted in the primary separation chamber, and the water discharge paddle (1036) is located at the water inlet end.

2. The adjustable side channel for algae pollution abatement in a body of water of claim 1, wherein: the first blowdown shaft (1034) and the second blowdown shaft (1035) are both spiral conveying shaft structures.

3. The adjustable side channel for algae pollution abatement in a body of water of claim 1, wherein: a chain is connected between the first blowdown shaft (1034) and the second blowdown shaft (1035).

4. The adjustable side channel for algae pollution abatement in a body of water of claim 1, wherein: the sieve mesh has all been seted up to the bottom of first blow off pipe (1032) and second blow off pipe (1033), communicates each other through the sieve mesh between first blow off pipe (1032) and second blow off pipe (1033).

5. The adjustable side channel for algae pollution abatement in a body of water of claim 1, wherein: the primary chamber and the secondary chamber are both in a trapezoidal cavity structure, the primary chamber is communicated with the water inlet, and the secondary chamber is communicated with the water outlet.

6. The adjustable side channel for algae pollution abatement in a body of water of claim 1, wherein: the opening height of the primary chamber is higher than that of the secondary chamber.

7. The adjustable side channel for algae pollution abatement in a body of water of claim 1, wherein: the monitoring control frame (2) comprises a mounting shaft (201), a plurality of mounting rods (202) are arranged on the mounting shaft (201), and sliding grooves (2021) are formed in two sides of the surface of each mounting rod (202); an absorption monitor (203) is clamped between two adjacent mounting rods (202) through a sliding groove (2021), and the absorption monitor (203) is in sliding fit with the sliding groove (2021).

8. The adjustable side channel for algae pollution abatement in a body of water of claim 1, wherein: keep apart one side of otter board (101) and articulate there is water conservancy diversion apron (102), has seted up spacing groove (1021) on water conservancy diversion apron (102), keeps apart the opposite side of otter board (101) and installs electronic hydraulic stem (107), and the one end and the spacing groove (1021) joint of electronic hydraulic stem (107), electronic hydraulic stem (107) and spacing groove (1021) sliding fit.

9. The adjustable side channel for algal pollution abatement of a body of water of claim 7, wherein: the absorption monitor (203) is of a hollow sphere structure, a plurality of through holes are formed in the surface of the sphere, and an adsorbent is filled in the sphere.

10. The adjustable side channel for algal pollution abatement of a body of water of claim 7, wherein: the surface of the installation rod (202) is provided with a waterproof switch, and the installation rod (202) is electrically connected with the electric hydraulic rod (107) and the sewage discharge motor (106) through the waterproof switch.

Images