CN220734070U - Component capable of adjusting oxygenation capacity and oxygenation ship with component - Google Patents

Abstract

The utility model discloses an assembly capable of adjusting oxygenation capacity and an oxygenation boat thereof, belonging to the field of aquaculture, and comprising the following components: the rectangular frame consists of a side plate and a mesh plate I; two mesh plates I are symmetrically and fixedly arranged between the two side plates; the rectangular frame is fixedly provided with a pontoon; the second mesh plate is fixedly connected with the bottom of the rectangular frame; the support frame is fixedly provided with a sealing box; the sealing box is fixedly provided with a first motor; the first rotating shafts are symmetrically and rotationally connected with the sealing boxes; the first rotating shaft is in gear transmission with the first motor; compared with the prior art, the assembly capable of adjusting the oxygenation capacity and the oxygenation ship thereof limit the rotation striking water surface area of the impeller and the blades in the rectangular frame, so that the impeller and the blades are prevented from damaging fish shoals; meanwhile, the number of the rotating impellers and the rotating blades can be controlled by the motor I through the unidirectional bearing.

Description

Component capable of adjusting oxygenation capacity and oxygenation ship with component

Technical Field

The utility model relates to the field of aquaculture, in particular to an assembly capable of adjusting oxygenation capacity and an oxygenation ship thereof.

Background

The waterwheel aerator is a machine which is commonly applied to fishery industry. The main function of the water-based oxygen-free fish tank is to increase the oxygen content in water so as to ensure that fish in the water cannot be anoxic, and simultaneously inhibit the growth of anaerobic bacteria in the water, thereby preventing the deterioration of pool water and threatening the living environment of fish. The structure of the aerator mainly comprises three parts, namely a motor, a pontoon and a vertical impeller, wherein the motor is started, and the vertical impeller rotates to strike the water surface to bring air into the water in the process that the motor drives the vertical impeller to rotate so as to increase the oxygen content in the water. The new energy oxygenation device provided by the application number CN202122066349.3 comprises a floating pontoon, an oxygenation machine, a water quality detector, a controller, a frequency converter and a solar power generation assembly, wherein the floating pontoon is of a hollow structure, the oxygenation machine comprises a driving motor and an impeller, the impeller is connected with the driving motor through a rotating shaft, the driving motor is arranged on the floating pontoon, the impellers are arranged on two sides of the floating pontoon, a plurality of blades are arranged on the impellers, and the blades are at least partially contacted with a water body; however, if the oxygen content around the aerator is high, the aerator attracts the fish to the side of the aerator, and the high-speed rotating vertical impeller is extremely easy to damage the fish. For this purpose, the assembly of adjustable oxygenation volume and oxygenation ship.

Disclosure of Invention

Aiming at the defects of the prior art, the utility model provides an assembly capable of adjusting the oxygenation capacity and an oxygenation ship thereof, and the rotation striking water surface area of an impeller and blades is limited in a rectangular frame, so that the impeller and the blades are prevented from damaging fish shoals; meanwhile, the number of the rotating impellers and the rotating blades can be controlled by the motor I through the unidirectional bearing.

The aim of the utility model can be achieved by the following technical scheme:

an assembly for adjusting oxygenation capacity and an oxygenation vessel thereof, comprising:

the rectangular frame consists of a side plate and a mesh plate I; two mesh plates I are symmetrically and fixedly arranged between the two side plates; the rectangular frame is fixedly provided with a pontoon;

the second mesh plate is fixedly connected with the bottom of the rectangular frame;

the support frame is fixedly provided with a sealing box; the sealing box is fixedly provided with a first motor;

the first rotating shafts are symmetrically and rotationally connected with the sealing boxes; the first rotating shaft is in gear transmission with the first motor;

the second rotating shaft is symmetrically and rotatably connected with the rectangular frame; the second rotating shafts are respectively and rotatably connected with one first rotating shaft through a one-way bearing; when the motor I drives the rotating shaft I to rotate positively, the rotating shaft II cannot rotate along with the rotating shaft I under the action of the unidirectional bearing; when the motor I rotates reversely, the rotating shaft rotates along with the rotating shaft I under the action of the unidirectional bearing;

an impeller, the circumference of which is fixedly provided with blades; through holes are uniformly distributed on the blades, and when the impeller drives the blades to strike the water surface, part of water passes through the through holes and is struck by the blades, so that a water film is formed; the impeller is arranged on the first rotating shaft and the second rotating shaft.

When in use, the rectangular frame is moved into water and then fixed on objects such as a pool, a ship, a pole and the like; then, the motor I is started, the motor I drives the rotating shaft I to rotate positively, the rotating shaft II rotates relative to the rotating shaft I under the action of the unidirectional bearing, at the moment, only the impeller on the rotating shaft I drives the blades to rotate, and the blades strike the water surface to bring air into the water, so that the oxygen content in the water is increased; when the force is required to be increased, the motor I rotates reversely, and under the action of the unidirectional bearing, the rotating shaft II is fixed relative to the rotating shaft I, namely the rotating shaft II rotates along with the rotating shaft I, and at the moment, the rotating shaft II and the impeller on the rotating shaft I both rotate, so that the oxygenation capacity is improved; since the blades are positioned in the rectangular frame, the rectangular frame is used for water inflow through the mesh plate, so that the fish shoals are prevented from being attracted to the blades.

The noun, conjunctive or adjective parts referred to in the above technical solutions are explained as follows:

the term fixedly connected in this application refers to a connection without any relative movement after the parts or components are installed; the common way is to fix the parts together by using screw, spline, wedge pin, etc., the connection way can be disassembled during maintenance and the parts can not be damaged, and the way can also be called as detachable fixed connection; in addition, the parts and components can not be used secondarily in such a way as welding, riveting, tenon passing and matching and the like, and the parts and components can not be disassembled in the way of forging, sawing or oxygen cutting during maintenance or replacement. The rotating connection in the application is a connection that after parts or components are installed, the parts generate relative rotation motion relative to a fixing piece, and the common form is that the bearings are installed on the fixing piece, the parts are installed on the inner ring or the outer ring of the bearings, and the bearings are utilized to complete the rotation motion. The sliding connection in the present application is a connection in which a part or a component can be moved on a fixing member after the part or the component is mounted.

In some embodiments, the rectangular frame is symmetrically provided with sliding grooves; the second mesh plate is in sliding connection with the sliding chute; the second mesh plate is fixedly provided with a fixed block; limiting grooves are symmetrically formed in the fixed blocks; a limiting seat is fixedly arranged on one side of the rectangular frame, which is close to the limiting groove; the limiting seat is provided with a first limiting hole and a second limiting hole; the first limiting hole is communicated with the second limiting hole; the first limiting hole is connected with a limiting rod in a sliding manner; the limiting rod is fixedly provided with a limiting column; the limiting column is in sliding connection with the second limiting hole; the limiting rod is sleeved with a spring between the second limiting hole and the limiting column; the spring abuts against the limiting post, and the limiting rod abuts against the limiting groove.

In some embodiments, the stop lever is fixedly mounted with a handle; the rectangular frame is provided with a clamping seat at the upper end of the handle; the clamping seat is provided with a groove; the groove is provided with a first magnet; a magnet II is arranged in the handle; the handle and the groove are attracted.

In some embodiments, the first motor is fixedly provided with a first bevel gear; the first rotating shaft is fixedly provided with a bevel gear II; the first bevel gear is meshed with the second bevel gear.

In some embodiments, the rectangular frame is fixedly provided with a second supporting seat; the sealing box is fixedly provided with a first supporting seat; the first rotating shaft is rotationally connected with the supporting seat; the second rotating shaft is rotationally connected with the second supporting seat.

In some embodiments, a solar panel is fixedly arranged at the upper end of the rectangular frame; a battery is fixedly arranged in the sealing box; the battery is electrically connected with the solar panel and the motor.

In some embodiments, the bottom of the rectangular frame is fixedly provided with a rope; the rope is provided with a positioning column.

The application also discloses an oxygenation vessel, at least one component capable of adjusting oxygenation capacity is fixedly arranged on the oxygenation vessel.

The utility model has the beneficial effects that:

according to the component capable of adjusting the oxygenation capacity and the oxygenation boat thereof, the rotation striking water surface area of the impeller and the blades is limited in the rectangular frame, so that the impeller and the blades are prevented from damaging fish shoals; meanwhile, the number of the rotating impellers and the rotating blades can be controlled by the motor I through the unidirectional bearing.

Drawings

The utility model is further described below with reference to the accompanying drawings.

FIG. 1 is a schematic perspective view of the present application;

FIG. 2 is a schematic view of the interior of the seal box of the present application;

FIG. 3 is a schematic view of the bottom structure of the present application;

FIG. 4 is a schematic view of a partial enlarged structure of the present application;

fig. 5 is a schematic diagram of an internal structure of the limiting seat of the present application.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

In the description of the present utility model, it should be understood that the terms "open," "upper," "lower," "thickness," "top," "middle," "length," "inner," "peripheral," and the like indicate orientation or positional relationships, merely for convenience in describing the present utility model and to simplify the description, and do not indicate or imply that the components or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present utility model.

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

According to the component capable of adjusting the oxygenation capacity and the oxygenation boat thereof, the rotation striking water surface area of the impeller and the blades is limited in the rectangular frame, so that the impeller and the blades are prevented from damaging fish shoals; meanwhile, the number of the rotating impellers and the rotating blades can be controlled by the motor I through the unidirectional bearing.

Referring to fig. 1 to 5, an assembly for adjusting oxygenation capacity and an oxygenation vessel thereof, comprising:

the rectangular frame consists of a side plate 1 and a mesh plate I2; two mesh plates I2 are symmetrically and fixedly arranged between the two side plates 1; the rectangular frame is fixedly provided with a pontoon 3;

the second mesh plate 4 is fixedly connected with the bottom of the rectangular frame;

a support frame fixedly provided with a seal box 5; the sealing box 5 is fixedly provided with a motor I6;

the first rotating shafts 7, and the sealing boxes 5 are symmetrically and rotationally connected with the two first rotating shafts 7; the first rotating shaft 7 and the first motor 6 are driven by gears;

the second rotating shaft 8 is symmetrically and rotatably connected with the rectangular frame; the second rotating shafts 8 are respectively and rotatably connected with the first rotating shaft 7 through unidirectional bearings; when the motor I6 drives the rotating shaft I7 to rotate positively, the rotating shaft II 8 cannot rotate along with the rotating shaft I7 under the action of the unidirectional bearing; when the motor I6 rotates reversely, the rotating shaft rotates along with the rotating shaft I7 under the action of the unidirectional bearing;

an impeller 9 having blades 10 fixedly mounted on the circumference thereof; through holes 11 are uniformly distributed on the blades 10, and when the impeller 9 drives the blades 10 to strike the water surface, part of water passes through the through holes 11 and is struck by the blades 10, so that a water film is formed; the first rotating shaft 7 and the second rotating shaft 8 are both provided with impellers 9.

When in use, the rectangular frame is moved into water and then fixed on objects such as a pool, a ship, a pole and the like; then, the motor I6 is started, the motor I6 drives the rotating shaft I7 to rotate positively, the rotating shaft II 8 rotates relative to the rotating shaft I7 under the action of the unidirectional bearing, at the moment, only the impeller 9 on the rotating shaft I7 drives the blades 10 to rotate, and the blades 10 strike the water surface to bring air into water so as to increase the content of oxygen in the water; when the force is required to be increased, the motor I6 reversely rotates, and under the action of the unidirectional bearing, the rotating shaft II 8 is fixed relative to the rotating shaft I7, namely the rotating shaft II 8 rotates along with the rotating shaft I7, and at the moment, the rotating shaft II 8 and the impeller 9 on the rotating shaft I7 both rotate, so that the oxygenation capacity is improved; since the blades 10 are located in a rectangular frame, the rectangular frame is fed with water through the mesh plate, thereby avoiding that the fish are attracted to the blades 10.

A one-way bearing in this application is a bearing that is free to rotate in one direction and to lock in the other direction. The one-way bearing is also called an overrunning clutch, and is named according to different industries and different roles. The metal shell of the unidirectional bearing comprises a plurality of rolling shafts, rolling pins or rolling balls, and the rolling seat is shaped so that the unidirectional bearing can roll only in one direction and can generate great resistance in the other direction;

gear transmission in this application refers to a device for transmitting motion and power by a gear pair, and is one of the most widely used mechanical transmission modes in various modern devices. The device has the advantages of accurate transmission, high efficiency, compact structure, reliable work and long service life; common forms are transmission through a pair of meshed spur gears or bevel gears, wherein the spur gears are used for parallel two-shaft transmission, and the bevel gears can be used for non-parallel two-shaft transmission;

the seal box 5 refers to a box body structure for preventing external media from entering the interior of the seal box 5; the common forms are that rubber sealing rings are added on the box body and the box cover for protection; the seal box 5 is mainly used for waterproofing;

the mesh plate is formed by punching, shearing, stretching or punching steel plates made of various materials, and the surface of the mesh plate is provided with various hole patterns; the mesh of the mesh plate is provided with rectangular holes, diamond holes, round holes, hexagonal holes, cross holes, triangular holes, long round holes, long waist holes, plum blossom holes, fish scale holes, pattern holes, pentagram holes, irregular holes and bulge holes.

In some embodiments, the rectangular frame is symmetrically provided with sliding grooves; the second mesh plate 4 is connected with the chute in a sliding way; the second mesh plate 4 is fixedly provided with a fixed block 12; limiting grooves are symmetrically formed in the fixed block 12; a limit seat 13 is fixedly arranged on one side of the rectangular frame, which is close to the limit groove; the limiting seat 13 is provided with a first limiting hole 14 and a second limiting hole 15; the first limiting hole 14 is communicated with the second limiting hole 15; the first limiting hole 14 is connected with a limiting rod 16 in a sliding manner; the limiting rod 16 is fixedly provided with a limiting column 17; the limiting column 17 is in sliding connection with the limiting hole II 15; the limiting rod 16 is sleeved with a spring 18 between the limiting hole II 15 and the limiting column 17; the spring 18 butts against the limit post 17, and the limit rod 16 butts against the limit groove;

the second mesh plate 4 is positioned at the bottom and horizontally placed, and is easy to attach objects at the upper end of the second mesh plate 4, so that the weight of the second mesh plate 4 is increased; therefore, the second mesh plate 4 needs to be cleaned, the limiting rod 16 can be pulled out of the limiting groove by pulling the limiting rod 16, the fixing block 12 is not locked at this time, and the second mesh plate 4 is pulled out for cleaning and replacement; after the replacement is finished, the mesh plate II 4 is reset, the limiting rod 16 is pulled, and under the action of the spring 18, the spring 18 props against the limiting post 17, so that the limiting rod 16 props against the limiting groove.

In some embodiments, the stop lever 16 is fixedly mounted with a handle 19; the rectangular frame is provided with a clamping seat 20 at the upper end of the handle 19; the clamping seat 20 is provided with a groove 21; the groove 21 is provided with a first magnet; a second magnet is arranged inside the handle 19; the handle 19 and the groove 21 are attracted; the limiting rod 16 can be pulled by the handle 19, and after the limiting rod 16 is pulled out, the handle 19 is inserted into the groove 21, and the spring 18 is restrained at the moment, so that the second mesh plate 4 can be conveniently taken out.

In some embodiments, motor one 6 is fixedly mounted with bevel gear one 22; the first rotating shaft 7 is fixedly provided with a bevel gear II 23; bevel gear one 22 meshes with bevel gear two 23; the motor I6 drives the bevel gear II 23 to rotate through the bevel gear I22, so that the rotating shaft I7 is driven to rotate.

In some embodiments, the rectangular frame is fixedly provided with a second supporting seat; the sealing box 5 is fixedly provided with a first supporting seat; the first rotating shaft 7 is rotationally connected with the supporting seat; the second rotating shaft 8 is rotationally connected with the second supporting seat; the two supporting seats are used for increasing the supporting force of the rotating shaft.

In some embodiments, solar panels 24 are fixedly secured to the upper ends of the rectangular frames; a battery 25 is fixedly arranged in the sealing box 5; the battery 25 is electrically connected with the solar panel 24 and the motor I6; the solar panel 24 is used for converting solar energy into electric energy, the converted electric energy is stored through the battery 25 to supply power to the motor I6, and compared with a traditional aerator which is connected with an upper power supply through a cable, the aerator is free of limitation, can meet the aeration requirement of the whole farm, and is more flexible to use.

In some embodiments, the bottom of the rectangular frame is fixedly provided with a rope; the rope is provided with a positioning column; the positioning column can be inserted into the bottom of the pool to fix, so that the heavy wind is prevented from blowing over.

The application also discloses an oxygenation vessel, at least one component capable of adjusting oxygenation capacity is fixedly arranged on the oxygenation vessel.

The assembly capable of adjusting oxygenation and the oxygenation boat thereof provided by the utility model are further described below with reference to the accompanying drawings and the embodiments.

An assembly for adjusting oxygenation capacity and an oxygenation vessel thereof, comprising:

the rectangular frame consists of a side plate 1 and a mesh plate I2; two mesh plates I2 are symmetrically and fixedly arranged between the two side plates 1; the rectangular frame is fixedly provided with a pontoon 3;

a second mesh plate 4; the rectangular frame is symmetrically provided with sliding grooves; the second mesh plate 4 is connected with the chute in a sliding way; the second mesh plate 4 is fixedly provided with a fixed block 12; limiting grooves are symmetrically formed in the fixed block 12; a limit seat 13 is fixedly arranged on one side of the rectangular frame, which is close to the limit groove; the limiting seat 13 is provided with a first limiting hole 14 and a second limiting hole 15; the first limiting hole 14 is communicated with the second limiting hole 15; the first limiting hole 14 is connected with a limiting rod 16 in a sliding manner; the limiting rod 16 is fixedly provided with a limiting column 17; the limiting column 17 is in sliding connection with the limiting hole II 15; the limiting rod 16 is sleeved with a spring 18 between the limiting hole II 15 and the limiting column 17; the spring 18 butts against the limit post 17, and the limit rod 16 butts against the limit groove;

the second mesh plate 4 is positioned at the bottom and horizontally placed, and is easy to attach objects at the upper end of the second mesh plate 4, so that the weight of the second mesh plate 4 is increased; therefore, the second mesh plate 4 needs to be cleaned, the limiting rod 16 can be pulled out of the limiting groove by pulling the limiting rod 16, the fixing block 12 is not locked at this time, and the second mesh plate 4 is pulled out for cleaning and replacement; after the replacement is finished, the mesh plate II 4 is reset, the limiting rod 16 is pulled, and under the action of the spring 18, the spring 18 props against the limiting post 17, so that the limiting rod 16 props against the limiting groove. The limiting rod 16 is fixedly provided with a handle 19; the rectangular frame is provided with a clamping seat 20 at the upper end of the handle 19; the clamping seat 20 is provided with a groove 21; the groove 21 is provided with a first magnet; a second magnet is arranged inside the handle 19; the handle 19 and the groove 21 are attracted; the limiting rod 16 can be pulled by the handle 19, and after the limiting rod 16 is pulled out, the handle 19 is inserted into the groove 21, and the spring 18 is restrained at the moment, so that the second mesh plate 4 can be conveniently taken out.

A support frame fixedly provided with a seal box 5; the sealing box 5 is fixedly provided with a motor I6;

the first rotating shafts 7, and the sealing boxes 5 are symmetrically and rotationally connected with the two first rotating shafts 7; the motor I6 is fixedly provided with a bevel gear I22; the first rotating shaft 7 is fixedly provided with a bevel gear II 23; bevel gear one 22 meshes with bevel gear two 23; the motor I6 drives the bevel gear II 23 to rotate through the bevel gear I22, so that the rotating shaft I7 is driven to rotate;

the second rotating shaft 8 is symmetrically and rotatably connected with the rectangular frame; the second rotating shafts 8 are respectively and rotatably connected with the first rotating shaft 7 through unidirectional bearings; when the motor I6 drives the rotating shaft I7 to rotate positively, the rotating shaft II 8 cannot rotate along with the rotating shaft I7 under the action of the unidirectional bearing; when the motor I6 rotates reversely, the rotating shaft rotates along with the rotating shaft I7 under the action of the unidirectional bearing;

an impeller 9 having blades 10 fixedly mounted on the circumference thereof; through holes 11 are uniformly distributed on the blades 10, and when the impeller 9 drives the blades 10 to strike the water surface, part of water passes through the through holes 11 and is struck by the blades 10, so that a water film is formed; the first rotating shaft 7 and the second rotating shaft 8 are both provided with impellers 9.

When in use, the rectangular frame is moved into water and then fixed on objects such as a pool, a ship, a pole and the like; then, the motor I6 is started, the motor I6 drives the rotating shaft I7 to rotate positively, the rotating shaft II 8 rotates relative to the rotating shaft I7 under the action of the unidirectional bearing, at the moment, only the impeller 9 on the rotating shaft I7 drives the blades 10 to rotate, and the blades 10 strike the water surface to bring air into water so as to increase the content of oxygen in the water; when the force is required to be increased, the motor I6 reversely rotates, and under the action of the unidirectional bearing, the rotating shaft II 8 is fixed relative to the rotating shaft I7, namely the rotating shaft II 8 rotates along with the rotating shaft I7, and at the moment, the rotating shaft II 8 and the impeller 9 on the rotating shaft I7 both rotate, so that the oxygenation capacity is improved; since the blades 10 are located in a rectangular frame, the rectangular frame is fed with water through the mesh plate, thereby avoiding that the fish are attracted to the blades 10.

The foregoing has shown and described the basic principles, principal features and advantages of the utility model. It will be understood by those skilled in the art that the present utility model is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present utility model, and various changes and modifications may be made without departing from the spirit and scope of the utility model, which is defined in the appended claims.

Claims (8)

1. An assembly for regulating oxygenation, comprising:

the rectangular frame consists of a side plate (1) and a first mesh plate (2); two mesh plates I (2) are symmetrically and fixedly arranged between the two side plates (1); the rectangular frame is fixedly provided with a pontoon (3);

the second mesh plate (4) is fixedly connected with the bottom of the rectangular frame;

a support frame fixedly provided with a sealing box (5); the sealing box (5) is fixedly provided with a first motor (6);

the first rotating shafts (7), and the sealing boxes (5) are symmetrically and rotationally connected with the two first rotating shafts (7); the first rotating shaft (7) and the first motor (6) are in gear transmission;

the second rotating shafts (8) are symmetrically and rotatably connected with the rectangular frame; the second rotating shaft (8) is respectively and rotatably connected with one first rotating shaft (7) through a one-way bearing;

an impeller (9) having blades (10) fixedly mounted on the circumference thereof; through holes (11) are uniformly distributed in the blades (10); the impeller (9) is arranged on the first rotating shaft (7) and the second rotating shaft (8).

2. The assembly for adjusting oxygenation according to claim 1, wherein the rectangular frame is symmetrically provided with sliding grooves; the second mesh plate (4) is in sliding connection with the sliding groove; the second mesh plate (4) is fixedly provided with a fixed block (12); limiting grooves are symmetrically formed in the fixed blocks (12); a limiting seat (13) is fixedly arranged on one side of the rectangular frame, which is close to the limiting groove; the limiting seat (13) is provided with a first limiting hole (14) and a second limiting hole (15); the first limiting hole (14) is communicated with the second limiting hole (15); the first limiting hole (14) is connected with a limiting rod (16) in a sliding manner; the limiting rod (16) is fixedly provided with a limiting column (17); the limiting column (17) is in sliding connection with the limiting hole II (15); the limiting rod (16) is sleeved with a spring (18) between the limiting hole II (15) and the limiting column (17); the spring (18) is propped against the limit post (17), and the limit rod (16) is propped against the limit groove.

3. The assembly with adjustable oxygenation according to claim 2, wherein the limit lever (16) is fixedly provided with a handle (19); the rectangular frame is provided with a clamping seat (20) at the upper end of the handle (19); the clamping seat (20) is provided with a groove (21); the groove (21) is provided with a first magnet; a magnet II is arranged in the handle (19); the handle (19) and the groove (21) are attracted.

4. An assembly according to claim 3, wherein the first motor (6) is fixedly provided with a first bevel gear (22); the first rotating shaft (7) is fixedly provided with a bevel gear II (23); the bevel gear I (22) is meshed with the bevel gear II (23).

5. The assembly capable of adjusting oxygenation according to claim 4, wherein the rectangular frame is fixedly provided with a second supporting seat; the sealing box (5) is fixedly provided with a first supporting seat; the first rotating shaft (7) is rotationally connected with the supporting seat; the second rotating shaft (8) is rotationally connected with the second supporting seat.

6. The assembly for adjusting oxygenation according to claim 5, wherein a solar panel (24) is fixedly arranged at the upper end of the rectangular frame; a battery (25) is fixedly arranged in the sealing box (5); the battery (25) is electrically connected with the solar panel (24) and the motor I (6).

7. The assembly for adjusting oxygenation according to claim 6, wherein a rope is fixedly installed at the bottom of the rectangular frame; the rope is provided with a positioning column.

8. An oxygenation vessel having at least one oxygenation adjustable assembly of any of claims 1-7 fixedly mounted thereto.