CN218222928U - Blue algae pollution treatment equipment - Google Patents

Abstract

The utility model discloses a blue algae pollution treatment device, which comprises a box body, wherein the top end of the box body is provided with a water inlet component, and the bottom end of the box body is communicated with a water outlet; the bottom end of the box body is provided with a plurality of vibration reduction feet; the centrifugal assembly is rotationally connected in the box body and is communicated with the water inlet assembly, the centrifugal assembly is in transmission connection with a first driving assembly, and a plurality of water seepage holes are formed in the side wall of the centrifugal assembly; the dehydration subassembly, the dehydration unit mount is in the box, and the import of dehydration subassembly and the export intercommunication of centrifugation subassembly, the box is stretched out in the export of dehydration subassembly, and a plurality of dehydration holes have been seted up to the outer wall of dehydration subassembly. The utility model discloses blue alga in the ability flash separation water carries out recycle, effectively administers the blue alga pollution of water, reduces the threat of blue alga to water and aquatic organism, carries out recycle to the blue alga simultaneously, reduces the wasting of resources.

Description

Blue algae pollution treatment equipment

Technical Field

The utility model relates to a blue alga pollution treatment field especially relates to a blue alga pollution treatment equipment.

Background

Blue algae is original algae and generally occurs in water with serious pollution or nutrient enrichment and unbalanced nitrogen and phosphorus elements; the explosion and death and decomposition of the blue algae consume a large amount of dissolved oxygen in the water body, and the blue algae toxins cause a large amount of death of organisms in the water body, can also cause the water body to smell, and seriously influences the ecological balance.

The existing blue algae treatment is mainly carried out by manual fishing, the efficiency is low, and the danger is high; chinese patent No. CN202020768541.X discloses a blue algae pollution treatment device, which comprises a box body, a water suction pump and a water discharge pump, wherein the water suction pump is arranged in the middle of the left end of the box body, the water discharge pump is arranged in the middle of the right end of the box body, a photovoltaic panel is arranged at the upper end of the box body, a driving motor is arranged in the middle of the upper end of the box body, a liquid storage tank is arranged at the upper part in the box body, a first filter screen is arranged at the left part in the box body, and a second filter screen is arranged at the right part in the box body; filter screen one and filter screen two can filter the water source among this technical scheme, smash the cutter and can smash, stir the blue alga, and the catalyst can be deposited to the liquid reserve tank, and the ultraviolet lamp can be to water source ultraviolet sterilization, and the electric plate can heat sterilization to the water source, and the bradyseism seat can prevent that blue alga administers in-process device and takes place vibrations, and the photovoltaic board can be with absorbent light energy transformation electric energy storage to the battery and for the device power supply.

However, in the above scheme, the pulverized blue algae enters the water again, and is not completely separated from the water, and the pulverized blue algae causes water pollution again, so that the treatment effect is poor. Therefore, a blue algae pollution treatment device is needed to solve the technical problems.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a blue alga pollution treatment equipment to solve the problem that above-mentioned prior art exists.

In order to achieve the above purpose, the utility model provides a following scheme: the utility model provides a blue alga pollution treatment equipment, include:

the water inlet assembly is mounted at the top end of the box body, and the bottom end of the box body is communicated with a water outlet; the bottom end of the box body is provided with a plurality of damping feet;

the centrifugal assembly is rotatably connected in the box body and communicated with the water inlet assembly, the centrifugal assembly is in transmission connection with a first driving assembly, the first driving assembly is installed at the top end of the box body, and a plurality of water seepage holes are formed in the side wall of the centrifugal assembly;

the dewatering component is arranged in the box body, an inlet of the dewatering component is communicated with an outlet of the centrifugal component, an outlet of the dewatering component extends out of the box body, and a plurality of dewatering holes are formed in the outer wall of the dewatering component; the dehydration component is in transmission connection with a second driving component, and the second driving component is installed on the side wall of the box body.

Preferably, the centrifugal assembly comprises a centrifugal cylinder which is rotatably connected in the box body, a spiral flow deflector is fixedly connected in the centrifugal cylinder, and the water seepage hole is formed in the outer wall of the centrifugal cylinder; the top end of the centrifugal cylinder is fixedly connected with a communicating pipe, the communicating pipe extends out of the top end of the box body and is rotatably connected with the box body, and the communicating pipe is communicated with the water inlet assembly; the first driving assembly is in transmission connection with the communicating pipe; the bottom end of the centrifugal cylinder is rotatably connected and communicated with an inlet of the dewatering component.

Preferably, the outer wall of the centrifugal cylinder is fixedly sleeved with a supporting bearing, an inner ring of the supporting bearing is fixedly connected with the outer wall of the centrifugal cylinder, and a plurality of supporting rods are fixedly connected between an outer ring of the supporting bearing and the inner wall of the box body.

Preferably, the dewatering assembly comprises a dewatering cylinder arranged in the box body, an inlet of the dewatering cylinder is rotatably connected and communicated with an outlet of the centrifugal cylinder, and an outlet of the centrifugal cylinder extends out of the box body; the dewatering holes are formed in the outer wall of the dewatering cylinder; the centrifugal cylinder is rotatably connected with a dewatering helical blade, the dewatering helical blade is in transmission connection with the second driving assembly through a transmission shaft, and the dewatering helical blade is fixedly connected with the outer wall of the transmission shaft.

Preferably, a plurality of fixing rods are fixedly connected to an outlet of the dewatering cylinder, an outer ring of a fixed bearing is fixedly connected between the plurality of fixing rods, and the transmission shaft is fixedly connected with an inner ring of the fixed bearing.

Preferably, the blade surface spacing of the dewatering helical blades is reduced from the inlet to the outlet of the dewatering cylinder in sequence.

Preferably, the water inlet assembly comprises a water pump arranged at the top end of the box body, and an outlet of the water pump is rotatably connected and communicated with the communicating pipe; the outlet of the water pump is communicated with a water inlet pipe, one end of the water inlet pipe, which is far away from the water pump, is fixedly connected and communicated with an inlet assembly, and the inlet assembly extends into the water body containing the blue algae.

Preferably, the inlet assembly comprises a mounting ring fixedly connected to the tail end of the water inlet pipe, the bottom end of the mounting ring is fixedly connected with a suction port filter screen, and the suction port filter screen is located below the water surface; the mounting ring is fixedly connected with a plurality of floating balls, and the floating balls and the mounting ring float on the water surface.

The utility model discloses a following technological effect: the utility model discloses a blue alga pollution treatment equipment, in will containing the water of blue alga take out centrifugal assembly through the subassembly that intakes, first drive assembly drives centrifugal assembly high-speed rotation and carries out preliminary centrifugal dehydration to blue alga water, then guide into the dehydration subassembly with the blue alga after preliminary dehydration again, the dehydration subassembly carries out secondary dehydration to the blue alga after preliminary dehydration, separate blue alga and water once more, reduce the water content in the blue alga, the water that centrifugation and dehydration produced is discharged from the delivery port, the box is discharged from the export of dehydration subassembly to the blue alga after the dehydration, convenient recycle; the damping foot is used for reducing the vibration of equipment operation in-process, prolongs the life of equipment. The utility model discloses blue alga in the ability flash separation water carries out recycle, effectively administers the blue alga pollution of water, reduces the threat of blue alga to water and aquatic organism, carries out recycle to the blue alga simultaneously, reduces the wasting of resources.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings required to be used in the embodiments will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a schematic view of the structure of the blue algae pollution treatment equipment of the utility model;

FIG. 2 is an axial view of the centrifuge tube of the present invention;

FIG. 3 is an axial view of the spiral guide vane of the present invention;

FIG. 4 is a schematic top view of the centrifugal cylinder of the present invention;

FIG. 5 is an axial view of the dehydration cylinder of the present invention;

wherein, 1, a box body; 2. a water outlet; 3. a vibration damping foot; 4. a centrifugal cylinder; 5. a spiral flow deflector; 6. a water seepage hole; 7. a communicating pipe; 8. a support bearing; 9. a support bar; 10. a dewatering drum; 11. a dewatering hole; 12. a dewatering helical blade; 13. a drive shaft; 14. fixing the rod; 15. fixing the bearing; 16. a water pump; 17. a water inlet pipe; 18. a mounting ring; 19. a suction port filter screen; 20. a floating ball; 21. a first motor; 22. a drive bevel gear; 23. a driven bevel gear; 24. a second motor; 25. an outlet valve; 26. a rotating connector.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

In order to make the above objects, features and advantages of the present invention more comprehensible, the present invention is described in detail with reference to the accompanying drawings and the detailed description.

Referring to fig. 1-5, the utility model provides a blue algae pollution treatment equipment, include:

the water inlet component is arranged at the top end of the box body 1, and the water outlet 2 is communicated with the bottom end of the box body 1; the bottom end of the box body 1 is provided with a plurality of damping feet 3;

the centrifugal assembly is rotatably connected in the box body 1 and is communicated with the water inlet assembly, the centrifugal assembly is in transmission connection with a first driving assembly, the first driving assembly is installed at the top end of the box body 1, and a plurality of water seepage holes 6 are formed in the side wall of the centrifugal assembly;

the dewatering component is arranged in the box body 1, an inlet of the dewatering component is communicated with an outlet of the centrifugal component, an outlet of the dewatering component extends out of the box body 1, and a plurality of dewatering holes 11 are formed in the outer wall of the dewatering component; the dehydration component is connected with a second driving component in a transmission way, and the second driving component is arranged on the side wall of the box body 1.

The utility model discloses a blue algae pollution treatment equipment, through the subassembly that intakes with the water that contains the blue algae take out in the centrifugal subassembly, first drive assembly drives the high-speed rotation of centrifugal subassembly and carries out preliminary centrifugal dehydration to blue algae water, then the blue algae after preliminary dehydration is leading-in to the dehydration subassembly again, the dehydration subassembly carries out secondary dehydration to the blue algae after preliminary dehydration, separate blue algae and water once more, reduce the water content in the blue algae, the water that centrifugation and dehydration produced is discharged from delivery port 2, box 1 is discharged from the export of dehydration subassembly to the blue algae after the dehydration, convenient recycle; the vibration damping foot 3 is used for reducing vibration in the operation process of the equipment and prolonging the service life of the equipment.

Furthermore, the blue algae has a small size, so the aperture of the water seepage holes 6 and the dehydration holes 11 is not less than 120 meshes, and the blue algae is effectively filtered.

Further, the bottom of box 1 sets up to the centre slope, and delivery port 2 is installed in the lowest of 1 bottom of box for drainage speed prevents ponding, installs outlet valve 25 on the delivery port 2 for control goes out water.

In a further optimized scheme, the centrifugal assembly comprises a centrifugal cylinder 4 which is rotatably connected in the box body 1, a spiral flow deflector 5 is fixedly connected in the centrifugal cylinder 4, and a water seepage hole 6 is formed in the outer wall of the centrifugal cylinder 4; the top end of the centrifugal cylinder 4 is fixedly connected with a communicating pipe 7, the communicating pipe 7 extends out of the top end of the box body 1 and is rotatably connected with the box body 1, and the communicating pipe 7 is communicated with the water inlet assembly; the first driving component is in transmission connection with the communicating pipe 7; the bottom end of the centrifugal cylinder 4 is rotationally connected and communicated with an inlet of the dewatering component. The first driving component drives the centrifugal cylinder 4 to rotate at a high speed, water is thrown out from the water seepage holes 6 by using centrifugal force, and blue algae are intercepted by the water seepage holes 6; the spiral guide vane 5 is used for prolonging the water flow stroke, so that the water flow descends spirally, the centrifugation time is prolonged, and the centrifugation effect is improved.

Further, the first driving component comprises a first motor 21 arranged at the top end of the box body 1, an output shaft of the first motor 21 is in transmission connection with a driving bevel gear 22, and the driving bevel gear 22 is in meshing connection with a driven bevel gear 23 fixedly sleeved on the communicating pipe 7; the first motor 21 is a high-speed motor, and drives the communicating pipe 7 to rotate at a high speed through the meshed driving bevel gear 22 and the driven bevel gear 23, so that the centrifugal cylinder 4 rotates at a high speed.

According to a further optimized scheme, a supporting bearing 8 is fixedly sleeved on the outer wall of the centrifugal cylinder 4, an inner ring of the supporting bearing 8 is fixedly connected with the outer wall of the centrifugal cylinder 4, and a plurality of supporting rods 9 are fixedly connected between an outer ring of the supporting bearing 8 and the inner wall of the box body 1. The supporting bearing 8 and the supporting rod 9 are used for improving the stability of the centrifugal cylinder 4 and preventing the centrifugal cylinder 4 rotating at high speed from shaking; the support bearing 8 is a conventional high-speed bearing, which meets the requirement of the centrifugal cylinder 4 for the rotating speed, and is not described herein again.

In a further optimized scheme, the dewatering component comprises a dewatering cylinder 10 arranged in the box body 1, an inlet of the dewatering cylinder 10 is rotatably connected and communicated with an outlet of the centrifugal cylinder 4, and an outlet of the centrifugal cylinder 4 extends out of the box body 1; the dewatering holes 11 are arranged on the outer wall of the dewatering cylinder 10; a dewatering helical blade 12 is rotationally connected in the centrifuge tube 4, the dewatering helical blade 12 is in transmission connection with the second driving component through a transmission shaft 13, and the dewatering helical blade 12 is fixedly connected on the outer wall of the transmission shaft 13. The blue algae after preliminary centrifugation enters a dewatering cylinder 10, a transmission shaft 13 drives a dewatering helical blade 12 to rotate, the blue algae is pushed to move towards an outlet of the dewatering cylinder 10 by using the principle of a packing auger, the blue algae is extruded at the same time, the blue algae is further dewatered, and water is discharged from dewatering holes 11; the blue algae discharged from the dewatering cylinder 10 has less water content and is more convenient to recycle.

Furthermore, the recovered blue algae has various purposes, can be used as main feed for silver carps and bighead carps, and reduces the breeding cost; the blue algae compost can also be used as a compost material to be decomposed into an organic fertilizer to supplement nitrogen and phosphorus elements in soil; meanwhile, a process capable of effectively decomposing the blue algae toxin in the blue algae is developed by a certain team, and the blue algae subjected to detoxification treatment can be used as a high-quality vegetable protein source.

Further, the second drive assembly comprises a second motor 24 installed on the outer wall of the box body 1, an output shaft of the second motor 24 extends out of the box body 1 and is in transmission connection with the transmission shaft 13, and the second motor 24 drives the dewatering helical blades 12 to rotate through the transmission shaft 13, so that the effects of dewatering and transferring blue algae are achieved.

According to the further optimized scheme, a plurality of fixing rods 14 are fixedly connected to the outlet of the dewatering cylinder 10, outer rings of fixing bearings 15 are fixedly connected among the fixing rods 14, and the transmission shaft 13 is fixedly connected with inner rings of the fixing bearings 15. The fixing rod 14 and the fixing bearing 15 are used for supporting the tail end of the transmission shaft 13 and maintaining the stability of the transmission shaft 13; since the rotation speed of the transmission shaft 13 during the dehydration process is relatively slow, the fixed bearing 15 may be a conventional ball bearing, which is not described herein again.

In a further optimized scheme, the blade surface spacing of the dewatering helical blades 12 is sequentially reduced from the inlet to the outlet of the dewatering cylinder 10. The blade spacing of the dewatering helical blades 12 is gradually reduced, the dewatering strength can be gradually increased, the dewatering effect is improved, and the water content of the blue algae after treatment is lower.

Furthermore, the centrifugation and dehydration process of the application can not lead to the death of a large amount of cracked blue algae, thereby not leading to the back discharge of the blue algae toxin into water and simultaneously reducing the nutrition loss of the recovered blue algae.

According to a further optimized scheme, the water inlet assembly comprises a water pump 16 arranged at the top end of the box body 1, and an outlet of the water pump 16 is rotatably connected and communicated with the communicating pipe 7; the outlet of the water pump 16 is communicated with a water inlet pipe 17, one end of the water inlet pipe 17, which is far away from the water pump 16, is fixedly connected and communicated with an inlet assembly, and the inlet assembly extends into the water body containing the blue algae. The water pump 16 pumps the blue algae on the water surface into the centrifugal cylinder 4 through the water inlet pipe 17; the communicating pipe 7 is connected with the outlet of the water pump 16 through the rotary connector 26, so that the inflow of the water containing blue algae is not influenced by the high-speed rotation of the communicating pipe 7; the purpose of the import component is to improve the recovery rate of the blue algae.

Furthermore, the outlet of the centrifuge tube 4 is connected with the inlet of the dewatering tube 10 by a rotary connector 26, and the rotary connector 26 is prior art and will not be described in detail herein.

According to a further optimization scheme, the inlet assembly comprises a mounting ring 18 fixedly connected to the tail end of the water inlet pipe 17, a suction port filter screen 19 is fixedly connected to the bottom end of the mounting ring 18, and the suction port filter screen 19 is located below the water surface; the mounting ring 18 is fixedly connected with a plurality of floating balls 20, and the floating balls 20 and the mounting ring 18 float on the water surface. The buoyancy of the floating ball 20 drives the mounting ring 18 and the suction port filter screen 19 to float on the water surface, and the blue algae floats on the water surface, so that the design can improve the content of the blue algae in the pumped water and improve the treatment efficiency of the blue algae; the function of the suction screen 19 is to prevent floating debris from blocking the intake pipe 17 or damaging the water pump 16.

The using method comprises the following steps:

the water area with more blue algae but less stormy waves and calm water surface is selected, and the blue algae on the water surface can be intercepted and dragged to a preset place by a trawl, so that the density of the blue algae is improved, and the treatment efficiency is accelerated.

The inlet assembly is thrown into water, and the mounting ring 18 and the suction port filter screen 19 float under the water surface through the floating ball 20, so that blue algae can be sucked conveniently, and meanwhile, water surface garbage is intercepted.

The water pump 16 sends water containing blue algae into the centrifugal cylinder 4, the first driving assembly drives the centrifugal cylinder 4 to rotate at a high speed, the water is discharged from the seepage holes 6, and the blue algae moves downwards under the action of centrifugal force and the friction force of the spiral flow deflector 5 to enter the dewatering cylinder 10.

The second motor 24 drives the dewatering helical blade 12 to rotate, carries the blue algae after preliminary dewatering to move to the export, and the blade that draws near gradually simultaneously makes mutual extrusion between the blue algae, discharges moisture from dewatering hole 11, makes the water content of blue algae further reduce, discharges from the export of dewatering cylinder 10 at last and retrieves.

In the process, the outlet valve 25 is in an open state, and the water generated by the centrifugation and dehydration is discharged from the water outlet 2 and is discharged back into the water body through a drain pipe (not shown).

In the description of the present invention, it is to be understood that the terms "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on those shown in the drawings, and are merely for convenience of description of the present invention, and do not indicate or imply that the device or element so referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention.

The above embodiments are only for describing the preferred embodiments of the present invention, and are not intended to limit the scope of the present invention, and various modifications and improvements made by those skilled in the art without departing from the design spirit of the present invention should fall within the protection scope defined by the claims of the present invention.

Claims (8)

1. The utility model provides a blue alga pollution treatment equipment which characterized in that includes:

the water inlet device comprises a box body (1), wherein a water inlet assembly is installed at the top end of the box body (1), and a water outlet (2) is communicated with the bottom end of the box body (1); a plurality of vibration reduction feet (3) are arranged at the bottom end of the box body (1);

the centrifugal assembly is rotatably connected in the box body (1), the centrifugal assembly is communicated with the water inlet assembly, the centrifugal assembly is in transmission connection with a first driving assembly, the first driving assembly is installed at the top end of the box body (1), and a plurality of water seepage holes (6) are formed in the side wall of the centrifugal assembly;

the dewatering component is arranged in the box body (1), an inlet of the dewatering component is communicated with an outlet of the centrifugal component, an outlet of the dewatering component extends out of the box body (1), and a plurality of dewatering holes (11) are formed in the outer wall of the dewatering component; the dehydration component is in transmission connection with a second driving component, and the second driving component is installed on the side wall of the box body (1).

2. The cyanobacteria pollution treatment apparatus according to claim 1, wherein: the centrifugal assembly comprises a centrifugal cylinder (4) which is rotatably connected in the box body (1), a spiral flow deflector (5) is fixedly connected in the centrifugal cylinder (4), and the water seepage holes (6) are formed in the outer wall of the centrifugal cylinder (4); a communicating pipe (7) is fixedly connected to the top end of the centrifugal cylinder (4), the communicating pipe (7) extends out of the top end of the box body (1) and is rotatably connected with the box body (1), and the communicating pipe (7) is communicated with the water inlet assembly; the first driving assembly is in transmission connection with the communicating pipe (7); the bottom end of the centrifugal cylinder (4) is rotatably connected and communicated with an inlet of the dewatering component.

3. The cyanobacteria pollution treatment device according to claim 2, characterized in that: the outer wall fixed cover of centrifuge bowl (4) is equipped with support bearing (8), the inner circle of support bearing (8) with centrifuge bowl (4) outer wall rigid coupling, the outer lane of support bearing (8) with the rigid coupling has a plurality of bracing pieces (9) between box (1) inner wall.

4. The cyanobacteria pollution treatment apparatus according to claim 2, wherein: the dewatering assembly comprises a dewatering cylinder (10) arranged in the box body (1), an inlet of the dewatering cylinder (10) is rotatably connected and communicated with an outlet of the centrifugal cylinder (4), and an outlet of the centrifugal cylinder (4) extends out of the box body (1); the dewatering holes (11) are formed in the outer wall of the dewatering cylinder (10); the centrifugal cylinder (4) internal rotation is connected with dehydration helical blade (12), dehydration helical blade (12) through transmission shaft (13) with the transmission of second drive assembly is connected, dehydration helical blade (12) rigid coupling is in the outer wall of transmission shaft (13).

5. The cyanobacteria pollution treatment device according to claim 4, characterized in that: the outlet of the dewatering cylinder (10) is fixedly connected with a plurality of fixing rods (14), outer rings of fixing bearings (15) are fixedly connected among the fixing rods (14), and the transmission shaft (13) is fixedly connected with inner rings of the fixing bearings (15).

6. The cyanobacteria pollution treatment apparatus according to claim 4, wherein: the blade surface space of the dewatering helical blade (12) is reduced from the inlet of the dewatering cylinder (10) to the outlet direction in sequence.

7. The cyanobacteria pollution treatment device according to claim 2, characterized in that: the water inlet assembly comprises a water pump (16) arranged at the top end of the box body (1), and the outlet of the water pump (16) is rotatably connected and communicated with the communicating pipe (7); the outlet of the water pump (16) is communicated with a water inlet pipe (17), one end of the water inlet pipe (17) far away from the water pump (16) is fixedly connected and communicated with an inlet assembly, and the inlet assembly extends into the water body containing the blue algae.

8. The cyanobacteria pollution treatment apparatus according to claim 7, wherein: the inlet assembly comprises a mounting ring (18) fixedly connected to the tail end of the water inlet pipe (17), the bottom end of the mounting ring (18) is fixedly connected with a suction port filter screen (19), and the suction port filter screen (19) is located below the water surface; the mounting ring (18) is fixedly connected with a plurality of floating balls (20), and the floating balls (20) and the mounting ring (18) float on the water surface.

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