LU103128B1

LU103128B1 - Novel automatic oxygen enriching device for higher-place pond aquiculture in mountainous area

Info

Publication number: LU103128B1
Application number: LU103128A
Authority: LU
Inventors: Hanchang Sun
Original assignee: Univ Chongqing Arts & Sciences
Priority date: 2022-09-14
Filing date: 2023-03-21
Publication date: 2023-08-16
Also published as: CN115399280A; WO2023143635A1

Abstract

The invention discloses an automatic oxygen enriching device for higher-place pond aquiculture in mountainous areas, and particularly relates to the oxygen enriching technologies for aquaculture ponds. The automatic oxygen enriching device includes a hull. Square slots are formed in both left and right sides of the bottom end of the hull, and a first rotating rod and a second rotating rod are disposed in the two square slots respectively. According to the invention, a rotating shaft is driven to rotate by rotating a handle, the rotating shaft enables the second rotating rod to rotate in the same direction by using second chains and second sprockets, the second rotating rod enables connecting shafts to rotate in an opposite direction by using first gears and second gears, and the connecting shafts enable the first rotating rod to rotate in the same direction by using first chains and first sprockets.

Description

C52WOI12LU-LTLUP230503 09.05.2023

NOVEL AUTOMATIC OXYGEN ENRICHING DEVICE FOR HIGHER-PLACE LU103128

POND AQUICULTURE IN MOUNTAINOUS AREA

TECHNICAL FIELD

[0001] The present invention relates to the field of oxygen enriching technologies for aquiculture ponds, and in particular to a novel automatic oxygen enriching device for higher- place pond aquiculture in a mountainous area.

BACKGROUND ART

[0002] The mode of higher-place pond aguiculture of fishes in mountainous areas is a high- density aquiculture mode. Generally, higher-place ponds are built above the high tide line of a natural sea level, require mechanical water lifting and can drain all water at any time, and are thus obtaining its name. The higher-place pond aquiculture consists of a water lifting system with a filtering function, a higher-place pond, a drainage system, etc. In addition to higher hardware requirements, the most important factor is high-health aquiculture technology with the main characteristics that aquiculture water can be disinfected and filtered initially, meanwhile, an oxygen enriching machine is equipped to greatly increase an aquiculture density, and in conjunction with efficient and high-quality feed, the possibility of success in high- density fish aquiculture will greatly increase.

[0003] When an existing oxygen enriching machine is used, workers need to carry the oxygen enriching machine to various places. Since the oxygen enriching machine carries impeller blades, which are usually higher than a whole enclosure and the whole device is relatively heavy, more people are required to lift the enclosure during carrying, which is time-consuming and laborious in use.

SUMMARY OF THE INVENTION

[0004] In order to overcome above defecis of the prior art, embodiments of the present invention provide a novel automatic oxygen enriching device for higher-place pond aquiculture in à mountainous area, to solve the problem that it is time-consuming and laborious to carry an existing oxygen enriching machine.

[0005] In order to achieve the above objective, the present invention provides the following technical solution: a novel automatic oxygen enriching device for higher-place pond aquiculture in a mountainous area, which includes a hull, wherein square slots are formed in both left and right sides of the bottom end of the hull, a first rotating rod and a second rotating rod are disposed in the two square slots respectively, two support rods distributed at front and 1

C52WOI12LU-LTLUP230503 09.05.2023 rear portions of the first or second rotating rod sleeve the outer wall of each of the first rotating | 03128 rod and the second rotating rod, an cuter end of each support rod is connected a moving wheel, and the moving wheels are used to support the bottom end of the hull, which is convenient for workers to move the hull and adjust a position of the hull. A slot is formed in one end of the hull, and a handle is disposed inside the slot, which is convenient for the workers to pull the handle and drive the hull to move. A rotating shaft is fixedly disposed at the top end of the handle, two first transmission assemblies are disposed between the first rotating rod and the second rotating rod, and two second transmission assemblies are disposed between the rotating shaft and the second rotating rod. An accommodating slot is formed in the top end of the hull, and a transmission shaft is disposed inside the accommodating slot. Both ends of the transmission shaft runs through the hull and extend to the outer side of the hull, a shaft sleeve sleeves each of both sides of the transmission shaft, a plurality of impeller blades are fixedly disposed on the surface of the outer side wall of the shaft sleeve, and the impeller blades are used to generate splashes on a water surface to supply oxygen, and a driving assembly and two winding assemblies are disposed in the accommodating slot.

[0006] The present invention has the following technical effects and advantages. 1. The rotating shaft is driven to rotate by turning the handle, the rotating shaft enables the second rotating rod to rotate in the same direction by using second chains and second sprockets, the second rotating rod enables connecting shafts to rotate in an opposite direction by using first gears and second gears, and the connecting shafts enable the first rotating rod to rotate in the same direction by using first chains and first sprockets, so that the first rotating rod and the second rotating rod rotate in opposite directions, and the moving wheels on the support rods are driven to move out of the square slots. Thus the whole hull is jacked up, which is convenient for the workers to pull the handle and move the hull to a pond edge, then the handle is turned back to the right position, and the moving wheels can be accommodated in the square slots again. Finally, the hull can be directly pushed into a higher-place pond, so that manual handling of the hull is not needed, and the operation is very time-and-labor-saving.

[0007] 2. À smart phone is connected with a wireless connector on a sealing plate, and used to send a signal to a controller on the sealing plate, which is convenient for the workers to remotely control the controller, and control the operation of a motor by using the controller.

The motor uses two third gears to drive the transmission shaft to rotate, the transmission shaft drives the plurality of impeller blades on the two shaft sleeves to rotate, and the impeller blades generate splashes when rotating at a high speed on the water surface, thereby playing a role of enriching oxygen. 2

C52WOI12LU-LTLUP230503 09.05.2023

[0008] 3. An air pipe is unreeled by controlling a winch wound with the air pipe, ÉU103128 counterweight block pulls the air pipe to sink to the bottom of water under its own weight, and the winch can be controlled to reel the air pipe, which is convenient for adjusting a depth of the counterweight block in the water. Then, an air pump is used to transport air into an air cavity via the air pipe, and the air is ejected from a plurality of air outlets, thereby further increasing oxygen in the water. Filter screens are used to filter impurities such as aquatic plants in the water and prevent the aquatic plants from blocking the air outlets.

BRIEF DESCRIPTION OF THE DRAWINGS

[0009] Fig. 1 is a schematic structural diagram of a sealing plate when closed according to the present invention:

[0010] Fig. 2 is a schematic structural diagram of a first rotating rod and a second rotating rod according to the present invention;

[0011] Fig. 3 is a bottom view of the structure of Fig. 1 according to the present invention;

[0012] Fig. 4 is a schematic structural diagram of a sealing plate when opened according to the present invention;

[0013] Fig. S is a sectional view of a hull according to the present invention:

[0014] Fig. 6 is a partial sectional view according to the present invention; and

[0015] Fig. 7 is a sectional view of a counterweight block according to the present invention.

DETAILED DESCRIPTION

[0016] As shown in Fig. 1, Fig. 2, Fig, 3 and Fig. 4, the present invention provides a novel automatic oxygen enriching device for higher-place pond aquicuiture in a mountainous area, which includes a hull 1 with a supporting device floating on the water surface. The bottom end of the hull 1 is provided with two square slots 2 distributed left and right, a first rotating rod 3 and a second rotating rod 4 which are rotatable are installed in the two square slots 2 respectively, and two support rods 5 which are in front-back symmetry sleeve each of the first rotating rod 3 and the second rotating rod 4. Both support rods 5 are connected with rotatable moving wheels 6. Specifically, the moving wheels 6 are installed on the support rods 5 through bearings for use. In this embodiment, the plurality of moving wheels 6 are adjusted to the bottom end of the bull 1, so that the moving wheels 6 are in contact with the ground, which 1s convenient for workers to push the hull 1 to move.

[0017] The right end surface of the hull 1 is provided with a slot 7, a rotating shaft 9 is disposed in the slot 7, and the bottom end of the rotating shaft 9 is connected with a handle 8.

Specifically, both front and rear ends of the rotating shaft 9 may be connected with the inner 3

C52WOI12LU-LTLUP230503 09.05.2023 wall of the slot 7 through bearings, so that the workers can grab the handle 8 and open the 103128 handle 8 by turning it from the inside of the slot 7, and then pull the handle 8 to drive the hull 1 to move. The first rotating rod 3 and the second rotating rod 4 are linked together through two first transmission assemblies. The rotating shaft 9 and the second rotating rod 4 are linked together through two second transmission assemblies. Understandably, the first rotating rod 3 and the second rotating rod 4 are linked together through the first transmission assemblies and the second transmission assemblies. Two installation cavities 14 are formed in the hull 1. The two installation cavities 14 are formed in both front and rear ends of each of the first rotating rod 3, the second rotating rod 4 and the rotating shaft © respectively. Understandably, both front and rear ends of each of the first rotating rod 3, the second rotating rod 4 and the rotating shaft 9 run through the hull 1 to extend into the two installation cavities 14, and both front and rear ends of each of the first rotating rod 3, the second rotating rod 4 and the rotating shaft © are connected with the inner walls of the installation cavities 14 through bearings, so that the first rotating rod 3, the second rotating rod 4 and the rotating shaft 9 can rotate.

[0018] In this embodiment, each first transmission assembly includes two first gears 15, the two first gears 15 sleeve both front and rear ends of the second rotating rod 4 respectively, left sides of the two first gears 15 are meshed with second gears 16, and connecting shafts 36 are installed inside the two second gears 16. Specifically, the second gears 16 may be welded on outer walls of the connecting shafts 36 to support the second gears 16. In addition, when the connecting shafts 30 rotate along with the second gears 16, a rotating direction of the connecting shafts 36 is opposite to that of the second rotating rod 4. Both front and rear ends of the connecting shafts 36 are connected with the inner walls of the installation cavities 14 through bearings, and two left-right symmetrical first sprockets 17 are disposed in each installation cavity 14. The two first sprockets 17 sleeve the outer walls of the connecting shafts 36 and the first rotating rod 3 respectively. Specifically, the two first sprockets 17 on the connecting shafts 36 are installed on the inner sides of the two second gears 16 respectively to prevent the second gears 16 from affecting the use of the first sprockets 17. À first chain 18 is connected between the two lefi-right symmetrical first sprockets 17. Understandably, the first sprockets 17 sleeve both front and rear ends of the first rotating rod 3 and the connecting shafts 36. The two first sprockets 17 located at the front ends of the first rotating rod 3 and the connecting shafts 36 are connected by the first chain 18, and the two first sprockets 17 located at the rear ends of the first rotating rod 3 and the connecting shafts 36 are connected by the first chain 18. When the connecting shafis 36 rotate, the first rotating rod 3 is driven to rotate therewith by the first chains 18 and the two first sprockets 17, so that the first rotating rod 3 4

C52WOI12LU-LTLUP230503 09.05.2023 and the second rotating rod 4 rotate in opposite directions at the same time, which i 3103128 convenient for adjusting positions of the moving wheels 6.

[0019] Each second transmission assembly includes two second sprockets 19, and a second chain 20 is connected between the two second sprockets 19. Both the second chain 20 and the second sprockets 19 are installed in the installation cavity 14 for use. The two second sprockets 19 sleeve outer walls of the rotating shaft 9 and the second rotating rod 4 respectively.

Specifically, the second sprockets 19 located at both front and rear ends of the second rotating rod 4 are installed at the outer sides of the two first gears 1S to prevent the first gears 15 from affecting the use of the second sprockets 19. When the workers turn the handie &, the handle 8 drives the rotating shaft 9 to rotate, and the rotating shaft 9 drives the second rotating rod 4 to rotate therewith through the second chains 20 and the two second sprockets 19, thereby realizing linkage among the handle 8, the second rotating rod 4 and the first rotating rod 3.

[0020] When the device needs to be used, the workers firstly grab the handle 8 and then open the handle 8 by turning it from the inside of the slot 7. Since the rotating shaft 9 and the second rotating rod 4 are linked by the second chains 20 and the two second sprockets 19, when rotating, the handle 8 drives the second rotating rod 4 to rotate in the same direction. When the first gears 15 on the second rotating rod 4 drive the second gears 16 to rotate, the connecting shafts 36 and the second rotating rod 4 are driven to rotate in opposite directions. Since the connecting shafts 36 and the first rotating rod 3 are linked by the first chains 18 and the two first sprockets 17, the first rotating rod 3 and the connecting shafts 36 rotate in the same direction, so that the first rotating rod 3 and the second rotating rod 4 rotate in opposite directions. When the first rotating rod 3 and the second rotating rod 4 rotate, the moving wheels 6 on the support rods 5 are driven to move out of the square slots 2, and the four moving wheels 6 play a supporting role at the bottom end of the hull 1. At this time, the handle 8 and the hull 1 are in a horizontal state. The workers grab the handle & to conveniently pull the hull 1 to move. When moving the hull 1 to a pond edge, the workers turn the handle 8 into the slot 7 again. Under linkage of the first transmission assemblies and the second transmission assemblies, the rotating shaft 9 drives the first rotating rod 3 and the second rotating rod 4 to reverse, so that the moving wheels 6 can be accommodated in the square slots 2 again, and then the workers directly push the hull 1 into the higher-place pond for use.

[0021] Please continuously referring to Fig. 1, Fig 3, Fig. 4, Fig. 5 and Fig. 6, the upper surface of the hull 1 is provided with an accommodating groove 10, and a driving assembly and two winding assemblies are disposed in the accommodating groove 10. The front side of the hull 1 is provided with a transmission shaft 11, and the rear end of the transmission shaft 11 runs through the hull 1 and extends out from the rear end of the hull 1. Specifically, there is a

C52WOI12LU-LTLUP230503 09.05.2023 through hole in the hull 1, and both front and rear ends of the through hole extend to the outer, | 03128 surface of the hull 1. The transmission shaft 11 may be installed in the through hole through bearings, shaft sleeves 12 sleeve both front and rear ends of the transmission shaft 11, and a plurality of impeller blades 13 distributed in an annular array are fixedly disposed on each of the two shaft sleeves 12. Specifically, the plurality of impeller blades 13 are installed on the outer wall of the shaft sleeve 12 at intervals.

[0022] In this embodiment, the driving assembly includes a motor 21, and the motor 21 is fixedly connected with the inner wall of the bottom end of the accommodating slot 10.

Specifically, the motor 21 may be installed in the accommodating slot 10 through bolts for use.

In addition, the motor 21 is installed under the transmission shaft 11 for use. The motor 21 and the transmission shaft 11 are meshed and linked through two third gears 22. Understandably, the two third gears 22 sleeve outer walls of an output shaft of the motor 21 and the transmission shaft 11 respectively, and the top end of one of the two third gears 22 is meshed with the bottom end of the other of the two third gears 22.

[0023] Each winding assembly includes a winch 23. The two winches 23 are installed on the left and right sides of the motor 21 respectively. The winch 23 on the left side of the motor 21 is wound with a power supply line 24. Specifically, the power supply fine 24 is wound on a reel of the winch 23 on the left side of the motor 21. One end of the power supply line 24 passes through the hull 1 and the power supply line is connected with an external power supply to provide electric energy for the whole device.

[0024] When moving the hull 1 into the higher-place pond, the workers pull the power supply fine 24, and connect the power supply line 24 with the external power supply to control an operation of the motor 21. The motor 21 is used to drive the transmission shaft 11 to rotate through the two third gears 22, the transmission shaft 11 drives the plurality of impeller blades 13 on the two shaft sleeves 12 to rotate, and the impeller blades 13 rotate to generate splashes and make the water in the higher-place pond flow, thereby playing the role of enriching oxygen.

[0025] Please continuously referring to Fig. 1, Fig. 4, Fig. 5 and Fig. 7. The winch 23 located on the right side of the motor 21 is wound with an air pipe 25. Specifically, the air pipe 25 is wound on a reel of the winch 23 on the right side of the motor 21, and an air pump 26 is installed above the hull 1. Specifically, the air pump 26 may be installed on the hull 1 by bolts for use, and the air pump 26 is communicated with one end of the air pipe 25.

[0026] In this embodiment, the bottom end of the hull 1 is provided with an embedding slot 27, a counterweight block 28 is movably disposed inside the embedding slot 27, and an air cavity 29 is disposed inside the counterweight block 28. The surface of the outer side wall of the counterweight block 28 is provided with a plurality of evenly distributed air outlets 30, each air 6

C52WOI12LU-LTLUP230503 09.05.2023 outlet 30 is communicated with the inside of the air cavity 29, and a filter screen 31 15 installed | 03128 inside each air outlet 30, so that impurities in water can be filtered by the filter screens 31 to prevent the impurities from blocking the air outlets 30.

[0027] The accommodating slot 10 is internally provided with a sealing plate 32 which may be opened by turning it, and a wireless network receiver 33 and a controller 34 are installed at the bottom end of the sealing plate 32. Specifically, the wireless network receiver 33 refers to a wireless local area network, which refers to a group of computers and related equipment interconnected by a wireless technology. The controller 34 is connected with the wireless network receiver 33, the air pump 26, the winches 23 and the motor 21. Understandably, the controller 34 is used to control the operation of the air pump 26, the winches 23 and the motor 21. In addition, a wireless signal sent by the wireless network receiver 33 is used to remotely connect the controller 34 with intelligent equipment, which is convenient for the workers to remotely control the controller 34 to control the whole device.

[0028] Side plates 35 are installed at both front and rear ends of the hull 1, and the sides of the side plates 35 close to the hull 1 are fixedly connected with the hull 1 through two brackets, so that the stability is increased at both sides of the hull 1 by using the two side plates 35, and the hull T is prevented from rolling over when in use.

[0029] When the impeller blades 13 are used to stir water in the pond, the winch 23 wound with the air pipe 25 is controlled to operate, so that the winch 23 unreels the air pipe 25, the counterweight block 28 pulls the air pipe 25 to sink to the bottom due to its own weight, and then the air pump 26 is used to suck external air, pressurize the air and then deliver the air into the air cavity 29 inside the counterweight block 28. Then the air is ejected from the plurality of air outlets 30, thereby further supplying oxygen. The filter screen 31 inside each air outlet 30 can filter the impurities such as aquatic plants in the water to prevent the aquatic plants from blocking the air outlet 30. The workers may also use the controller 34 to control the winch 23 to reel the air pipe 25, which is convenient for adjusting a depth of the counterweight block 28 in the water. 7

Claims

C52WOI12LU-LTLUP230503 09.05.2023 CLAIMS LU103128

1. A novel automatic oxygen enriching device for higher-place pond aquiculture in a mountainous area, comprising a hull, wherein square slots are formed in both left and right sides of a bottom end of the hull, a first rotating rod and a second rotating rod are disposed in the two square slots respectively, two support rods distributed at front and rear portions of the first or second rotating rod sleeve an outer wall of each of the first rotating rod and the second rotating rod, an outer end of each support rod is connected with a moving wheel, one end of the hull is provided with a slot, a handle is disposed in the slot, a rotating shaft is fixedly disposed at a top end of the handle, two first transmission assemblies are disposed between the first rotating rod and the second rotating rod, and two second transmission assemblies are disposed between the rotating shaft and the second rotating rod; a top end of the hull is provided with an accommodating slot, a transmission shaft is disposed in the accommodating slot, both ends of the transmission shaft run through the hull and extend to an outer side of the hull, a shaft sleeve sleeves each of both sides of the transmission shaft, the surface of an outer side wall of the shaft sleeve is fixedly provided with a plurality of impeller blades, and a driving assembly and two winding assemblies are disposed in the accommodating slot.

2. The novel automatic oxygen enriching device for the higher-place pond aquiculture in the mountainous area according to claim 1, wherein two installation cavities distributed at front and rear portions are formed in the hull, and both ends of each of the first rotating rod, the second rotating rod and the rotating shaft extend into the two installation cavities and are connected with inner walls of the installation cavities through bearings.

3. The novel automatic oxygen enriching device for the higher-place pond aquiculture in the mountainous area according to claim 1, wherein the two first transmission assemblies are disposed in two installation cavities respectively, each first transmission assembly comprises two first gears, the two first gears sleeve the outer wall of the second rotating rod respectively, one side of each of the two first gears is meshed with a second gear, the two second gears are connected with inner walls of the installation cavities through connecting shafts, a first sprocket sleeves each of outer walls of the two connecting shafts and the outer walls of the two first rotating rods, and the two first sprockets are connected by a first chain.

4. The novel automatic oxygen enriching device for the higher-place pond aquiculture in the mountainous area according to claim 1, wherein each second transmission assembly comprises two second sprockets, the two second sprockets sleeve outer walls of the rotating 1

C52WOI12LU-LTLUP230503 09.05.2023 shaft and the second rotating rod respectively, the two second sprockets are connected by A 103128 second chain, and the second chain and the two second sprockets are disposed in an installation cavity.

5. The novel automatic oxygen enriching device for the higher-place pond aquiculture in the mountainous area according to claim 1, wherein the driving assembly comprises a motor, the motor is fixed in the accommodating slot, a third gear sleeves each of outer walls of an output shaft of the motor and the transmission shaft, and a top end of the third gear on the output shaft of the motor is meshed with a bottom end of the third gear on the outer wall of the transmission shaft.

6. The novel automatic oxygen enriching device for the higher-place pond aquiculture in the mountainous area according to claim 5, wherein each winding assembly comprises a winch, the two winches are respectively fixed in the accommodating slot, the two winches are disposed on both sides of the motor, a power supply line (24) is wound on the winch on the left side of the motor, an air pipe is wound on the winch on the right side of the motor, and one end of the power supply line runs through the hull and extends to the outer side of the hull.

7. The novel automatic oxygen enriching device for the higher-place pond aquiculture in the mountainous area according to claim 6, wherein an air pump is fixedly disposed at the top end of the hull, an embedding slot is disposed in the center of the bottom end of the hull, a counterweight block is disposed in the embedding slot, an air cavity is disposed in the counterweight block, the surface of an outer side wall of the air cavity is provided with a plurality of air outlets, a filter screen is fixedly disposed in each air outlet, one end of the air pipe sequentially runs through the hull and the counterweight block to communicate with the air cavity inside the counterweight block, and the other end of the air pipe runs through the hull to communicate with the air pump.

8. The novel automatic oxygen enriching device for the higher-place pond aquiculture in the mountainous area according to claim 7, wherein a sealing plate is hinged to a top end of the accommodating slot, a wireless network receiver and a controller are embedded in a bottom end of the sealing plate, and the controller is connected with the wireless network receiver, the air pump, the winches and the motor.

9. The novel automatic oxygen enriching device for the higher-place pond aquiculture in the mountainous area according to claim 1, wherein each of the front and rear ends of the hull is provided with a side plate, and the two side plates are fixedly connected with the hull through two brackets. 2