CN217905856U - Floatable aquaculture aerator - Google Patents

Abstract

The utility model is suitable for the technical field of aquaculture, and provides a floatable aquaculture aerator, which comprises a first floating cabin, a second floating cabin, a first driving shaft, a second driving shaft, a first driving motor, a second driving motor and a connecting frame, wherein the first floating cabin is fixed on the second floating cabin through the connecting frame, so that the two floating cabins form a whole, and meanwhile, the first floating cabin and the second floating cabin are filled with gas, so that the aerator can float on the water surface conveniently and is suitable for the field of aquaculture; the first driving shaft and the second driving shaft driven by the motor are respectively provided with a plurality of first blades and second blades, the water surface is turned through the blades, then the underwater oxygen increasing is carried out, when the first driving shaft and the second driving shaft rotate in opposite directions, the oxygen increasing machine stays on the water surface, when the first driving shaft and the second driving shaft rotate in the same direction, the oxygen increasing machine is driven to move on the water, the oxygen increasing operation can be carried out at different positions, and the efficiency is higher; the oxygen increasing machine is convenient to operate, and the oxygen increasing efficiency can be further improved through the oxygen increasing pump.

Description

Floatable aquaculture aerator

Technical Field

The utility model belongs to the technical field of aquaculture, especially, relate to a floatable aquaculture oxygen-increasing machine.

Background

In the current technical field of aquaculture, the aquaculture industry uses water areas available for human cultivation (including planting) to carry out aquatic economic animal and plant cultivation by applying aquaculture technology and facilities according to the ecological habits of cultivation objects and the requirements on the environmental conditions of the water areas, wherein an oxygen aerator is an essential device in the aquaculture and mainly used for increasing the oxygen content in water to ensure that fish in the water cannot lack oxygen, and simultaneously can inhibit the growth of anaerobic bacteria in the water to prevent pond water from deteriorating to threaten the living environment of the fish.

At present, floating aquaculture oxygen increasing machines on the market mostly float by using floating balls, for example, an automatic control oxygen increasing machine is proposed in (CN 102948392B), wherein a plastic floating ball is floated on the water surface for oxygen increasing operation;

although the method can enable the aerator to stay on the water surface, the movement is inconvenient, the aeration efficiency is insufficient, the aerator cannot be suitable for operation in a large water area, a plurality of machines are required to work simultaneously, and the use cost is high.

SUMMERY OF THE UTILITY MODEL

The utility model provides a floatable aquaculture oxygen-increasing machine aims at solving the ordinary showy oxygen-increasing machine that mentions in the above-mentioned background and only possesses showy function, removes comparatively inconveniently, the lower problem of oxygenation efficiency.

The utility model discloses a realize like this, a floatable aquaculture oxygen-increasing machine, including floating cabin one, floating cabin two, drive shaft one, drive shaft two and link.

And two ends of the connecting frame are fixedly connected with the upper surfaces of the first floating cabin and the second floating cabin.

The first floating cabin is provided with a first machine shell, and the second floating cabin is provided with a second machine shell.

One end of the first driving shaft is rotatably connected with the second floating cabin through a bearing seat, and the other end of the first driving shaft is rotatably connected with the first casing.

One end of the driving shaft II is rotatably connected with the first floating cabin through a bearing seat, and the other end of the driving shaft II is rotatably connected with the second casing.

A plurality of first blades and second blades are respectively arranged on the first driving shaft and the second driving shaft, and a plurality of through holes are formed in the first blades and the second blades.

The first driving shaft is provided with a first bevel gear, and the second driving shaft is provided with a second bevel gear.

The first floating cabin and the second floating cabin are filled with gas and are connected through the connecting frame, so that the first floating cabin and the second floating cabin float on the water surface, the driving motor drives the driving shaft I to rotate, the driving shaft II drives the driving shaft II to rotate, and then the first blades and the second blades are driven to rotate, and the first blades and the second blades turn over the water surface, so that air enters the water.

Preferably, a first driving motor is fixedly installed inside the second casing, and a third helical gear meshed with the first helical gear is installed at the output end of the first driving motor.

And a second driving motor is arranged inside the first shell, and a fourth helical gear meshed with the second helical gear is arranged at the output end of the second driving motor.

Preferably, an oxygenation pump is installed on the connecting frame, and a guide pipe is installed at the output end of the oxygenation pump.

Preferably, the upper surface of the connecting frame is fixedly provided with a control box, a programmable controller is arranged in the control box, and the programmable controller is provided with a communication module.

The programmable controller is electrically connected with the first driving motor, the second driving motor and the oxygenation pump.

Preferably, the connecting frame is fixedly provided with a solar panel, and the inside of the first floating cabin and the inside of the second floating cabin are both provided with storage batteries.

The solar panel is electrically connected with the two storage batteries through the inverter and the conducting wires.

And the two storage batteries are electrically connected with the programmable controller through leads.

The oxygenation pump can carry out oxygenation operation, makes oxygen get into the bottom by the pipe, carries out the oxygenation to the depths at bottom, and applicable in multiple aquatic products uses, programmable controller is steerable driving motor one, driving motor two and the switch of oxygenation pump carry out the removal of position.

Preferably, steering engines are installed inside the first floating cabin and the second floating cabin, and tail rudders driven by the steering engines are installed on the outer walls of the first floating cabin and the second floating cabin.

Preferably, an oxygen detector electrically connected with the programmable controller is installed on the lower surface of the first floating cabin.

And an indicator light is arranged on the connecting frame.

The steering engine can be operated the accuse tail vane, and then drive float cabin one and float cabin two turn to, and it is more convenient to adjust the position, simultaneously the steering engine is by programmable controller control.

Compared with the prior art, the utility model discloses this kind of floatable aquaculture oxygen-increasing machine

The beneficial effects are that:

(1) the first floating cabin fixes the second floating cabin through the connecting frame, so that the two floating cabins form a whole, and meanwhile, the first floating cabin and the second floating cabin are filled with gas, so that the aerator can float on the water surface conveniently, and is suitable for the field of aquatic products;

(2) the first driving shaft and the second driving shaft driven by the motor are respectively provided with a plurality of first blades and second blades, the water surface is turned through the blades, then the underwater oxygenation is carried out, when the first driving shaft and the second driving shaft rotate in opposite directions, the aerator stays on the water surface, when the first driving shaft and the second driving shaft rotate in the same direction, the aerator is driven to move on the water, and the first floating cabin and the second floating cabin are respectively provided with a tail vane controlled by a steering engine, so that the moving direction can be conveniently adjusted, the oxygenation operation can be carried out at different positions, and the efficiency is higher;

(3) the connecting frame is fixedly provided with the oxygenation pump, and is provided with the conduit connected with the oxygenation pump, so that oxygen can be conveyed to the water bottom, oxygen can be added for different fishes, the application range is wider, and the oxygen adding efficiency is further improved;

(4) the solar water heater is characterized in that a control box is arranged in the water heater, remote control is performed through a programmable controller with a communication module in the control box, the water heater is more convenient to use, and the solar panel is arranged on the connecting frame to charge energy, so that the water heater can be used on the water surface for a long time;

therefore, the aerator is simple to operate, convenient to use, applicable to various aquaculture plants, and more worthy of popularization and sale.

Drawings

FIG. 1 is a front view of the whole structure of the present invention

FIG. 2 is a top view of the whole structure of the present invention

FIG. 3 is a side view of the whole structure of the present invention

FIG. 4 is an enlarged view of the portion A in FIG. 2

FIG. 5 is an enlarged view of the point B in FIG. 2

In the figure: 1-floating cabin one; 101-a first machine shell; 2-floating cabin two; 201-case two; 3, driving a first shaft; 301-paddle one; 302-bevel gear one; 4, driving a second shaft; 401-paddle two; 402-bevel gear two; 5, driving a first motor; 501-bevel gear three; 6, driving a motor II; 601-helical gear four; 7-a connecting frame; 8-oxygenation pump; 801-a catheter; 9-a control box; 901-programmable controller 10-solar panel; 11-a storage battery; 12-an oxygen detector; 13-a steering engine; 14-tail rudder; 15-indicator light.

Detailed Description

The technical solution of the present invention will be described clearly and completely with reference to the accompanying drawings, and obviously, the described embodiments are some, but not all embodiments of the present invention.

The components of the embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations. Thus, the following detailed description of the embodiments of the invention, as presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention.

Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts all belong to the protection scope of the present invention.

Referring to fig. 2, fig. 4 and fig. 5, the present invention provides a technical solution:

the utility model provides a floatable aquaculture oxygen-increasing machine, including floating cabin one 1, float cabin two 2, drive shaft one 3, drive shaft two 4 and link 7, the both ends fixed connection of link 7 floats the upper surface of cabin one 1 and float cabin two 2, it installs casing one 101 on the cabin one 1 to float, it installs casing two 201 on the cabin two 2 to float, 3 one ends of drive shaft are rotated through the bearing frame and are connected floating cabin two 2, the other end rotates and connects casing one 101, drive shaft two 4 one end is rotated through the bearing frame and is connected floating cabin one 1, the other end rotates and connects casing two 201, install a plurality of paddle one 301 and paddle two 401 on drive shaft one 3 and the drive shaft two 4 respectively, all seted up a plurality of through-holes on paddle one 301 and the paddle two 401, install bevel gear one 302 on the drive shaft one 3, install bevel gear two 402 on the drive shaft two 4, the inside fixed mounting of casing two 201 has drive motor one 5, the output of drive motor one 5 installs bevel gear three 501 with a 302 meshing, the internally mounted of drive motor two 101, the output of drive motor 402 installs bevel gear 601 with four helical gear meshes mutually.

The first floating cabin 1 and the second floating cabin 2 are filled with gas and connected through the connecting frame 7, the first floating cabin 1 and the second floating cabin 2 are integrated and float on the water surface, the aerator floats on the water surface, the first driving shaft 3 is driven to rotate by the first driving motor 5, the second driving shaft 4 is driven to rotate by the second driving shaft 4, the first blades 301 and the second blades 401 are driven to rotate, the first blades 301 and the second blades 401 turn over the water surface, air enters the water, meanwhile, the first blades 301 and the second blades 401 are convenient for the gas to pass through the plurality of through holes, aeration is conducted on a culture water area, when the first driving motor 5 and the second driving shaft 4 rotate in opposite directions, the first blades and the second blades counteract each other, the aerator stops on the water surface, when the first driving motor 5 and the second driving shaft 4 rotate in the same direction, power is provided for the aerator, the aerator is driven to conduct aeration operation at different positions, aeration efficiency is higher, and the application range is wider.

Referring to fig. 1 and 3, an oxygenation pump 8 is mounted on a connecting frame 7, a conduit 801 is mounted at an output end of the oxygenation pump 8, a control box 9 is fixedly mounted on an upper surface of the connecting frame 7, a programmable controller 901 is mounted inside the control box 9, a communication module is arranged on the programmable controller 901, the programmable controller 901 is electrically connected with a first driving motor 5, a second driving motor 6 and the oxygenation pump 8, an oxygen detector 12 electrically connected with the programmable controller 901 is mounted on a lower surface of a first floating cabin 1, and an indicator light 15 is mounted on the connecting frame 7.

Wherein, oxygenation pump 8 can carry out the oxygenation operation, make oxygen get into subaqueously by pipe 801, carry out the oxygenation to submarine depths, it is applicable in multiple aquatic products use, the steerable driving motor of programmable controller 901 is one 5, the switch of two 6 driving motors and oxygenation pump 8, carry out the removal of position, accessible communication module remote control programmable controller 901 simultaneously, and then this oxygen-increasing machine of remote operation, it is more convenient to use, oxygen detector 12 and pilot lamp 15 are controlled by programmable controller 901, oxygen detector 12 can examine the content of aquatic oxygen, night pilot lamp 15 lights, play the effect of instruction, discover this oxygen-increasing machine at night.

The solar panel 10 is fixedly mounted on the connecting frame 7, the storage batteries 11 are mounted in the first floating cabin 1 and the second floating cabin 2, the solar panel 10 is electrically connected with the two storage batteries 11 through the inverter and the wires, and the two storage batteries 11 are electrically connected with the programmable controller 901 through the wires.

In addition, the solar panel 10 can convert chemical energy into electric energy, change voltage by the inverter, and store the electric energy into the storage battery 11, so that the aerator can be powered on and used for a long time.

Steering engines 13 are arranged inside the first floating cabin 1 and the second floating cabin 2, and tail rudders 14 driven by the steering engines 13 are arranged on the outer walls of the first floating cabin 1 and the second floating cabin 2.

In addition, the steering engine 13 can control the tail rudder 14, so as to drive the first floating cabin 1 and the second floating cabin 2 to steer, the position is more convenient to adjust, and meanwhile, the steering engine 13 is controlled by the programmable controller 901.

The utility model discloses a theory of operation and use flow: the oxygen increasing machine is characterized in that gas is filled in a first floating cabin 1 and a second floating cabin 2, the oxygen increasing machine is enabled to float on the water surface, a first driving motor 5 drives a first driving shaft 3 to rotate, a second driving shaft 4 drives a second driving shaft 4 to rotate, a first paddle 301 and a second paddle 401 are further driven to rotate, the first paddle 301 and the second paddle 401 turn over the water surface, air is enabled to enter water, meanwhile, a plurality of through holes in the first paddle 301 and the second paddle 401 facilitate gas passing, oxygen increasing is further conducted on a culture water area, oxygen increasing operation can be conducted on the oxygen increasing pump 8, oxygen is enabled to enter the water bottom through a guide pipe 801, oxygen increasing is conducted in deep parts of the water bottom, the oxygen increasing machine is applicable to various aquatic products, the programmable controller 901 can control the first driving motor 5, the second driving motor 6 and the oxygen increasing pump 8 to be switched on and off, position movement is conducted, meanwhile, the programmable controller 901 can be remotely controlled through a communication module, the oxygen increasing machine is further remotely operated, the oxygen detecting machine is more convenient to use, the oxygen detecting instrument 12 and the indicator lamp 15 are both controlled by the programmable controller 901, the oxygen detecting instrument 12 can detect the content of oxygen in water at night, the indicator lamp 15 is lightened, and plays a role of indicating.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not intended to limit the present invention, and any modifications, equivalents, improvements, etc. made within the spirit and principles of the present invention should be included within the scope of the present invention.

Claims (7)

1. The utility model provides a floatable aquaculture oxygen-increasing machine which characterized in that: comprises a first floating cabin (1), a second floating cabin (2), a first driving shaft (3), a second driving shaft (4) and a connecting frame (7); two ends of the connecting frame (7) are fixedly connected with the upper surfaces of the first floating cabin (1) and the second floating cabin (2); a first machine shell (101) is installed on the first floating cabin (1), and a second machine shell (201) is installed on the second floating cabin (2); one end of the first driving shaft (3) is rotatably connected with the second floating cabin (2) through a bearing seat, and the other end of the first driving shaft is rotatably connected with the first casing (101); one end of the second driving shaft (4) is rotatably connected with the first floating cabin (1) through a bearing seat, and the other end of the second driving shaft is rotatably connected with the second casing (201); a plurality of first blades (301) and second blades (401) are respectively arranged on the first driving shaft (3) and the second driving shaft (4), and a plurality of through holes are formed in each of the first blades (301) and the second blades (401); the first bevel gear (302) is installed on the first driving shaft (3), and the second bevel gear (402) is installed on the second driving shaft (4).

2. A floatable aquaculture aerator as claimed in claim 1, wherein: a first driving motor (5) is fixedly installed inside the second casing (201), and a third bevel gear (501) meshed with the first bevel gear (302) is installed at the output end of the first driving motor (5);

and a second driving motor (6) is arranged in the first shell (101), and a fourth bevel gear (601) meshed with the second bevel gear (402) is arranged at the output end of the second driving motor (6).

3. A floatable aquaculture aerator as claimed in claim 2 wherein: install oxygenation pump (8) on link (7), pipe (801) are installed to the output of oxygenation pump (8).

4. A floatable aquaculture aerator as claimed in claim 3 wherein: a control box (9) is fixedly mounted on the upper surface of the connecting frame (7), a programmable controller (901) is mounted in the control box (9), and a communication module is arranged on the programmable controller (901); the programmable controller (901) is electrically connected with the first driving motor (5), the second driving motor (6) and the oxygenation pump (8).

5. A floatable aquaculture aerator as claimed in claim 4 wherein: a solar panel (10) is fixedly mounted on the connecting frame (7), and storage batteries (11) are mounted inside the first floating cabin (1) and the second floating cabin (2); the solar panel (10) is electrically connected with the two storage batteries (11) through an inverter and a conducting wire; and the two storage batteries (11) are electrically connected with the programmable controller (901) through leads.

6. A floatable aquaculture aerator as claimed in claim 1 wherein: steering engine (13) are all installed to the inside in floating cabin (1) and floating cabin two (2), just all install on the outer wall in floating cabin (1) and floating cabin two (2) steering engine (13) driven tail vane (14).

7. A floatable aquaculture aerator according to claim 4, wherein: the lower surface of the first floating cabin (1) is provided with an oxygen detector (12) which is electrically connected with the programmable controller (901); and an indicator light (15) is arranged on the connecting frame (7).

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