CN114403070A

CN114403070A - Intelligent aquaculture system

Info

Publication number: CN114403070A
Application number: CN202210078877.7A
Authority: CN
Inventors: 潘桂兰
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-01-24
Filing date: 2022-01-24
Publication date: 2022-04-29

Abstract

The invention discloses an intelligent aquaculture system, which comprises a floating platform, wherein the floating platform can float on the water surface, a smooth cavity is arranged on the top surface of the floating platform, an upwardly extending aquaculture box is arranged in the smooth cavity in a sliding manner, an oxygen supply box is fixedly arranged on the top surface of the aquaculture box, an oxygen supply pipe is fixedly arranged on the bottom surface of the oxygen supply box, the bottom surface of the oxygen supply pipe is inserted into the aquaculture box, two bilaterally symmetrical exhaust ports are formed in the top surface of the aquaculture box, a fixed block is fixedly arranged on the bottom surface of the floating platform, a fixed cavity is arranged in the fixed block, a left bevel gear and a right bevel gear are rotatably arranged in the fixed cavity, a left rotating shaft is fixedly arranged on the left side surface of the left bevel gear, and three rotationally symmetrical pulp sheets are fixedly arranged on the periphery of the left rotating shaft. High efficiency and can effectively save labor force.

Description

Intelligent aquaculture system

Technical Field

The invention relates to the technical field of aquaculture, in particular to an intelligent aquaculture system.

Background

Aquaculture generally fixes the culture device in river water, so that a plurality of culture devices are generally required to be installed for the river water with a large area, the cost of the culture device is increased, and the culture device is fixed in the river water, so that the maintenance and the detection of the culture device are difficult, and the maintenance cost of the culture device is increased;

and current fry is put in and generally adopts the manual work to put in, not only troublesome poeration, moreover consuming time hard, work efficiency is low to in the manual transportation input process, the easy oxygen deficiency of fry dies, and the ecosystem of river can be influenced to rubbish in the river, thereby reduces the environmental quality that the fry lives, has reduced the survival rate of fry in the river.

Disclosure of Invention

The present invention aims to provide an intelligent aquaculture system for overcoming the above-mentioned drawbacks of the prior art.

The intelligent aquaculture system comprises a floating platform, wherein the floating platform can float on the water surface, a smooth cavity is formed in the top surface of the floating platform, an upwards extending aquaculture box is slidably arranged in the smooth cavity and used for containing fish fries, an oxygen supply box is fixedly arranged on the top surface of the aquaculture box and used for storing oxygen, an oxygen supply pipe is fixedly arranged on the bottom surface of the oxygen supply box, the bottom surface of the oxygen supply pipe is inserted into the aquaculture box, so that the oxygen in the oxygen supply box can flow into the aquaculture box through the oxygen supply pipe, oxygen can be supplied to the fish fries in the aquaculture box, two bilaterally symmetrical exhaust ports are formed in the top surface of the aquaculture box, and the exhaust ports are used for exhausting gas in the aquaculture box;

the floating platform is characterized in that a fixed block is fixedly arranged on the bottom surface of the floating platform, a fixed cavity is formed in the fixed block, a left bevel gear and a right bevel gear are rotatably arranged in the fixed cavity, a left rotating shaft is fixedly arranged on the left side surface of the left bevel gear, three rotationally symmetric blades are fixedly arranged on the periphery of the left rotating shaft, the floating platform can slide leftwards through the blades, a right rotating shaft is fixedly arranged on the right side surface of the right bevel gear, and two vertically symmetric fixed plates are fixedly arranged on the periphery of the right rotating shaft;

float and to be equipped with on the platform fixedly and arrange the material pipe, it runs through to arrange the material pipe float the platform top surface, arrange and to be equipped with the feedbox on the material pipe top surface fixedly, the fodder is equipped with in the feedbox, and fodder in the feedbox can be followed arrange the material pipe bottom mouth and fall out, two the fixed plate all is used for the shutoff arrange the material pipe bottom mouth.

Preferably, a collecting plate is fixedly arranged on the left side surface of the floating table and used for collecting garbage on the left side of the collecting plate in a centralized manner, a collecting cavity is formed in the left side surface of the collecting plate, a concentrating cavity is formed in the right wall of the collecting cavity, and a collecting opening is formed in the bottom wall of the concentrating cavity;

the garbage net is fixedly arranged on the bottom surface of the floating platform and used for loading garbage, and a top port of the garbage net is communicated with a bottom port of the collecting port, so that the garbage in the collecting cavity can flow into the garbage net along with water flow through the concentrating cavity and the collecting port.

Preferably, four rotationally symmetrical support rods are fixedly arranged on the top surface of the floating platform, a hoisting box is fixedly arranged on the upper side of the floating platform, the top ends of the four support rods are fixed to the outer peripheral surface of the hoisting box, a hoisting cavity is formed in the hoisting box, and a hoisting shaft is rotatably arranged on the inner wall of the hoisting cavity;

the device comprises a culture box, a smooth cavity, a winding shaft, a winding rope, a rotating motor and a motor, wherein the winding rope is wound on the periphery of the winding shaft, the lower end of the winding rope is fixed to the top surface of the culture box, so that the culture box entering water can be pulled back upwards into the smooth cavity through the winding rope, the rotating motor is fixedly arranged in the inner wall of the winding cavity, and the rotating motor is in power connection with the winding shaft.

Preferably, two culture cavities which are symmetrical up and down are formed in the culture box, sliding doors are arranged in the left walls of the two culture cavities in a sliding mode, and the two sliding doors can prevent the fry from swimming out of the culture cavities on the same side to the left;

two sliding door cavities which are symmetrical up and down are formed in the left walls of the two breeding cavities, the upper side surface and the lower side surface of each sliding door are respectively inserted into the sliding door cavities on the same side, so that the sliding doors can only slide in the front-back direction, sliding door shafts are rotatably arranged in the bottom surfaces of the two sliding doors, sliding door gears are fixedly arranged on the peripheries of the two sliding door shafts, and the peripheral surfaces of the two sliding door gears are respectively meshed with the bottom walls of the sliding door cavities on the same side, so that the sliding doors on the same side can slide back and forth;

and sliding motors are fixedly arranged in the bottom surfaces of the two sliding doors and are respectively in power connection with the sliding door shafts on the same side, so that the sliding door gears can rotate.

Preferably, an oxygen supply cavity is formed in the oxygen supply box, an extrusion screw is rotatably arranged on the bottom wall of the oxygen supply cavity, an extrusion plate is in threaded connection with the periphery of the extrusion screw, an oxygen supply motor is fixedly arranged in the bottom wall of the oxygen supply cavity, the oxygen supply motor is in power connection with the extrusion screw, an oxygen delivery cavity is formed in the top surface of the oxygen supply pipe, and the top port of the oxygen delivery cavity is communicated with the oxygen supply cavity, so that oxygen in the oxygen supply cavity can be pressed into the oxygen delivery cavity through the extrusion plate;

two oxygen therapy ports are formed in the left wall of the oxygen therapy cavity from top to bottom, the oxygen therapy port at the upper side is located in the breeding cavity at the upper side, the oxygen therapy port at the lower side is located in the breeding cavity at the lower side, so that oxygen in the oxygen therapy cavity can flow into the breeding cavities at the same side through the two oxygen therapy ports respectively, a breathable net is fixedly arranged between the two breeding cavities, and therefore gas in the breeding cavities at the lower side can flow upwards into the breeding cavities at the upper side through the breathable net and can be discharged through the exhaust port finally.

Preferably, a baffle is fixedly arranged on the bottom surface of the floating platform, the baffle can prevent the culture cavity in water from continuously moving rightwards, so that the culture cavity is prevented from colliding with the blades, a moving motor is fixedly arranged in the fixed block, a main rotating shaft is dynamically connected to the bottom surface of the moving motor, and the bottom surface of the main rotating shaft is inserted into the fixed cavity;

the utility model discloses a feed bin, including main pivot, left bevel gear, right bevel gear, row's material pipe bottom surface, main pivot bottom surface, main bevel gear, right bevel gear, row has seted up the material chamber on the row's material pipe bottom surface, it inserts to arrange the material chamber top port in the feedbox, thereby can make fodder in the feedbox falls into arrange the material intracavity.

The invention has the beneficial effects that: the intelligent aquaculture system is provided with the garbage collection device, garbage can be collected in the moving process of the culture platform, the operation is simple and convenient, and meanwhile, the feed in the feed box can be automatically and intermittently fed, so that the feed can be uniformly fed, and the operation is very convenient and fast;

the fish fry breeding device is characterized in that the oxygen supply box is arranged on the breeding platform, oxygen can be input into the breeding box, and accordingly the fish fry can be prevented from dying in the breeding box.

Drawings

FIG. 1 is a schematic external view of an intelligent aquaculture system of the present invention;

FIG. 2 is a schematic cross-sectional view of an intelligent aquaculture system of the present invention;

FIG. 3 is an enlarged partial schematic view of A of FIG. 2 according to the present invention;

FIG. 4 is an enlarged view of the mounting block of FIG. 2 according to the present invention;

FIG. 5 is an enlarged schematic view of the oxygen supply enclosure of FIG. 2 in accordance with the present invention;

FIG. 6 is an enlarged schematic view of the habitat of FIG. 2 of the present invention.

In the figure:

10. a floating platform; 11. a collection plate; 12. a collection chamber; 13. a concentration chamber; 14. a collection port; 15. a trash net; 16. a support bar; 17. a hoisting box; 18. a hoisting chamber; 19. a hoisting shaft; 20. a hoisting rope; 21. a breeding box; 22. a culture cavity; 23. a breathable net; 24. a sliding door cavity; 25. a sliding door; 26. a sliding door shaft; 27. a sliding door gear; 28. an oxygen supply box; 29. an oxygen supply tube; 30. an oxygen supply chamber; 31. an oxygen delivery cavity; 32. an oxygen delivery port; 33. a smooth cavity; 34. extruding the screw; 35. a pressing plate; 36. an exhaust port; 37. a baffle plate; 38. a fixed block; 39. a moving motor; 40. a main rotating shaft; 41. a main bevel gear; 42. a left rotating shaft; 43. a left bevel gear; 44. a fixed cavity; 45. pulp sheet; 46. a right rotating shaft; 47. a right bevel gear; 48. a fixing plate; 49. a discharge pipe; 50. a discharge chamber; 51. a feed 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. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-6, an intelligent aquaculture system according to an embodiment of the present invention, comprises a floating platform 10, the floating platform 10 can float on the water surface, a smooth cavity 33 is arranged on the top surface of the floating platform 10, the smooth cavity 33 is internally provided with a culture box 21 which extends upwards in a sliding way, the culture box 21 is used for containing the fry, an oxygen supply box 28 is fixedly arranged on the top surface of the culture box 21, oxygen is stored in the oxygen supply box 28, an oxygen supply pipe 29 is fixedly arranged on the bottom surface of the oxygen supply box 28, the bottom surface of the oxygen supply pipe 29 is inserted into the culture box 21, so that the oxygen in the oxygen supply box 28 can flow into the cultivation box 21 through the oxygen supply pipe 29, therefore, oxygen can be provided for the fry in the cultivation box 21, two symmetrical air outlets 36 are formed in the top surface of the cultivation box 21, and the air outlets 36 are used for exhausting air in the cultivation box 21;

a fixed block 38 is fixedly arranged on the bottom surface of the floating platform 10, a fixed cavity 44 is formed in the fixed block 38, a left bevel gear 43 and a right bevel gear 47 are rotationally arranged in the fixed cavity 44, a left rotating shaft 42 is fixedly arranged on the left side surface of the left bevel gear 43, three rotationally symmetric blades 45 are fixedly arranged on the periphery of the left rotating shaft 42, the floating platform 10 can slide leftwards through the blades 45, a right rotating shaft 46 is fixedly arranged on the right side surface of the right bevel gear 47, and two vertically symmetric fixed plates 48 are fixedly arranged on the periphery of the right rotating shaft 46;

float and fixedly on the platform 10 and be equipped with row material pipe 49, row material pipe 49 runs through float and float platform 10 top surface, arrange and fixedly on the material pipe 49 top surface and be equipped with feedbox 51, the fodder is equipped with in the feedbox 51, and fodder in the feedbox 51 can be followed row material pipe 49 bottom port drops out, two fixed plate 48 all is used for the shutoff row material pipe 49 bottom port.

Optionally, a collecting plate 11 is fixedly arranged on the left side surface of the floating platform 10, the collecting plate 11 is used for collecting garbage located on the left side of the collecting plate 11 in a centralized manner, a collecting cavity 12 is formed in the left side surface of the collecting plate 11, a concentrating cavity 13 is formed in the right wall of the collecting cavity 12, and a collecting port 14 is formed in the bottom wall of the concentrating cavity 13;

the fixed rubbish net 15 that is equipped with on the floating platform 10 bottom surface, rubbish net 15 is used for loading rubbish, rubbish net 15 top port with collect 14 bottom port intercommunication, thereby rubbish in the collection chamber 12 pass through concentrated chamber 13 with collect 14 rivers and flow in can following the rubbish net 15 in, when floating platform 10 moves left, collecting plate 11 also can move left, thereby can make and be located the left rubbish of collecting plate 11 gets into collect chamber 12, thereby can make the rubbish in the collection chamber 12 follow rivers and flow in concentrated chamber 13.

Optionally, four rotationally symmetric support rods 16 are fixedly arranged on the top surface of the floating platform 10, a hoisting box 17 is fixedly arranged on the upper side of the floating platform 10, the top ends of the four support rods 16 are fixed to the outer peripheral surface of the hoisting box 17, a hoisting cavity 18 is formed in the hoisting box 17, and a hoisting shaft 19 is rotatably arranged on the inner wall of the hoisting cavity 18;

the periphery of the winding shaft 19 is wound with a winding rope 20, the lower end of the winding rope 20 is fixed with the top surface of the culture box 21, so that the culture box 21 entering water can be pulled back upwards into the smooth cavity 33 through the winding rope 20, the inner wall of the winding cavity 18 is internally and fixedly provided with a rotating motor, the rotating motor is in power connection with the winding shaft 19, and the rotating motor is started to rotate the winding shaft 19.

Optionally, two vertically symmetrical culture cavities 22 are formed in the culture box 21, sliding doors 25 are slidably arranged in the left walls of the two culture cavities 22, and the two sliding doors 25 can respectively prevent the fry from migrating to the left from the culture cavities 22 on the same side;

two sliding door cavities 24 which are symmetrical up and down are formed in the left walls of the two breeding cavities 22, the two sliding door cavities 24 are formed in a way that the upper side surface and the lower side surface of each sliding door 25 are respectively inserted into the sliding door cavities 24 on the same side, so that the sliding doors 25 can only slide in the front-back direction, sliding door shafts 26 are respectively and rotatably arranged in the bottom surfaces of the two sliding doors 25, sliding door gears 27 are respectively and fixedly arranged on the peripheries of the two sliding door shafts 26, and the peripheral surfaces of the two sliding door gears 27 are respectively meshed with the bottom walls of the sliding door cavities 24 on the same side, so that the sliding doors 25 on the same side can slide back and forth;

two sliding motors are fixedly arranged in the bottom surfaces of the two sliding doors 25 and are respectively in power connection with the sliding door shafts 26 on the same side, so that the sliding door gears 27 can rotate, and the sliding motors are turned on to rotate the sliding door shafts 26.

Optionally, an oxygen supply cavity 30 is formed in the oxygen supply box 28, an extrusion screw 34 is rotatably arranged on the bottom wall of the oxygen supply cavity 30, an extrusion plate 35 is connected to the periphery of the extrusion screw 34 in a threaded manner, an oxygen supply motor is fixedly arranged in the bottom wall of the oxygen supply cavity 30, the oxygen supply motor is in power connection with the extrusion screw 34, an oxygen supply cavity 31 is formed in the top surface of the oxygen supply pipe 29, and the top end of the oxygen supply cavity 31 is communicated with the oxygen supply cavity 30, so that oxygen in the oxygen supply cavity 30 can be pressed into the oxygen supply cavity 31 through the extrusion plate 35;

two oxygen therapy mouth 32 have been seted up from last down on the oxygen therapy chamber 31 left wall, the upside oxygen therapy mouth 32 is located the upside breed in the chamber 22, the downside oxygen therapy mouth 32 is located the downside breed in the chamber 22, thereby oxygen in the oxygen therapy chamber 31 passes through two oxygen therapy mouth 32 can flow into the homonymy respectively breed in the chamber 22, two it is fixed between the chamber 22 to breed to be equipped with ventilative net 23, thereby the downside breed the gas in the chamber 22 and pass through ventilative net 23 can upwards flow into the upside breed in the chamber 22, finally pass through gas vent 36 can discharge, open the oxygen suppliment motor, make stripper plate 35 rotates.

Optionally, a baffle 37 is fixedly arranged on the bottom surface of the floating platform 10, the baffle 37 can prevent the cultivation cavity 22 in water from continuously moving rightward, so as to prevent the cultivation cavity 22 from colliding with the pulp sheet 45, a moving motor 39 is fixedly arranged in the fixed block 38, a main rotating shaft 40 is dynamically connected to the bottom surface of the moving motor 39, the bottom surface of the main rotating shaft 40 is inserted into the fixed cavity 44, a main bevel gear 41 is fixedly arranged on the bottom surface of the main rotating shaft 40, the outer peripheral surface of the main bevel gear 41 is meshed with the left bevel gear 43, so as to enable the left rotating shaft 42 to rotate, the outer peripheral surface of the main bevel gear 41 is meshed with the right bevel gear 47, so as to enable the right rotating shaft 46 to rotate, a discharge cavity 50 is arranged on the bottom surface of the discharge pipe 49, the top port of the discharge cavity 50 is inserted into the feed box 51, so as to enable the feed in the feed box 51 to fall into the discharge cavity 50, the moving motor 39 is turned on to rotate the main rotating shaft 40.

The invention discloses an intelligent aquaculture system, which comprises the following working procedures:

the automatic feeding function:

placing the floating platform 10 on the water surface, turning on the moving motor 39 to rotate the main rotating shaft 40, so that the left rotating shaft 42 and the right rotating shaft 46 can be simultaneously rotated, and the three paddles 45 can be driven to rotate together by the left rotating shaft 42, so that the floating platform 10 can slide leftwards on the water surface;

meanwhile, the two fixing plates 48 can be driven to rotate together through the right rotating shaft 46, when the fixing plates 48 are abutted against the bottom surface of the discharge pipe 49, the feed in the discharge cavity 50 cannot fall out from the bottom end opening of the discharge cavity 50, and when the fixing plates 48 are not abutted against the bottom surface of the discharge pipe 49, the feed in the discharge cavity 50 can fall into water through the bottom end opening of the discharge cavity 50;

therefore, in the process that the fixing plate 48 rotates along with the right rotating shaft 46, the feed in the feed box 51 can intermittently fall into the water, so that the feed can be automatically and uniformly fed in the moving process of the floating platform 10.

Collecting garbage:

when the floating platform 10 slides leftwards, the collecting plate 11 also slides leftwards, so that the garbage on the left side of the collecting plate 11 can enter the collecting cavity 12, and the garbage in the collecting cavity 12 can flow into the collecting cavity 13 along with water flow, so that the garbage and the water flow can flow into the garbage net 15 through the collecting port 14, finally the water flow flows back through the garbage net 15, and the garbage is left in the garbage net 15, so that the garbage in the water can be collected and treated.

Fry throwing function:

placing two groups of fish fries in the two culture cavities 22 respectively, starting the oxygen supply motor, rotating the extrusion screw 34, so that the extrusion plate 35 can slide downwards, oxygen in the extrusion plate 35 can be pressed into the oxygen delivery cavity 31 through the extrusion plate 35, and finally the oxygen in the oxygen delivery cavity 31 can flow into the culture cavities 22 through the air permeable net 23, so that the fish fries in the culture cavities 22 can be supplied with oxygen, oxygen deficiency of the fish fries is prevented, and gas in the culture cavities 22 can be discharged through the exhaust ports 36;

until the floating platform 10 moves to a first throwing point, the rotating motor is started to rotate the hoisting shaft 19, so that the culture box 21 can fall downwards into the water due to the action of gravity, and the culture box 21 can pull the bottom end of the hoisting rope 20 to move downwards until the culture box 21 completely enters the water;

then, the sliding motor on the upper side is started to enable the sliding door shaft 26 on the upper side to rotate, so that the sliding door gear 27 on the upper side can rotate, the sliding door 25 on the upper side can slide backwards, so that the fry in the culture cavity 22 on the upper side can flow into water, the fry throwing on the first throwing point is completed, then the rotating motor is started to enable the winch shaft 19 to rotate reversely, so that the culture box 21 can slide upwards to an initial position;

then, the floating platform 10 is moved to a second throwing point through the paddles 45, the rotating motor is started to make the culture box 21 slide downwards into the water until the culture box 21 completely enters the water, the sliding motor on the lower side is started to make the sliding door shaft 26 on the lower side rotate, so that the sliding door gear 27 on the lower side can be rotated, the sliding door 25 on the lower side can be made to slide backwards, the fry in the culture cavity 22 on the lower side can be made to enter the water, and the fry throwing on the second throwing point is completed.

It will be apparent to those skilled in the art that various modifications may be made to the above embodiments without departing from the general spirit and concept of the invention. All falling within the scope of protection of the present invention. The protection scheme of the invention is subject to the appended claims.

Claims

1. An intelligent aquaculture system, comprising a floating platform (10), characterized in that: the floating platform (10) can float on the water surface, a smooth cavity (33) is formed in the top surface of the floating platform (10), an upwards extending cultivation box (21) is arranged in the smooth cavity (33) in a sliding mode, an oxygen supply box (28) is fixedly arranged on the top surface of the cultivation box (21), oxygen is stored in the oxygen supply box (28), an oxygen supply pipe (29) is fixedly arranged on the bottom surface of the oxygen supply box (28), the bottom surface of the oxygen supply pipe (29) is inserted into the cultivation box (21), and two air exhaust ports (36) which are symmetrical left and right are formed in the top surface of the cultivation box (21);

a fixed block (38) is fixedly arranged on the bottom surface of the floating platform (10), a fixed cavity (44) is formed in the fixed block (38), a left bevel gear (43) and a right bevel gear (47) are rotatably arranged in the fixed cavity (44), a left rotating shaft (42) is fixedly arranged on the left side surface of the left bevel gear (43), three rotationally symmetrical blades (45) are fixedly arranged on the periphery of the left rotating shaft (42), a right rotating shaft (46) is fixedly arranged on the right side surface of the right bevel gear (47), and two vertically symmetrical fixed plates (48) are fixedly arranged on the periphery of the right rotating shaft (46);

float and be equipped with on platform (10) fixedly and arrange material pipe (49), it runs through to arrange material pipe (49) float platform (10) top surface, it is fixed on material pipe (49) top surface and is equipped with feedbox (51), the fodder is equipped with in feedbox (51).

2. An intelligent aquaculture system according to claim 1 wherein: a collecting plate (11) is fixedly arranged on the left side surface of the floating platform (10), the collecting plate (11) is used for collecting garbage located on the left side of the collecting plate (11) in a centralized manner, a collecting cavity (12) is formed in the left side surface of the collecting plate (11), a centralized cavity (13) is formed in the right wall of the collecting cavity (12), and a collecting opening (14) is formed in the bottom wall of the centralized cavity (13);

the floating platform is characterized in that a garbage net (15) is fixedly arranged on the bottom surface of the floating platform (10), the garbage net (15) is used for loading garbage, and a top port of the garbage net (15) is communicated with a bottom port of the collection port (14).

3. An intelligent aquaculture system according to claim 2 wherein: four rotationally symmetrical support rods (16) are fixedly arranged on the top surface of the floating platform (10), a hoisting box (17) is fixedly arranged on the upper side of the floating platform (10), the top ends of the four support rods (16) are fixed with the outer peripheral surface of the hoisting box (17), a hoisting cavity (18) is formed in the hoisting box (17), and a hoisting shaft (19) is rotatably arranged on the inner wall of the hoisting cavity (18);

the device is characterized in that a hoisting rope (20) is wound on the periphery of the hoisting shaft (19), the lower end of the hoisting rope (20) is fixed to the top surface of the culture box (21), a rotating motor is fixedly arranged in the inner wall of the hoisting cavity (18), and the rotating motor is in power connection with the hoisting shaft (19).

4. An intelligent aquaculture system according to claim 3 wherein: breed the breed chamber (22) that has seted up two longitudinal symmetries in case (21), two it all slides in the chamber (22) left wall and is equipped with sliding door (25), two all seted up two longitudinal symmetries's sliding door chamber (24) in breeding chamber (22) left wall, two are that sliding door (25) upper and lower both sides face inserts respectively the homonymy in sliding door chamber (24).

5. An intelligent aquaculture system according to claim 4 wherein: sliding door shafts (26) are rotatably arranged in the bottom surfaces of the two sliding doors (25), sliding door gears (27) are fixedly arranged on the peripheries of the two sliding door shafts (26), and the peripheral surfaces of the two sliding door gears (27) are respectively meshed with the bottom walls of the sliding door cavities (24) on the same side;

and sliding motors are fixedly arranged in the bottom surfaces of the two sliding doors (25), and the two sliding motors are respectively in power connection with the sliding door shafts (26) on the same side.

6. An intelligent aquaculture system according to claim 5 wherein: an oxygen supply cavity (30) is formed in the oxygen supply box (28), an extrusion screw rod (34) is rotatably arranged on the bottom wall of the oxygen supply cavity (30), an extrusion plate (35) is connected to the periphery of the extrusion screw rod (34) in a threaded manner, an oxygen supply motor is fixedly arranged in the bottom wall of the oxygen supply cavity (30), the oxygen supply motor is in power connection with the extrusion screw rod (34), an oxygen supply cavity (31) is formed in the top surface of the oxygen supply pipe (29), and the top port of the oxygen supply cavity (31) is communicated with the oxygen supply cavity (30);

two oxygen delivery ports (32) are formed in the left wall of the oxygen delivery cavity (31) from top to bottom, the oxygen delivery port (32) on the upper side is located in the breeding cavity (22) on the upper side, the oxygen delivery port (32) on the lower side is located in the breeding cavity (22) on the lower side, and a ventilation net (23) is fixedly arranged between the two breeding cavities (22).

7. An intelligent aquaculture system according to claim 6 wherein: a baffle (37) is fixedly arranged on the bottom surface of the floating platform (10), the baffle (37) can prevent the culture cavity (22) in water from continuously moving rightwards, a moving motor (39) is fixedly arranged in the fixed block (38), a main rotating shaft (40) is dynamically connected to the bottom surface of the moving motor (39), and the bottom surface of the main rotating shaft (40) is inserted into the fixed cavity (44);

the feed bin is characterized in that a main bevel gear (41) is fixedly arranged on the bottom surface of the main rotating shaft (40), the peripheral surface of the main bevel gear (41) is meshed with the left bevel gear (43), the peripheral surface of the main bevel gear (41) is meshed with the right bevel gear (47), a discharge cavity (50) is formed in the bottom surface of the discharge pipe (49), and a top end opening of the discharge cavity (50) is inserted into the feed bin (51).