A batching device for animal feed processing
By designing a batching device with a dispersing plate and a propeller, the problem of difficult-to-break agglomerated materials was solved, achieving more efficient animal feed mixing and improved preparation quality.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- BAODING DE NEIGHBOR BIOTECHNOLOGY CO LTD
- Filing Date
- 2025-07-22
- Publication Date
- 2026-06-23
AI Technical Summary
Existing batching equipment cannot effectively break up clumps of materials, affecting the quality of animal feed preparation.
A batching device including a mixing tank, a connecting box, and a connecting tank is designed. The motor drives the rotating shaft to engage the driving wheel and the driven wheel. The transmission shaft and the drive shaft rotate to drive the dispersing plate and the propeller to disperse the raw materials. The mixing is carried out by the stirring blade and the scraper. The amount of raw materials fed is controlled by the pressure sensor.
It effectively breaks up and mixes clumps of materials, improving the production quality of animal feed.
Smart Images

Figure CN224388568U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of ingredient dispensing devices, and in particular to an ingredient dispensing device for animal feed processing. Background Technology
[0002] Animal feed refers to live feed such as various insects and fish and shrimp, as well as eggs, meat, fish meal, silkworm pupa powder, fly larvae powder and milk powder. Animal feed is indispensable in livestock production, and safe animal feed is one of the factors that promote the healthy development of livestock production.
[0003] In the production and processing of animal feed, a batching device is usually required to process the feed to ensure the quality of animal feed production. However, the raw materials used in batching are often prone to clumping, but existing batching devices cannot break up the clumped materials, which affects the quality of subsequent feed preparation. Therefore, we propose a batching device for animal feed processing. Utility Model Content
[0004] This utility model addresses the shortcomings of existing technologies by providing the following technical solution: a batching device for animal feed processing, comprising:
[0005] A mixing tank, wherein a motor is installed at the bottom of the mixing tank, and a rotating shaft is installed through the bottom of the motor at the power end of the mixing tank. A first drive wheel is installed through the top of the outer ring of the rotating shaft at the top of the mixing tank, and a second drive wheel is installed at the end of the rotating shaft away from the motor.
[0006] The top of the mixing tank is connected to a connecting box, the side wall of the connecting box is provided with a conveying shaft, the outer ring of the conveying shaft is provided with a dispersing plate, and one side of the conveying shaft is provided with a first driven wheel that penetrates the side wall of the connecting box. The first driven wheel meshes with a first driving wheel.
[0007] The connecting box has a connecting tank connected to its side wall, and a drive shaft is provided on the side wall of the connecting tank. A second driven wheel is provided on one side of the drive shaft, which passes through the side wall of the connecting box. The second driven wheel meshes with a second driving wheel. A propeller is provided on the outer ring of the drive shaft.
[0008] As an improvement to the above technical solution, the side wall of the rotating shaft is provided with stirring blades, the top side wall of the rotating shaft is provided with a connecting rod, the connecting rod is located above the stirring blades but does not contact them, and a scraper is provided at the bottom of the side of the connecting rod away from the rotating shaft, and one side of the scraper is in contact with the inner wall of the mixing tank.
[0009] As an improvement to the above technical solution, a pressure sensor is provided on the top of the connecting tank, a control valve is provided on the top of the pressure sensor, a feed hopper is provided on the top of the control valve, and a display screen is provided on the side wall of the feed hopper.
[0010] As an improvement to the above technical solution, the bottom inner wall of the mixing tank is inclined, the side wall of the mixing tank is provided with a discharge port, and a discharge valve is provided on the outside of the discharge port.
[0011] As an improvement to the above technical solution, the top and bottom of the mixing tank are provided with first bearings, and the rotating shaft is rotatably connected to the first bearings.
[0012] As an improvement to the above technical solution, a second bearing is provided on the side wall of the connecting box, and the transmission shaft is rotatably connected to the second bearing.
[0013] As an improvement to the above technical solution, both the side wall of the connecting box and the side wall of the connecting tank are provided with a third bearing, and the transmission shaft is rotatably connected to the third bearing.
[0014] The beneficial effects of this utility model are:
[0015] The raw materials are placed in the connecting tank, and the motor is turned on so that the rotating shaft drives the first driving wheel and the second driving wheel to rotate. Through the meshing of the first driving wheel and the first driven wheel and the second driving wheel and the second driven wheel, the conveying shaft and the transmission shaft rotate, which drives the dispersing plate and the propeller to rotate, transporting and dispersing the raw materials. After being dispersed, the raw materials fall into the mixing tank for mixing. Attached Figure Description
[0016] Figure 1 This is a front view of the overall structure of this utility model;
[0017] Figure 2 This is a cross-sectional view of the mixing tank structure of this utility model;
[0018] Figure 3 This is a partial structural cross-sectional view of the present invention.
[0019] Figure label:
[0020] 10. Mixing tank; 101. First bearing; 11. Motor; 12. Shaft; 13. Connecting rod; 14. Scraper; 15. Mixing blade; 16. First drive wheel; 17. Second drive wheel; 18. Discharge port; 19. Discharge valve; 20. Connecting box; 21. Conveyor shaft; 22. First driven wheel; 23. Dispersing plate; 24. Second bearing; 30. Connecting tank; 31. Drive shaft; 32. Propeller; 33. Second driven wheel; 34. Feed hopper; 35. Control valve; 36. Pressure sensor; 37. Display screen; 38. Third bearing. Detailed Implementation
[0021] The following specific examples illustrate the implementation of this utility model. Those skilled in the art can easily understand other advantages and effects of this utility model from the content disclosed in this specification. This utility model can also be implemented or applied through other different specific embodiments, and various details in this specification can also be modified or changed based on different viewpoints and applications without departing from the spirit of this utility model.
[0022] Please see Figure 1-3 A batching device for animal feed processing, comprising:
[0023] A mixing tank 10 is provided with a motor 11 at the bottom of the mixing tank 10. The power end of the motor 11 passes through the bottom of the mixing tank 10 and a rotating shaft 12 is provided. The top of the outer ring of the rotating shaft 12 passes through the top of the mixing tank 10 and a first drive wheel 16 is provided. A second drive wheel 17 is provided at the end of the rotating shaft 12 away from the motor 11.
[0024] A connecting box 20 is connected to the top of the mixing tank 10. A conveying shaft 21 is provided on the side wall of the connecting box 20. A dispersing plate 23 is provided on the outer ring of the conveying shaft 21. A first driven wheel 22 is provided through the side wall of the connecting box 20 on one side of the conveying shaft 21. The first driven wheel 22 meshes with the first driving wheel 16.
[0025] A connecting tank 30 is connected to the side wall of the connecting box 20. A drive shaft 31 is provided on the side wall of the connecting tank 30. A second driven wheel 33 is provided through the side wall of the connecting box 20 on one side of the drive shaft 31. The second driven wheel 33 meshes with the second driving wheel 17. A propeller 32 is provided on the outer ring of the drive shaft 31.
[0026] When the motor 11 is turned on, the rotating shaft 12 rotates, driving the first driving wheel 16 and the second driving wheel 17 to rotate. The meshing of the first driving wheel 16 with the first driven wheel 22 and the second driving wheel 17 with the second driven wheel 33 causes the transmission shaft 21 and the drive shaft 31 to rotate, driving the dispersing plate 23 and the propeller 32 to rotate. The propeller 32 rotates to transport the raw materials to the connecting box 20. The dispersing plate 23 rotates to disperse the raw materials, and the dispersed raw materials fall into the mixing tank 10 for mixing.
[0027] The side wall of the rotating shaft 12 is provided with stirring blades 15, and the top side wall of the rotating shaft 12 is provided with a connecting rod 13. The connecting rod 13 is located above the stirring blades 15 but does not contact them. A scraper 14 is provided at the bottom of the side of the connecting rod 13 away from the rotating shaft 12. One side of the scraper 14 is in contact with the inner wall of the mixing tank 10.
[0028] When the raw materials enter the mixing tank 10, the motor 11 is turned on, which causes the rotating shaft 12 to rotate and also drives the stirring blades 15 to rotate to mix the dispersed raw materials. During the mixing process, the rotation of the rotating shaft 12 also causes the connecting rod 13 to drive the scraper 14 to rotate and scrape off the raw materials adhering to the inner wall of the mixing tank 10, so as to mix more thoroughly.
[0029] A pressure sensor 36 is installed on the top of the connecting tank 30, a control valve 35 is installed on the top of the pressure sensor 36, a feed hopper 34 is installed on the top of the control valve 35, and a display screen 37 is installed on the side wall of the feed hopper 34.
[0030] In use, the raw materials are put into each feed hopper 34. The weight of the feed hopper 34 increases, and the weight of the material is measured by the pressure sensor 36. The weight of the material is controlled. When the weight of the material is appropriate, the control valve 35 is opened, and the raw materials fall into the connecting tank 30 for transportation.
[0031] The bottom inner wall of the mixing tank 10 is inclined, and the side wall of the mixing tank 10 is provided with a discharge port 18, and a discharge valve 19 is provided on the outside of the discharge port 18.
[0032] Opening the discharge valve 19 allows the mixed raw materials in the mixing tank 10 to be taken out from the discharge port 18.
[0033] The mixing tank 10 is provided with a first bearing 101 at both the top and bottom, and the rotating shaft 12 is rotatably connected to the first bearing 101.
[0034] Turning on the motor 11 causes the rotating shaft 12 to rotate within the first bearing 101, which in turn drives the first drive wheel 16 and the second drive wheel 17 to rotate.
[0035] A second bearing 24 is provided on the side wall of the connecting box 20, and the transmission shaft 21 is rotatably connected to the second bearing 24.
[0036] The raw materials enter the connecting box 20. The motor 11 is turned on, which causes the rotating shaft 12 to drive the first driving wheel 16 to rotate. The first driving wheel 16 meshes with the first driven wheel 22, which causes the conveying shaft 21 to rotate. In turn, the conveying shaft 21 rotates in the second bearing 24, which drives the dispersing plate 23 to rotate and disperse the raw materials. After being dispersed, the raw materials fall into the mixing tank 10.
[0037] Both the side wall of the connecting box 20 and the side wall of the connecting tank 30 are provided with a third bearing 38, and the drive shaft 31 is rotatably connected to the third bearing 38.
[0038] The raw materials enter the connecting tank 30. The motor 11 is turned on, which causes the rotating shaft 12 to drive the second driving wheel 17 to rotate. The meshing of the second driving wheel 17 and the second driven wheel 33 causes the transmission shaft 31 to rotate. In turn, the transmission shaft 31 rotates in the third bearing 38, which drives the propeller 32 to rotate to transport the raw materials. Then, the raw materials enter the connecting box 20 to be broken up.
[0039] In operation, raw materials are fed into each feed hopper 34, increasing the weight of the feed hopper 34. The weight of the material is measured by the pressure sensor 36. Once the weight is appropriate, the control valve 35 is opened, and the raw materials fall into the connecting tank 30. The motor 11 is then turned on, causing the rotating shaft 12 to rotate within the first bearing 101, which in turn drives the first driving wheel 16 and the second driving wheel 17 to rotate. Through the meshing of the first driving wheel 16 with the first driven wheel 22 and the second driving wheel 17 with the second driven wheel 33, the transmission shaft 21 and the drive shaft 31 rotate within the second bearing 24 and the third bearing 38, respectively. The dispersing plate 23 and the propeller 32 rotate, and the propeller 32 rotates to transport the raw materials to the connecting box 20. The dispersing plate 23 rotates to disperse the raw materials, and the dispersed raw materials fall into the mixing tank 10 for mixing. At the same time, the rotating shaft 12 drives the stirring blade 15 to rotate to mix the dispersed raw materials. During the mixing process, the rotating shaft 12 also causes the connecting rod 13 to drive the scraper 14 to rotate to scrape off the raw materials adhering to the inner wall of the mixing tank 10, so as to better mix them. After mixing, the discharge valve 19 can be opened to discharge the mixed raw materials from the discharge port 18.
[0040] The above embodiments are only used to illustrate the technical solution of this utility model, and are not intended to limit it. Any person skilled in the art can modify or change the above embodiments without departing from the spirit and scope of this utility model. Therefore, all equivalent modifications or changes made by those skilled in the art without departing from the spirit and technical concept disclosed in this utility model should still be covered by the claims of this utility model.
Claims
1. A batching device for processing animal feed, characterized in that, include: A mixing tank (10) is provided with a motor (11) at the bottom of the mixing tank (10). A rotating shaft (12) is provided through the bottom of the motor (11) and the top of the outer ring of the rotating shaft (12) is provided through the top of the mixing tank (10). A first drive wheel (16) is provided at the top of the rotating shaft (12) away from the motor (11). A second drive wheel (17) is provided at the end of the rotating shaft (12) away from the motor (11). The top of the mixing tank (10) is connected to a connecting box (20), and a conveying shaft (21) is provided on the side wall of the connecting box (20). A dispersing plate (23) is provided on the outer ring of the conveying shaft (21). A first driven wheel (22) is provided through the side wall of the connecting box (20) on one side of the conveying shaft (21). The first driven wheel (22) meshes with the first driving wheel (16). The side wall of the connecting box (20) is connected to the connecting tank (30), and the side wall of the connecting tank (30) is provided with a drive shaft (31). One side of the drive shaft (31) passes through the side wall of the connecting box (20) and is provided with a second driven wheel (33). The second driven wheel (33) meshes with the second driving wheel (17). The outer ring of the drive shaft (31) is provided with a propeller (32).
2. The feed dispensing device for animal feed processing according to claim 1, characterized in that: The side wall of the rotating shaft (12) is provided with stirring blades (15), and the top side wall of the rotating shaft (12) is provided with a connecting rod (13). The connecting rod (13) is located above the stirring blades (15) and does not contact them. A scraper (14) is provided at the bottom of the side of the connecting rod (13) away from the rotating shaft (12). One side of the scraper (14) is in contact with the inner wall of the mixing tank (10).
3. The feed dispensing device for animal feed processing according to claim 1, characterized in that: A pressure sensor (36) is provided on the top of the connecting tank (30), a control valve (35) is provided on the top of the pressure sensor (36), a feed hopper (34) is provided on the top of the control valve (35), and a display screen (37) is provided on the side wall of the feed hopper (34).
4. The feed dispensing device for animal feed processing according to claim 1, characterized in that: The bottom inner wall of the mixing tank (10) is inclined, and the side wall of the mixing tank (10) is provided with a discharge port (18), and the outside of the discharge port (18) is provided with a discharge valve (19).
5. The feed dispensing device for animal feed processing according to claim 1, characterized in that: The mixing tank (10) is provided with a first bearing (101) at both the top and bottom, and the rotating shaft (12) is rotatably connected to the first bearing (101).
6. The feed dispensing device for animal feed processing according to claim 1, characterized in that: The side wall of the connecting box (20) is provided with a second bearing (24), and the transmission shaft (21) is rotatably connected to the second bearing (24).
7. The feed dispensing device for animal feed processing according to claim 1, characterized in that: The side wall of the connecting box (20) and the side wall of the connecting tank (30) are both provided with a third bearing (38), and the transmission shaft (31) is rotatably connected to the third bearing (38).