CN219835075U

CN219835075U - Multidirectional automatic moving oxygenation device

Info

Publication number: CN219835075U
Application number: CN202321216316.5U
Authority: CN
Inventors: 刘盛理
Original assignee: Shanghai Mingzhu Chenxi Intelligent Technology Co ltd
Current assignee: Shanghai Mingzhu Chenxi Intelligent Equipment Co ltd
Priority date: 2023-05-18
Filing date: 2023-05-18
Publication date: 2023-10-17
Anticipated expiration: 2033-05-18

Abstract

The utility model discloses an automatic multidirectional moving oxygenation device, which comprises an equipment main body, wherein a plurality of mounting rods are circumferentially arranged at the bottom of the equipment main body, a pontoon is fixedly connected at the tail ends of the mounting rods, the equipment main body comprises a power device, the power device comprises a first driving unit, the output end of the first driving unit penetrates out of the bottom of the equipment main body, an adapter plate is fixedly connected with the output end, and a propeller is arranged on the adapter plate; the mounting rod is fixedly connected with an oxygenation mechanism, the oxygenation mechanism comprises a bottom plate, the bottom plate is fixedly connected with the mounting rod, the oxygenation mechanism further comprises an impeller connected with the bottom plate, the impeller penetrates out of the bottom plate, and the oxygenation mechanism further comprises a second driving unit, and the second driving unit is connected with the impeller. According to the utility model, the rotary power device at the bottom of the oxygenation device is used for driving, so that the oxygenation device can move in any direction, the oxygenation device achieves the effect of multidirectional movement, one oxygenation device can meet the oxygen requirement of one farm, and the cultivation cost is reduced.

Description

Multidirectional automatic moving oxygenation device

Technical Field

The utility model belongs to the field of aquaculture, and particularly relates to an automatic multidirectional moving oxygenation device.

Background

In aquaculture, because the aquatic products density in the plant is higher, can be equipped with oxygenation device in the plant generally, increase the oxygen content in water through oxygenation device, ensure that the aquatic products in the plant can not lack of oxygen. However, most of the existing oxygenation devices are not movable, and when the area of the farm is large, a plurality of oxygenation devices are needed to meet the oxygen demand of the farm, so that the cost is high.

In prior art, like the patent document of publication number CN208030008U, disclose an oxygenation equipment for aquaculture, including waterproof shell and fixing base, the inside fixed mounting of waterproof shell has the oxygenation pump machine, and the lower extreme internal surface of oxygenation pump machine is close to the position department fixed mounting in the middle has the gas-supply pipe, the surface of gas-supply pipe is close to the position department fixed mounting in the middle has the suspension dish. However, the oxygenation equipment cannot move, and when the area of the farm is large, a plurality of oxygenation equipment are needed to meet the oxygen demand of the farm, so that the cultivation cost is greatly increased.

Therefore, there is a need for an oxygenation device that automatically moves in multiple directions to address the above-described shortcomings.

Disclosure of Invention

Aiming at the problems in the prior art, the utility model provides the multi-direction automatic moving oxygenation device, and one oxygenation device can meet the oxygen demand of a farm in a moving mode, so that the cultivation cost is reduced.

The utility model is realized in the following way: the utility model provides an oxygenation device of multi-direction automatic movement, includes an equipment main part, equipment main part bottom circumference is equipped with a plurality of evenly distributed's installation pole, the top of installation pole with equipment main part rigid coupling, the terminal rigid coupling has a flotation pontoon, the flotation pontoon is used for oxygenation device provides buoyancy, makes it float in the surface of water.

The equipment main body comprises a power device arranged at the bottom, the power device comprises a first driving unit arranged in the equipment main body, an output end of the first driving unit penetrates out of the bottom of the equipment main body from top to bottom, an adapter plate fixedly connected with the output end, and a propeller with a built-in motor, and the propeller is fixedly arranged on the adapter plate; the power device is used for driving the oxygenation device to move, the screw propeller provides moving power for the oxygenation device, and the first driving unit drives the screw propeller to turn, so that the oxygenation device achieves the technical effect of multidirectional movement.

Each mounting rod is fixedly connected with an oxygenation mechanism, each oxygenation mechanism comprises a bottom plate, each bottom plate is fixedly connected with the mounting rod, each oxygenation mechanism further comprises an impeller rotationally connected with the bottom plate, each impeller penetrates out of the bottom plate from bottom to top, each oxygenation mechanism further comprises a second driving unit arranged on the bottom plate, and each second driving unit is in transmission connection with each impeller. The impeller stirs the water in the plant, and oxygen in the air is quickly transferred into the water in a water stirring mode, so that the technical effect of oxygenation is achieved.

Preferably, a control module is disposed on the device main body, and the control module is electrically connected with the first driving unit, the second driving unit and the propeller respectively.

Preferably, the device main body further comprises a power storage module arranged in the device main body, and a power generation module arranged at the top of the device main body, and the power generation module is electrically connected with the power storage module. The power storage module and the power generation module are used for providing energy for the oxygenation device, and because the oxygenation device needs to be moved and is not suitable for being powered by a cable, the power storage module is required to be arranged in the oxygenation device for providing energy; the power generation module is used for providing electric quantity for the power storage module, and is energy-saving and environment-friendly.

Specifically, the power generation module is a photovoltaic panel.

Preferably, the output end of the second driving unit is fixedly connected with a first bevel gear, a second bevel gear is arranged at the top of the impeller, and the first bevel gear and the second bevel gear are meshed for transmission.

Specifically, the modulus of the first bevel gear is equal to that of the second bevel gear, and the number of teeth of the first bevel gear is smaller than that of the second bevel gear.

Specifically, the gear ratio of the first bevel gear to the second bevel gear is 1:2. When the number of teeth of the first bevel gear is smaller than that of the second bevel gear, the first bevel gear and the second bevel gear are meshed to form deceleration meshing transmission, so that the rotation moment of the impeller is increased, the rated power of the second driving unit is further reduced, and the cruising ability of the oxygenation device is prolonged.

Specifically, the oxygenation mechanism further comprises a protection cover, and the protection cover covers the second driving unit, the first bevel gear and the second bevel gear. The protection casing is used for preventing when oxygenation mechanism works, splashes the water in the cultivation ground to on the oxygenation mechanism, reduces oxygenation mechanism's security risk.

Preferably, the impeller comprises a plurality of blades which are uniformly distributed along the circumferential direction, and a plurality of water passing holes are formed in the blades. The water passing holes are used for reducing the resistance of the impeller during stirring water, so that the rated power of the second driving unit is further reduced, and the endurance of the oxygenation device is prolonged.

Specifically, the number of the blades is 4-8, and the diameter of the water passing hole is 8-12mm.

Preferably, the circumferential top of the pontoon is provided with a range radar, and the circumferential bottom is provided with a dissolved oxygen sensor. The range radar is used for detecting the distance from the oxygenation device to the shore, and when the distance from the oxygenation device to the shore is smaller than a set value, the oxygenation device is driven to move in the opposite direction, so that the oxygenation device is prevented from supporting the foundation. The oxygen dissolving sensor is used for detecting the oxygen content of the current water area, the oxygenation device is used for inspecting the farm at regular time, when the oxygen content of the inspected area is lower than a set value, the oxygenation device is started, when the oxygen content is higher than the set value, the oxygenation device is stopped, and the oxygenation device is driven to move towards other areas.

The utility model has the beneficial effects that:

according to the utility model, the rotatable power device at the bottom of the oxygenation device is used for driving, so that the oxygenation device can move and can turn to any direction, the oxygenation device achieves the technical effect of multidirectional movement, and further one oxygenation device can meet the oxygen requirement of a farm, and the cultivation cost is reduced.

Drawings

FIG. 1 is an overall schematic view of an oxygenation device according to the utility model;

FIG. 2 is a schematic view of the main body of the aerator according to the present utility model;

FIG. 3 is a schematic view of a power plant of the oxygenation device of the utility model;

FIG. 4 is a schematic view of an oxygenation mechanism of an oxygenation device of the utility model;

FIG. 5 is a schematic view of the inside of the oxygenation mechanism of the oxygenation device of the utility model.

Reference numerals:

1. an apparatus main body; 2. a power device; 3. an oxygenation mechanism; 11. a pontoon; 12. a power generation module; 13. a control module; 14. a mounting rod; 21. an adapter plate; 22. a propeller; 31. a protective cover; 32. an impeller; 33. a second driving unit; 111. a range radar; 112. an oxygen dissolving sensor; 321. a blade; 322. a second bevel gear; 331. a first bevel gear; 3211. and water holes.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the utility model. 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.

As shown in fig. 1-5, an oxygenation device capable of automatically moving in multiple directions comprises a device main body 1, wherein a plurality of uniformly distributed mounting rods 14 are circumferentially arranged at the bottom of the device main body 1, the initial ends of the mounting rods 14 are fixedly connected with the device main body 1, the tail ends of the mounting rods are fixedly connected with a pontoon 11, and the pontoon 11 is used for providing buoyancy for the oxygenation device so as to enable the oxygenation device to float on the water surface.

In this embodiment, the device main body 1 further includes a power storage module disposed inside the device main body 1, and a power generation module 12 disposed on the top of the device main body 1, where the power generation module 12 is electrically connected to the power storage module. The power storage module and the power generation module 12 are used for providing energy for the oxygenation device, and because the oxygenation device needs to be moved and is not suitable for being powered by a cable, the power storage module is required to be arranged in the oxygenation device for providing energy; the power generation module 12 is used for providing electric quantity for the power storage module, and is energy-saving and environment-friendly.

Specifically, the power generation module 12 is a photovoltaic panel.

The equipment main body 1 comprises a power device 2 arranged at the bottom, the power device 2 comprises a first driving unit arranged in the equipment main body 1, an output end of the first driving unit penetrates out of the bottom of the equipment main body 1 from top to bottom, an adapter plate 21, a propeller 22 with a built-in motor, and the propeller 22 is fixedly arranged on the adapter plate 21; the power device 2 is used for driving the oxygenation device to move, wherein the propeller 22 provides moving power for the oxygenation device, and the first driving unit drives the propeller 22 to turn, so that the oxygenation device achieves the technical effect of multidirectional movement.

Each mounting rod 14 is fixedly connected with an oxygenation mechanism 3, the oxygenation mechanism 3 comprises a bottom plate, the bottom plate is fixedly connected with the mounting rods 14, the oxygenation mechanism further comprises an impeller 32 rotatably connected with the bottom plate, and the impeller 32 penetrates out of the bottom plate from bottom to top.

In this embodiment, the impeller 32 includes a plurality of blades 321 uniformly distributed along the circumferential direction, and a plurality of water holes 3211 are formed in the blades 321. The water passing hole 3211 is configured to reduce resistance when the impeller 32 stirs water, further reduce rated power of the second driving unit 33, and prolong cruising ability of the oxygenation device.

Specifically, the number of the blades 321 is 8, and the diameter of the water passing hole 3211 is 10mm.

The motor further comprises a second driving unit 33 arranged on the bottom plate, and the second driving unit 33 is in transmission connection with the impeller 32. The impeller 32 stirs the water in the farm, and oxygen in the air is quickly transferred into the water in a water stirring manner, so that the technical effect of oxygenation is achieved.

In this embodiment, a first bevel gear 331 is fixedly connected to the output end of the second driving unit 33, a second bevel gear 322 is disposed on the top of the impeller 32, and the first bevel gear 331 is meshed with the second bevel gear 322 for transmission.

Specifically, the first bevel gear 331 and the second bevel gear 322 have equal modulus, and the number of teeth of the first bevel gear 331 is smaller than the number of teeth of the second bevel gear 322.

Specifically, the gear ratio of the first bevel gear 331 to the second bevel gear 322 is 1:2. When the number of teeth of the first bevel gear 331 is smaller than that of the second bevel gear 322, the first bevel gear 331 and the second bevel gear 322 are meshed to form a reduced meshed transmission, so that the rotation moment of the impeller 32 is increased, the rated power of the second driving unit 33 is further reduced, and the cruising ability of the oxygenation device is prolonged.

Specifically, the oxygenation mechanism 3 further comprises a protection cover 31, and the protection cover 31 covers the second driving unit 33, the first bevel gear 331 and the second bevel gear 322. The protection cover 31 is used for preventing water in the cultivation field from splashing on the oxygenation mechanism 3 when the oxygenation mechanism 3 works, so that the safety risk of the oxygenation mechanism 3 is reduced.

In this embodiment, a control module 13 is disposed on the apparatus main body 1, and the control module 13 is electrically connected to the first driving unit, the second driving unit 33, and the propeller 22, respectively.

In this embodiment, a range radar 111 is disposed at the top of the pontoon 11 in the circumferential direction, and an oxygen dissolving sensor 112 is disposed at the bottom of the pontoon in the circumferential direction. The range radar 111 is used for detecting the distance between the oxygenation device and the shore, and when the distance between the oxygenation device and the shore is smaller than 1 meter, the oxygenation device is driven to move in the opposite direction, so that the oxygenation device is prevented from supporting the foundation. The dissolved oxygen sensor 112 is used for detecting the oxygen content of the current area, the oxygenation device is used for inspecting the farm every half an hour for one circle, when the oxygen content of the inspected area is lower than 7mg/L, the oxygenation device is started, when the oxygen content is higher than 15mg/L, the oxygenation device is stopped, and the oxygenation device is driven to move towards other areas.

In this embodiment, the working procedure of the oxygenation device is as follows: when the oxygenation device needs to be moved, the first driving unit drives the adapter plate 21 to rotate, so that the propeller 22 faces the direction opposite to the moving direction of the oxygenation device, and then the propeller 22 is started to drive the oxygenation device to move.

Variations and modifications to the above would be obvious to persons skilled in the art to which the utility model pertains from the foregoing description and teachings. Therefore, the utility model is not limited to the specific embodiments disclosed and described above, but some modifications and changes of the utility model should be also included in the scope of the claims of the utility model. In addition, although specific terms are used in the present specification, these terms are for convenience of description only and do not limit the present utility model in any way.

Claims

1. The multidirectional automatic-movement oxygenation device comprises an equipment main body, wherein a plurality of uniformly distributed mounting rods are circumferentially arranged at the bottom of the equipment main body, the starting ends of the mounting rods are fixedly connected with the equipment main body, the tail ends of the mounting rods are fixedly connected with a pontoon, the oxygenation device is characterized in that,

the equipment main body comprises a power device arranged at the bottom, the power device comprises a first driving unit arranged in the equipment main body, an output end of the first driving unit penetrates out of the bottom of the equipment main body from top to bottom, an adapter plate fixedly connected with the output end, and a propeller with a built-in motor, and the propeller is fixedly arranged on the adapter plate;

each mounting rod is fixedly connected with an oxygenation mechanism, each oxygenation mechanism comprises a bottom plate, each bottom plate is fixedly connected with the mounting rod, each oxygenation mechanism further comprises an impeller rotationally connected with the bottom plate, each impeller penetrates out of the bottom plate from bottom to top, each oxygenation mechanism further comprises a second driving unit arranged on the bottom plate, and each second driving unit is in transmission connection with each impeller.

2. The multi-directional automatic moving oxygen increasing device according to claim 1, wherein a control module is arranged on the device main body, and the control module is electrically connected with the first driving unit, the second driving unit and the propeller respectively.

3. The multi-directional automatic moving oxygenation device of claim 1, wherein the device body further comprises a power storage module arranged inside the device body, and a power generation module arranged on the top of the device body, wherein the power generation module is electrically connected with the power storage module.

4. A multidirectional automatically moving oxygenation device according to claim 3, wherein said power generation module is a photovoltaic panel.

5. The multi-directional automatic moving oxygenation device according to claim 1, wherein the output end of the second driving unit is fixedly connected with a first bevel gear, a second bevel gear is arranged at the top of the impeller, and the first bevel gear is meshed with the second bevel gear for transmission.

6. The multi-directional, automatically moving oxygenation apparatus of claim 5 wherein the first bevel gear is of equal modulus to the second bevel gear and the number of teeth of the first bevel gear is less than the number of teeth of the second bevel gear.

7. The multi-directional, automatically moving oxygenation apparatus of claim 6 wherein the first bevel gear and the second bevel gear have a gear ratio of 1:2.

8. The multi-directional, automatically moving oxygenation apparatus of claim 5, wherein the oxygenation mechanism further comprises a shield covering the second drive unit, the first bevel gear, and the second bevel gear.

9. The multi-directional automatic moving oxygen increasing device according to claim 1, wherein the impeller comprises a plurality of blades which are uniformly distributed along the circumferential direction, a plurality of water passing holes are formed in the blades, the number of the blades is 4-8, and the diameter of the water passing holes is 8-12mm.

10. The multi-directional automatic moving oxygenation device according to claim 1, wherein a range radar is arranged at the circumferential top of the pontoon, and an oxygen dissolving sensor is arranged at the circumferential bottom of the pontoon.