CN115184086B

CN115184086B - Water quality real-time moving type monitoring equipment based on aquaculture

Info

Publication number: CN115184086B
Application number: CN202210765527.8A
Authority: CN
Inventors: 杨杰; 李贤良; 涂红雨; 赵延轲; 高丽; 关天横
Original assignee: Chongqing Customs Technology Center
Current assignee: Chongqing Customs Technology Center
Priority date: 2022-07-01
Filing date: 2022-07-01
Publication date: 2023-03-17
Anticipated expiration: 2042-07-01
Also published as: CN115184086A

Abstract

The invention belongs to the technical field of water quality monitoring, and particularly relates to a real-time mobile water quality monitoring device based on aquaculture. According to the invention, by arranging the area adjusting component, when a water area is sampled, the worm can be driven by the driving box to rotate, so that the lifting frame can move up and down on the guide rod, the lifting frame drives the sampling pipes on the movable sampling supporting blocks on the connecting rod to sample different depths of the water area, the diversity of the detection result is increased, the accuracy of monitoring is improved, and meanwhile, when two adjacent points are required to be sampled, one driving box drives the corresponding lifting frame to move, so that the connecting rod drives the sampling pipes on the movable sampling supporting blocks to move on the same horizontal plane, and then water is sampled, so that the water at the two adjacent points can be conveniently sampled, and the detection efficiency is improved.

Description

Water quality real-time moving type monitoring equipment based on aquaculture

Technical Field

The invention relates to the technical field of water quality monitoring, in particular to a real-time movable water quality monitoring device based on aquaculture.

Background

Aquaculture is the production activity of breeding, cultivating and harvesting aquatic animals and plants under artificial control. Generally comprises the whole process of cultivating aquatic products from seedlings under artificial feeding management. In a broad sense, this may also include the proliferation of aquatic resources. Aquaculture has modes of rough culture, intensive culture, high-density intensive culture and the like. The rough culture is to put seedlings in medium and small natural waters and to culture aquatic products such as fish in lakes and reservoirs, shellfish in shallow seas and the like by completely relying on natural baits. Intensive culture is to culture aquatic products such as pond fish culture, net cage fish culture, fence culture and the like in a small water body by using bait casting and fertilizing methods. The high-density intensive culture adopts methods of running water, temperature control, oxygenation, feeding of high-quality baits and the like to carry out high-density culture in a small water body so as to obtain high yield, such as running water high-density fish culture, shrimp culture and the like. With the continuous development of society, the problem of environmental pollution is more and more serious, which causes serious influence on water quality and seriously harms aquaculture.

When current aquaculture, need monitor water in real time, adopt a quality monitoring equipment that can remove to carry out the multiple spot to the waters and take a sample and detect at present, but at the sampling in-process, though can take a sample to a plurality of points, but can only take a sample to same degree of depth point, cause the sample test result single easily, cause the degree of accuracy of monitoring to reduce, this removal quality monitoring device belongs to large-scale device simultaneously, is not convenient for remove the sample to two close points.

Disclosure of Invention

The invention provides aquaculture-based real-time movable water quality monitoring equipment which comprises a monitoring platform and a movable sampling support block, wherein guide rods are fixedly connected to one end of the monitoring platform at equal intervals, the outer walls of two guide rods on one side are slidably connected with the same lifting frame, one end of the lifting frame is provided with a worm hole, one end of each guide rod on one side is fixedly connected with the same baffle, one end of each baffle is provided with a mounting hole, the inside of each mounting hole is connected with a worm through a bearing, the worm is meshed with the worm hole, one end of each lifting frame is fixedly connected with a mounting block, the mounting block and the outer wall of the protruding end of the movable sampling support block are provided with mounting holes, the inside of each mounting hole is connected with a rotating shaft through a bearing, the two ends of each rotating shaft are fixedly connected with the mounting frame, the two ends of each mounting frame are provided with mounting holes, the insides of two opposite mounting holes are connected with rotating shafts through bearings, the outsides of two rotating shafts on one side and the other are fixedly connected with connecting rods, one end of each movable sampling support block is fixedly connected with a perforated pipe, one end of a sampling pipe is fixedly connected with a telescopic pipe, and the top end of a sampling pipe is connected with a driving head of each sampling pipe.

Preferably, the one end of monitoring platform equidistance fixedly connected with expanding spring, and the same sampling case of every expanding spring's outside fixedly connected with, the feed inlet has been seted up to the one end of sampling case, and the flexible lower model of one end fixedly connected with cavity of feed inlet, the inside one end equidistance fixedly connected with triangle of sampling case support the board, and the feed port has been seted up to the inside one end equidistance of sampling case.

Preferably, the inside bottom equidistance fixedly connected with baffle of sampling case, the one end fixedly connected with telescopic link of sampling case, the one end fixedly connected with connecting plate of telescopic link, one end one side of connecting plate is provided with the jam head, and the length of every jam head differs.

Preferably, the one end fixedly connected with two cavity stoppers of sampling case, and the inside swing joint of two cavity stoppers has the slide bar, and the outside fixedly connected with of slide bar shakes the pole, shakes the one end of pole and is connected with the one end of sampling case, shakes the one end of pole and has seted up the installing port.

Preferably, the one end fixedly connected with motor of monitoring platform, and the output fixedly connected with of motor is partial to the piece, partial to the piece is located the inside of installing port, the spacing support of one end fixedly connected with of monitoring platform, the movable groove has been seted up to the one end of spacing support, it is located the inside of movable groove to rock the pole, the detection mouth has been seted up to the one end equidistance of sampling box, water quality testing appearance has been placed to the inside of every detection mouth, the one end fixedly connected with sampling pump of monitoring platform, the sampling end fixedly connected with hose of sampling pump, the end of arranging the appearance of sampling pump is connected with the one end of the flexible lower model of cavity.

Preferably, the one end fixedly connected with cavity circular connecting frame of monitoring platform, and the one end equidistance of cavity circular connecting frame has seted up the hole that absorbs water, and the one end equidistance fixed connection cavity water storage plate of cavity circular connecting frame, two orifices have all been seted up to the one end of every cavity water storage plate, and the equal fixedly connected with metal telescopic pipe in inside of every orifice, the equal fixedly connected with water smoke shower nozzle of the other end of every metal telescopic pipe.

Preferably, the monitoring platform is fixedly connected with support plates at equal distances at one end, a suction pump is fixedly connected with one end of one support plate, the drainage end of the suction pump is connected with the inside of one hollow water storage plate through a conveying pipe, and the outside of two adjacent hollow water storage plates is fixedly connected with a communicating pipe.

Preferably, no. four mounting holes have been seted up to the one end of monitoring platform, and the inside of No. four mounting holes is connected with from the rotating shaft through the bearing, from the rotating shaft and the equal fixedly connected with band pulley in the outside of motor output end, the outside sliding connection of two band pulleys has same No. two rotating bands.

Preferably, the mounting groove has been seted up to monitoring platform's bottom one end, and the inside of mounting groove is connected with rotatory plectane through the bearing, and the one end equidistance fixedly connected with mounting panel of rotatory plectane, the equal fixedly connected with of one end of every mounting panel drives the silk ribbon, and rotatory plectane and the equal fixedly connected with of the outside of spinning axle have No. two band pulleys, and the outside sliding connection of two No. two band pulleys has same rolling belt.

Preferably, every the equal fixedly connected with suspension ball of one end of extension board, the one end of monitoring platform is provided with the screw subassembly, and the one end fixedly connected with central processing unit of monitoring platform, the discharge port has been seted up to the one end of sampling box, and the internally mounted of discharge port has the discharge lid.

The beneficial effects of the invention are as follows:

1. through being provided with regional adjusting part, when taking a sample to the waters, can drive the worm through the drive case and rotate and make the lift frame reciprocate on the guide arm, the sampling pipe on the removal sample supporting shoe on driving the connecting rod through the lift frame takes a sample to the different degree of depth in this waters, increase this testing result's diversification, promote the accuracy of monitoring, simultaneously when needs take a sample to two close points, drive corresponding lift frame through one of them drive case and remove, make the connecting rod drive the sampling pipe that removes on the sample supporting shoe and remove at same horizontal plane, then take a sample to water, be convenient for take a sample to the water of two close points, promote detection efficiency.

2. Through being provided with multiple spot mixing analysis subassembly, when examining the quality of water after the sample, the sampling pump absorbs the quality of water of difference in proper order, and later discharge to the sampling box in, when the triangle that sets up through the sampling box inside supports the board, the triangle supports the board and carries out the dispersion to the water of sample and flows and make its intensive mixing, adjust the quality of water that the jam head on the telescopic link made each point sample and discharge to the sampling box in proper order, starting motor drives the partial piece and is rocking the pole internal rotation simultaneously, make to rock the pole and drive the sampling box and fully rock, through the water mixing to the sample, be convenient for detect the analysis of quality of water, the analysis efficiency of water sample is improved.

3. Through being provided with the subassembly that sprays, this remove water quality monitoring device is at the removal in-process, opens the suction pump, absorbs the water on the monitoring platform through the circular link frame of cavity, then sprays out through the water smoke shower nozzle on the cavity water storage board, can prevent that water from getting into monitoring platform top, makes the monitoring platform sink, and the water smoke that sprays simultaneously can reduce the dust that contains in the air, plays certain dust removal effect.

4. Through being provided with the subassembly of driving, when taking a sample to the waters, drive a rotation band of autogyration epaxial through the autogyration axle and rotate for the silk ribbon that drives on the rotatory plectane rotates and drives the fish of sample lower floor, prevents its striking sampling pipe, prevents that equipment from causing the damage.

Drawings

FIG. 1 is a schematic view of the overall structure of a real-time mobile water quality monitoring device based on aquaculture according to the present invention;

FIG. 2 is a schematic diagram of a side view structure of a real-time mobile water quality monitoring device based on aquaculture according to the present invention;

FIG. 3 is a schematic view of a part of the structure of a regional regulating component of a real-time mobile water quality monitoring device based on aquaculture according to the present invention;

FIG. 4 is a schematic view of a portion of the assembly of FIG. 3;

FIG. 5 is a schematic view of a part of the structure of a multipoint blending analysis component of a real-time mobile water quality monitoring device based on aquaculture, which is provided by the invention;

FIG. 6 is a schematic view of a portion of the assembly of FIG. 7;

FIG. 7 is a schematic structural view of a spraying assembly of a real-time mobile water quality monitoring device based on aquaculture according to the present invention;

fig. 8 is a schematic structural diagram of a driving assembly of a real-time mobile water quality monitoring device based on aquaculture.

In the figure: 1. monitoring the platform; 2. a guide bar; 3. a baffle plate; 4. a drive box; 5. a worm; 6. a lifting frame; 7. mounting a block; 8. a rotating shaft; 9. installing a frame; 10. moving the sampling supporting block; 11. a rotating shaft; 12. a connecting rod; 13. a sampling tube; 14. a filter head; 15. a telescopic pipe; 16. a sampling pump; 17. a hose; 18. rotating the circular plate; 19. a spin axis; 20. a first rotating belt; 21. mounting a plate; 22. driving the silk ribbon; 23. a second rotating belt; 24. a tension spring; 25. a partition plate; 26. a hollow telescopic lower sample plate; 27. a triangular butt plate; 28. a telescopic rod; 29. a connecting plate; 30. a discharge cap; 31. a motor; 32. a hollow limiting block; 33. a slide bar; 34. a shaking rod; 35. a limiting bracket; 36. a deflection block; 37. a water quality detector; 38. a plugging head; 39. a hollow circular connecting frame; 40. a central processing unit; 41. a water suction pump; 42. a transport pipe; 43. a hollow water storage plate; 44. a metal telescopic pipe; 45. a water mist spray head; 46. a communicating pipe; 47. a support plate; 48. suspending the ball; 49. a propeller assembly; 50. and a sampling box.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Referring to fig. 1, 2, 3 and 4, the water quality real-time mobile monitoring device based on aquaculture comprises a monitoring platform 1 and a mobile sampling support block 10, wherein one end of the monitoring platform 1 is fixedly connected with guide rods 2 at equal intervals, the outer walls of the two guide rods 2 at one side are slidably connected with a same lifting frame 6, one end of the lifting frame 6 is provided with a worm groove, one end of the two guide rods 2 at one side is fixedly connected with a same baffle 3, one end of each baffle 3 is provided with a first mounting hole, the inside of each first mounting hole is connected with a worm 5 through a bearing, the worm 5 is meshed with the worm groove, one end of each lifting frame 6 is fixedly connected with a mounting block 7, the outer walls of the protruding ends of the mounting block 7 and the mobile sampling support block 10 are provided with second mounting holes, and the inside of each second mounting hole is connected with a rotating shaft 8 through a bearing, the two ends of each rotating shaft 8 are fixedly connected with mounting frames 9, the two ends of each mounting frame 9 are respectively provided with three mounting holes, the interiors of the two opposite three mounting holes are connected with a rotating shaft 11 through a bearing, the outer parts of the upper rotating shaft 11 and the lower rotating shaft 11 which are positioned on one side are fixedly connected with a connecting rod 12, one end of a movable sampling supporting block 10 is provided with a perforation, the inner part of the perforation is fixedly connected with a sampling pipe 13, one end of the sampling pipe 13 is fixedly connected with a filter head 14, the other end of the sampling pipe 13 is fixedly connected with a telescopic pipe 15, the top end of each baffle 3 is fixedly connected with a driving box 4, through the arrangement of a region adjusting component, when a water area is sampled, the driving box 4 can drive a worm 5 to rotate so that a lifting frame 6 can move up and down on a guide rod 2, the lifting frame 6 drives the sampling pipe 13 on the movable sampling supporting block 10 on the connecting rod 12 to sample different depths of the water area, increase the diversification of this testing result, promote the accuracy of monitoring, when needs are taken a sample to two close points simultaneously, drive corresponding lift frame 6 through one of them drive case 4 and remove for connecting rod 12 drives the sampling pipe 13 that removes on the sample supporting shoe 10 and removes at same horizontal plane, then samples quality of water, is convenient for take a sample to the water of two close points, promotes detection efficiency.

Referring to fig. 1, 5 and 6, one end of the monitoring platform 1 is fixedly connected with the telescopic springs 24 at equal intervals, the outer part of each telescopic spring 24 is fixedly connected with the same sampling box 50, one end of each sampling box 50 is provided with a feeding hole, one end of each feeding hole is fixedly connected with the hollow telescopic lower sample plate 26, one end of the inner part of each sampling box 50 is fixedly connected with the triangular resisting plate 27 at equal intervals, and one end of the inner part of each sampling box 50 is provided with feeding holes at equal intervals.

Referring to fig. 6, the partition plates 25 are fixedly connected to the bottom end of the interior of the sampling box 50 at equal intervals, the telescopic rod 28 is fixedly connected to one end of the sampling box 50, the connecting plate 29 is fixedly connected to one end of the telescopic rod 28, the plugging heads 38 are arranged on one side of one end of the connecting plate 29, and the lengths of the plugging heads 38 are different.

Referring to fig. 5, one end of the sampling box 50 is fixedly connected with two hollow limiting blocks 32, the two hollow limiting blocks 32 are movably connected inside with a sliding rod 33, the sliding rod 33 is fixedly connected outside with a shaking rod 34, one end of the shaking rod 34 is connected with one end of the sampling box 50, and a mounting opening is formed in one end of the shaking rod 34.

Referring to fig. 1, fig. 5 and fig. 6, one end fixedly connected with motor 31 of monitoring platform 1, and output fixedly connected with deviation block 36 of motor 31, deviation block 36 is located inside the installing port, one end fixedly connected with limit bracket 35 of monitoring platform 1, the activity groove has been seted up to the one end of limit bracket 35, sway pole 34 is located inside the activity groove, detection port has been seted up to the one end equidistance of sampling box 50, water quality testing appearance 37 has been placed to the inside of every detection port, one end fixedly connected with sampling pump 16 of monitoring platform 1, the sampling end fixedly connected with hose 17 of sampling pump 16, the end of arranging of sampling pump 16 is connected with the one end of the flexible lower template 26 of cavity, through being provided with multiple spot mixing analysis subassembly, when examining the quality of water after the sample, sampling pump 16 absorbs the quality of different points in proper order, and then discharges to the incasement 50, when the triangle buttrestle plate 27 that sets up through the inside of sampling box 50, triangle buttrestle plate 27 disperses the sample water that flows and makes its intensive mixing, adjust plugging head 38 on telescopic link 28 makes the water of each point discharge to the incasement 50 in proper order, start-up at the while driving motor at the quality of water of the sampling block 34 of shaking of the pole, it is convenient for the full detection of shaking of the sample 34 of the sample, rock the sample by the detection of the quality analysis of the detection of the sample 34, the sample box 50, the quality analysis of the sample block 34 of the sample is improved efficiency of the sample.

Referring to fig. 1 and 7, one end of the monitoring platform 1 is fixedly connected with a hollow circular connecting frame 39, water suction holes are formed in one end of the hollow circular connecting frame 39 at equal intervals, one end of the hollow circular connecting frame 39 is fixedly connected with a hollow water storage plate 43 at equal intervals, two spray holes are formed in one end of each hollow water storage plate 43, metal telescopic pipes 44 are fixedly connected inside each spray hole, and a water mist spray head 45 is fixedly connected to the other end of each metal telescopic pipe 44.

Referring to fig. 1 and 7, one end of the monitoring platform 1 is fixedly connected with support plates 47 at equal distances, one end of one support plate 47 is fixedly connected with a water suction pump 41, a water discharge end of the water suction pump 41 is connected to the inside of one hollow water storage plate 43 through a conveying pipe 42, the outside of two adjacent hollow water storage plates 43 is fixedly connected with a communicating pipe 46, and by arranging a spraying component, the water suction pump 41 is opened during the moving process of the mobile water quality monitoring device, water on the monitoring platform 1 is sucked through a hollow circular connecting frame 39, and then the water is sprayed through water mist nozzles 45 on the hollow water storage plates 43, so that water can be prevented from entering the upper part of the monitoring platform 1, the monitoring platform 1 sinks, and meanwhile, dust contained in air can be reduced through the sprayed water mist, and a certain dust removing effect is achieved.

Referring to fig. 1 and 8, a fourth mounting hole is formed in one end of the monitoring platform 1, a spin axis 19 is connected to the inside of the fourth mounting hole through a bearing, a first belt wheel is fixedly connected to the outer portions of the output ends of the spin axis 19 and the motor 31, and a second same rotating belt 23 is slidably connected to the outer portions of the first belt wheels.

Referring to fig. 1 and 8, the mounting groove has been seted up to the bottom one end of monitoring platform 1, and the inside of mounting groove is connected with rotatory plectane 18 through the bearing, the equal fixedly connected with mounting panel 21 of one end equidistance of rotatory plectane 18, the equal fixedly connected with of one end of every mounting panel 21 drives the ribbon 22, rotatory plectane 18 and the equal fixedly connected with of the outside of spinning shaft 19 take turns No. two, the outside sliding connection of two take turns has same one rolling band 20, through being provided with the driving subassembly, when taking a sample to the waters, drive a rolling band 20 on spinning shaft 19 through spinning shaft 19 and rotate, make the fish of taking a sample lower floor driven by the ribbon 22 rotation on the rotatory plectane 18, prevent it from striking sampling pipe 13, cause the damage to this equipment.

Referring to fig. 1, 2 and 5, one end of each support plate 47 is fixedly connected with a suspension ball 48, one end of the monitoring platform 1 is provided with a propeller assembly 49, one end of the monitoring platform 1 is fixedly connected with a central processing unit 40, one end of the sampling box 50 is provided with a discharge port, and a discharge cover 30 is arranged inside the discharge port.

When the device is used, when a water area is sampled, the worm 5 can be driven by the driving box 4 to rotate, so that the lifting frame 6 moves up and down on the guide rod 2, the lifting frame 6 drives the sampling pipes 13 on the movable sampling supporting blocks 10 on the connecting rod 12 to sample different depths of the water area, the diversification of the detection result is increased, the accuracy of monitoring is improved, when two adjacent points need to be sampled, one of the driving boxes 4 drives the corresponding lifting frame 6 to move, so that the connecting rod 12 drives the sampling pipes 13 on the movable sampling supporting blocks 10 to move on the same horizontal plane, then the water quality is sampled, the water at the two adjacent points is conveniently sampled, the detection efficiency is improved, the sampling pump 16 sequentially sucks the water sampled by the sampling pump and then discharges the water into the sampling box 50, when the water passes through the triangular supporting plate 27 arranged in the sampling box 50, the triangular supporting plate 27 dispersedly flows the sampled water to fully mix the water, the sampling pump 38 on the telescopic rod 28 is adjusted to sequentially discharge the water sampled into the sampling box 50, the sampling pump 31 is driven by the deflection block 34, so that the sampling pipe rotates when the sampling pipe is driven by the rotary sampling shaft 19, the rotary sampling pump, the rotary sampling shaft 19, the rotary sampling pump 19, the rotary sampling box 34 is conveniently, the rotary sampling pump 19, the rotary sampling tank 19, the rotary sampling tank is conveniently, the rotary sampling tank 19, the rotary water sampling tank, the rotary sampling tank 22, the rotary sampling tank 19, the rotary sampling tank 22, then the water mist is sprayed out through the water mist spray head 45 on the hollow water storage plate 43, so that water can be prevented from entering the upper part of the monitoring platform 1, the monitoring platform 1 sinks, and meanwhile, the sprayed water mist can reduce dust contained in the air and play a certain role in dust removal.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims

1. The utility model provides a quality of water real-time mobile monitoring equipment based on aquaculture, includes monitoring platform (1) and removal sample supporting shoe (10), its characterized in that, the one end equidistance fixedly connected with guide arm (2) of monitoring platform (1), the outer wall sliding connection of two guide arms (2) that lie in one side has same lift frame (6), the one end of lift frame (6) has seted up the worm line hole, and the one end fixedly connected with same baffle (3) of two guide arms (2) that lie in one side, the one end of every baffle (3) has all seted up the mounting hole, the inside of every mounting hole all is connected with worm (5) through the bearing, worm (5) and worm line hole meshing, the equal fixedly connected with installation piece (7) of one end of every lift frame (6), the protruding end outer wall of installation piece (7) and removal sample supporting shoe (10) has all seted up No. two mounting holes, the inside of every No. two mounting holes all is connected with rotation axis (8) through the bearing, the both ends of every rotation axis (8) all fixedly connected with installation frame (9), the both ends of every installation frame (9) have all seted up No. three mounting holes, the relative two mounting holes of the inside of the relative sample supporting shoe (11) are located the perforated connecting rod (11), one side of the outside fixed connection of the bearing (11) is connected with the mounting hole (11), the two support rod (11) is connected with the lower shaft (11), one end of the sampling pipe (13) is fixedly connected with a filter head (14), the other end of the sampling pipe (13) is fixedly connected with a telescopic pipe (15), and the top end of each baffle (3) is fixedly connected with a driving box (4); the worm (5) is driven to rotate by the driving box (4), so that the lifting frame (6) moves up and down on the guide rod (2), and the sampling pipes (13) on the movable sampling supporting blocks (10) on the connecting rod (12) are driven by the lifting frame (6) to sample different depths of the water area; drive corresponding lift frame (6) through one of them drive case (4) and remove for connecting rod (12) drive remove sampling pipe (13) on sample supporting shoe (10) and remove at same horizontal plane, then sample quality of water, are convenient for sample two water that are close to the point.

2. The aquaculture-based real-time mobile water quality monitoring device according to claim 1, wherein one end of the monitoring platform (1) is fixedly connected with expansion springs (24) at equal intervals, the outer part of each expansion spring (24) is fixedly connected with the same sampling box (50), one end of each sampling box (50) is provided with a feeding hole, one end of each feeding hole is fixedly connected with a hollow telescopic lower sample plate (26), one end of the inner part of each sampling box (50) is fixedly connected with a triangular support plate (27) at equal intervals, and one end of the inner part of each sampling box (50) is provided with a feeding hole at equal intervals.

3. The aquaculture-based real-time mobile water quality monitoring device according to claim 2, wherein the bottom end of the interior of the sampling box (50) is fixedly connected with partition plates (25) at equal intervals, one end of the sampling box (50) is fixedly connected with a telescopic rod (28), one end of the telescopic rod (28) is fixedly connected with a connecting plate (29), one side of one end of the connecting plate (29) is provided with plugging heads (38), and the plugging heads (38) are different in length.

4. The aquaculture-based real-time mobile water quality monitoring device according to claim 2, wherein two hollow limiting blocks (32) are fixedly connected to one end of the sampling tank (50), a slide rod (33) is movably connected to the insides of the two hollow limiting blocks (32), a shaking rod (34) is fixedly connected to the outside of the slide rod (33), one end of the shaking rod (34) is connected to one end of the sampling tank (50), and a mounting opening is formed in one end of the shaking rod (34).

5. The aquaculture-based real-time mobile water quality monitoring device according to claim 4, wherein a motor (31) is fixedly connected to one end of the monitoring platform (1), a deviation block (36) is fixedly connected to the output end of the motor (31), the deviation block (36) is located inside an installation port, a limit bracket (35) is fixedly connected to one end of the monitoring platform (1), a movable groove is formed in one end of the limit bracket (35), a swinging rod (34) is located inside the movable groove, detection ports are formed in one end of a sampling box (50) at equal intervals, a water quality detector (37) is placed inside each detection port, a sampling pump (16) is fixedly connected to one end of the monitoring platform (1), a hose (17) is fixedly connected to the sampling end of the sampling pump (16), and one end of a hollow telescopic lower sample plate (26) is connected to the sample discharging end of the sampling pump (16).

6. The aquaculture-based real-time mobile water quality monitoring device according to claim 1, wherein one end of the monitoring platform (1) is fixedly connected with a hollow circular connecting frame (39), one end of the hollow circular connecting frame (39) is provided with water suction holes at equal intervals, one end of the hollow circular connecting frame (39) is fixedly connected with a hollow water storage plate (43) at equal intervals, one end of each hollow water storage plate (43) is provided with two spray holes, a metal telescopic pipe (44) is fixedly connected inside each spray hole, and the other end of each metal telescopic pipe (44) is fixedly connected with a water spray nozzle (45).

7. The aquaculture-based real-time mobile water quality monitoring device according to claim 6, wherein one end of the monitoring platform (1) is fixedly connected with support plates (47) at equal distances, one end of one support plate (47) is fixedly connected with a water suction pump (41), the water discharge end of the water suction pump (41) is connected to the inside of one hollow water storage plate (43) through a conveying pipe (42), and the outside of two adjacent hollow water storage plates (43) is fixedly connected with a communicating pipe (46).

8. The aquaculture-based real-time mobile water quality monitoring device according to claim 5, wherein a fourth mounting hole is formed in one end of the monitoring platform (1), a self-rotating shaft (19) is connected to the inside of the fourth mounting hole through a bearing, a first belt wheel is fixedly connected to the outer portions of the self-rotating shaft (19) and the output end of the motor (31), and a second rotating belt (23) is slidably connected to the outer portions of the two first belt wheels.

9. The aquaculture-based real-time mobile water quality monitoring device according to claim 8, wherein a mounting groove is formed in one end of the bottom of the monitoring platform (1), a rotating circular plate (18) is connected to the inside of the mounting groove through a bearing, mounting plates (21) are fixedly connected to one end of each of the rotating circular plates (18) at equal intervals, a driving ribbon (22) is fixedly connected to one end of each of the mounting plates (21), a second belt wheel is fixedly connected to the rotating circular plate (18) and the outer portion of the rotating shaft (19), and a first rotating ribbon (20) is slidably connected to the outer portions of the two second belt wheels.

10. The aquaculture-based real-time mobile water quality monitoring device according to claim 7, wherein one end of each support plate (47) is fixedly connected with a suspension ball (48), one end of each monitoring platform (1) is provided with a propeller assembly (49), one end of each monitoring platform (1) is fixedly connected with a central processing unit (40), one end of each sampling box (50) is provided with a discharge port, and a discharge cover (30) is arranged inside each discharge port.