A sheep breeding feed throwing device
By using a servo motor-driven belt transmission system and a chopping assembly with alternating circular and square slices, the problem of uneven chopping and clogging in sheep feed delivery devices at high humidity has been solved, achieving more efficient and stable feed processing.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- XINJIANG ACADEMY OF AGRI & RECLAMATION SCI
- Filing Date
- 2025-07-31
- Publication Date
- 2026-06-26
AI Technical Summary
Existing feed dispensing devices for sheep farming are prone to causing some feed to stick to the blades when the feed moisture is high, resulting in uneven chopping and risks of blockage, noise, and vibration.
The system employs a servo motor-driven belt drive system, combined with a chopping assembly featuring alternating circular and square slices. The drive belt connects the primary and secondary conveyor wheels, while the main shaft rotates within a second bearing housing. The alternating design of circular and square slices, along with a through-type fixed column installed between them, enhances stability and reduces noise and vibration.
It improves the uniformity and efficiency of feed chopping, reduces the risk of clogging and failure, lowers noise and vibration, and enhances the stability and flexibility of the equipment.
Smart Images

Figure CN224402546U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of sheep breeding technology, and in particular to a feed delivery device for sheep breeding. Background Technology
[0002] Sheep are a common domesticated animal, with plump bodies and dense wool. They are raised all over the world. They are timid yet docile and easy to tame. Sheep can provide humans with meat and fur products, thereby increasing economic benefits. Therefore, more and more people are starting to raise sheep, which can bring huge economic benefits. In the process of raising sheep, it is necessary to provide them with feed regularly and in fixed quantities to ensure their healthy growth.
[0003] The existing feed feeding device for sheep farming, with announcement number CN221843422U, although the crushing blade 304 can break up and crush the feed, the two sets of crushing blades in this scheme have a grinding effect, which may vary depending on the type, moisture or hardness of the feed. When the feed moisture is high, some feed will stick to the blades, thus affecting the uneven cutting. Utility Model Content
[0004] This utility model addresses the shortcomings of existing technologies by providing the following technical solution:
[0005] A feed delivery device for sheep farming includes a mobile vehicle body. The mobile vehicle body includes a mounting base and wheels fixedly mounted on the bottom wall of the mounting base. A drive assembly for increasing rotational force is fixedly mounted on the upper surface of the mounting base. The drive assembly includes a servo motor, which is fixedly mounted on the upper part of the mounting base. A drive wheel is provided at the rotating end of the servo motor. A transmission belt is sleeved on the outside of the drive wheel. A secondary drive wheel is also rotatably mounted at the other end of the transmission belt. A transmission shaft is fixedly mounted in the middle of the secondary drive wheel. One end of the transmission shaft is inserted into... A feed chopping assembly is installed and fixedly mounted thereon. The feed chopping assembly includes a second bearing seat, a main shaft, circular slices, square slices, and a fixing post. One end of the main shaft is fixedly mounted to a transmission shaft, and the second bearing seat is rotatably mounted to the other end of the main shaft. Several sets of circular slices are fixedly mounted on the periphery of the main shaft, and several sets of square slices are evenly mounted at angles between each set of circular slices. Mounting holes are provided at both ends of each square slice. The fixing post is installed through the circular slices and square slices. A feed conveying assembly is provided below the feed chopping assembly.
[0006] As an improvement to the above technical solution, the drive assembly further includes a support frame, a support platform, a first bearing seat, a feed hood, a discharge hopper, and a screen. The support frame is bolted to the upper surface of the mounting base. The support platform is welded to one side of the support frame, and the bottom of the support platform is bolted to the upper surface of the mounting base. The servo motor is bolted to the upper surface of the support platform. The first bearing seat is bolted to one side of the support frame. One end of the secondary conveyor wheel and the main shaft are both inserted into the interior of the first bearing seat. The feed hood is bolted to the top of the support frame. The discharge hopper is bolted to the bottom of the support frame. The screen is fixedly installed below the support frame and located at the bottom end of the chopping assembly.
[0007] As an improvement to the above technical solution, the material transfer assembly includes a conveyor belt and a guide plate. The conveyor belt is fixedly installed on the upper surface of the mounting base and located below the feed hood. The guide plate is installed at an angle on one side of the conveyor belt.
[0008] As an improvement to the above technical solution, the top of the feeding hood is provided with a feeding port, and an arc-shaped cover plate is installed on one side of the feeding hood.
[0009] As an improvement to the above technical solution, the second bearing housing is fixedly installed on the other side of the support frame, and the other end of the main shaft is inserted into the interior of the second bearing housing.
[0010] The beneficial effects of this utility model are:
[0011] 1. The servo motor of this invention starts to rotate, driving the active conveyor wheel to rotate. The active conveyor wheel transmits power to the secondary conveyor wheel through a transmission belt, which in turn drives the transmission shaft to rotate. The rotation of the transmission shaft drives the main shaft to rotate within the second bearing seat. The circular and square blades on the main shaft rotate accordingly, chopping the feed placed in the chopping component. The alternating arrangement of the circular and square blades helps to chop the feed more efficiently and reduces the risk of clogging. After the feed is chopped, the servo motor is turned off, and the operation of the device stops. By adopting the design of alternating circular and square blades, this combination can more comprehensively cover the feed, improve chopping efficiency, and reduce the problem of uneven chopping that may be caused by a single blade shape. The fixed column installed between the circular and square blades enhances the overall stability of the blade assembly and reduces the risk of failure due to loose or falling blades. The transmission belt connects the active and secondary conveyor wheels. This transmission method is relatively smooth, reducing the noise and vibration that may be caused by direct gear transmission, and also facilitates maintenance and replacement. The transmission shaft is connected to the main shaft through the second bearing seat, providing good support and rotational stability, ensuring the smooth operation of the chopping component. Attached Figure Description
[0012] Figure 1This is a structural diagram of the present invention;
[0013] Figure 2 This is a structural diagram of the drive component of this utility model;
[0014] Figure 3 This is a structural diagram of the material transfer component of this utility model;
[0015] Figure 4 This is a structural diagram of the drive assembly and the shredding assembly of this utility model;
[0016] Figure 5 This is a structural diagram of the shredding component of this utility model.
[0017] Reference numerals: 1. Moving vehicle body; 11. Mounting base; 12. Moving wheel; 2. Drive assembly; 21. Support frame; 22. Support platform; 23. Servo motor; 231. Active conveyor wheel; 232. Transmission belt; 233. Secondary conveyor wheel; 234. Transmission shaft; 24. First bearing seat; 25. Feed hood; 251. Feed inlet; 252. Arc-shaped cover plate; 26. Discharge hopper; 27. Screen; 3. Shredding assembly; 31. Second bearing seat; 32. Main shaft; 33. Circular slice; 34. Square slice; 35. Mounting hole; 36. Fixing column; 4. Material transfer assembly; 41. Conveyor belt; 42. Guide plate. Detailed Implementation
[0018] To make the objectives, technical solutions, and advantages of this utility model clearer, the following provides a more detailed description of the utility model. It should be understood that the specific embodiments described herein are merely illustrative and not intended to limit the scope of the utility model.
[0019] Please see Figure 1-5 This utility model provides a technical solution:
[0020] A feed delivery device for sheep farming includes a mobile vehicle body 1. The mobile vehicle body 1 includes a mounting base 11 and casters 12 fixedly mounted on the bottom wall of the mounting base 11. A drive assembly 2 for increasing rotational force is fixedly mounted on the upper surface of the mounting base 11. The drive assembly 2 includes a servo motor 23, which is fixedly mounted on the upper part of the mounting base 11. A drive wheel 231 is provided at the rotating end of the servo motor 23. A transmission belt 232 is sleeved on the outside of the drive wheel 231. A secondary drive wheel 233 is also rotatably mounted at the other end of the transmission belt 232. A transmission shaft 234 is fixedly mounted in the middle of the secondary drive wheel 233. One end of the transmission shaft 234 is inserted into... A feed chopping assembly 3 is installed and fixedly mounted. The feed chopping assembly 3 includes a second bearing seat 31, a main rotating shaft 32, circular slices 33, square slices 34, and a fixing post 36. One end of the main rotating shaft 32 is fixedly mounted to the transmission rotating shaft 234, and the second bearing seat 31 is rotatably mounted to the other end of the main rotating shaft 32. Several sets of circular slices 33 are fixedly mounted on the periphery of the main rotating shaft 32, and several sets of square slices 34 are evenly mounted at angles between each set of circular slices 33. Mounting holes 35 are opened at both ends of the square slices 34. The fixing post 36 is installed through the circular slices 33 and the square slices 34. A feed conveying assembly 4 is provided below the feed chopping assembly 3.
[0021] In this implementation, the mobile vehicle 1 is moved to the feed storage area, ensuring that the moving wheels 12 are firmly supported on the ground. The installation of the drive assembly 2 and the chopping assembly 3 is checked to ensure that all components are securely connected without looseness or damage. The power is turned on, and the servo motor 23 is started. The servo motor 23 begins to rotate, driving the active conveyor wheel 231 to rotate. The active conveyor wheel 231 transmits power to the secondary conveyor wheel 233 through the transmission belt 232, which in turn drives the transmission shaft 234 to rotate. The rotation of the transmission shaft 234 drives the main shaft 32 to rotate within the second bearing seat 31. The circular slices 33 and square slices 34 on the main shaft 32 rotate accordingly, chopping the feed placed in the chopping assembly 3. The alternating arrangement of the circular slices 33 and square slices 34 helps to chop the feed more efficiently and reduces the risk of blockage. After the feed is chopped, the servo motor 23 is turned off, and the operation of the device is stopped. The alternating arrangement of round and square blades 33 and 34 allows for more comprehensive feed coverage, improving chopping efficiency and reducing uneven chopping issues that may result from a single blade shape. A fixing post 36 runs through the space between the round and square blades, enhancing the overall stability of the blade assembly and reducing the risk of malfunctions due to loose or detached blades. A drive belt 232 connects the drive wheel 231 and the secondary drive wheel 233, providing a relatively smooth transmission and reducing noise and vibration that may occur with direct gear drives. It also facilitates maintenance and replacement. The drive shaft 234 is connected to the main shaft 32 via a second bearing seat 31, providing good support and rotational stability, ensuring the smooth operation of the chopping assembly 3. The mobile vehicle 1 includes a mounting base 11 and wheels 12, allowing the device to be easily moved to different feed storage areas, improving its flexibility and applicability.
[0022] Specifically, the drive assembly 2 also includes a support frame 21, a support platform 22, a first bearing seat 24, a feed hood 25, a discharge hopper 26, and a screen 27. The support frame 21 is bolted to the upper surface of the mounting base 11. The support platform 22 is welded to one side of the support frame 21, and the bottom of the support platform 22 is bolted to the upper surface of the mounting base 11. The servo motor 23 is bolted to the upper surface of the support platform 22. The first bearing seat 24 is bolted to one side of the support frame 21. One end of the secondary conveyor wheel 233 and the main shaft 32 are both inserted into the inside of the first bearing seat 24. The feed hood 25 is bolted to the top of the support frame 21. The discharge hopper 26 is bolted to the bottom of the support frame 21. The screen 27 is fixedly installed below the support frame 21 and located at the bottom of the chopping assembly 3.
[0023] In this embodiment, the support frame 21 and the support platform 22 are firmly connected to the mounting base 11 by bolts and welding. This design provides a stable support structure, ensuring the stability of the device during operation and reducing structural loosening or damage caused by vibration or external force. One end of the secondary transmission wheel 233 and the main shaft 32 are both inserted into the interior of the first bearing seat 24, which not only improves the stability of the transmission components but also reduces the risk of transmission efficiency reduction or failure due to bearing wear. The feed hood 25 is bolted to the top of the support frame 21, providing a clear feeding path for the feed and reducing feed spillage and waste during the feeding process. It also helps to keep the working environment clean. The hopper 26 is bolted to the bottom of the support frame 21, facilitating the collection of chopped feed. The screen 27 is fixedly installed below the support frame 21 and at the bottom of the chopping component 3, which can further screen feed particles to ensure that the output feed particles are of uniform size and meet the digestive needs of sheep. The design of the feed hood 25 not only helps to guide the feed feeding but also prevents personnel from accidentally touching the chopping component 3 to a certain extent, improving the safety of operation.
[0024] Specifically, the material transfer assembly 4 includes a conveyor belt 41 and a guide plate 42. The conveyor belt 41 is fixedly installed on the upper surface of the mounting base 11 and located below the feed hood 25. The guide plate 42 is installed at an angle on one side of the conveyor belt 41.
[0025] In this embodiment, the conveyor belt 41 is fixedly installed on the upper surface of the mounting base 11 and located below the feed hood 25. This design allows the feed falling from the feed hood 25 to land directly and smoothly on the conveyor belt 41, reducing the risk of feed accumulation and blockage during the feeding process and improving feeding efficiency. The continuous operation of the conveyor belt 41 enables the device to continuously feed the feed without the need for frequent manual feeding, reducing labor intensity and improving breeding efficiency. The guide plate 42 is installed at an angle on one side of the conveyor belt 41, which can accurately guide the feed on the conveyor belt 41 to the inlet of the chopping component 3, reducing feed spillage and waste during the conveying process and ensuring full utilization of the feed. The design of the guide plate 42 provides a clear guiding path for the feed, enabling the feed to enter the chopping component 3 accurately and quickly, improving the overall operating efficiency of the device. The layout of the conveyor belt 41 and the guide plate 42 is compact and reasonable, making full use of the upper surface space of the mounting base 11, making the overall structure of the device more compact and easy to arrange and use in limited breeding space.
[0026] Specifically, the top of the feed hood 25 is provided with a feed inlet 251, and an arc-shaped cover plate 252 is installed on one side of the feed hood 25.
[0027] In this embodiment, the feed inlet 251 at the top of the feed hood 25 provides a clear feeding position, allowing operators to easily pour the feed into the device, reducing the risk of feed spillage and improving feeding convenience. The arc-shaped cover plate 252 on one side of the feed hood 25 not only provides additional protection for the feeding process, preventing feed from splashing or spilling when poured in, but also guides the feed to the feed inlet 251 to a certain extent, ensuring that the feed accurately enters the device, further improving feeding safety.
[0028] Specifically, the second bearing housing 31 is fixedly installed on the other side of the support frame 21, and the other end of the main shaft 32 is inserted into the interior of the second bearing housing 31.
[0029] In this embodiment, one end of the main rotating shaft 32 is connected to the secondary transmission wheel 233 through the first bearing seat 24, and the other end is inserted into the interior of the second bearing seat 31, forming a double bearing support structure. This greatly improves the stability of the main rotating shaft 32 and reduces its vibration and offset during high-speed rotation, thereby ensuring the smooth operation of the chopping component 3. Due to the enhanced stability of the main rotating shaft 32, the circular slices 33 and square slices 34 can maintain more precise chopping actions during rotation, improving the chopping efficiency and quality of the feed. This helps sheep to better digest and absorb the nutrients in the feed.
[0030] The above embodiments are only used to illustrate the technical solution of this utility model, and are not intended to limit it.
Claims
1. A feed delivery device for sheep farming, comprising a mobile vehicle (1), the mobile vehicle (1) including a mounting base (11) and wheels (12) fixedly mounted on the bottom wall of the mounting base (11), characterized in that: A drive assembly (2) for increasing rotational force is fixedly installed on the upper surface of the mounting base (11). The drive assembly (2) includes a servo motor (23). The servo motor (23) is fixedly installed on the upper part of the mounting base (11). An active transmission wheel (231) is provided at the rotating end of the servo motor (23). A transmission belt (232) is sleeved on the outside of the active transmission wheel (231). A secondary transmission wheel (233) is also rotatably provided at the other end of the transmission belt (232). A transmission shaft (234) is fixedly installed in the middle of the secondary transmission wheel (233). A chopping assembly (3) for chopping feed is fixedly installed at one end of the transmission shaft (234). The chopping assembly (3) includes... The components include a second bearing housing (31), a main shaft (32), circular slices (33), square slices (34), and a fixing post (36). One end of the main shaft (32) is fixedly installed with the transmission shaft (234), and the second bearing housing (31) is rotatably installed with the other end of the main shaft (32). Several sets of circular slices (33) are fixedly installed around the main shaft (32), and several sets of square slices (34) are evenly installed between each set of circular slices (33). Both ends of the square slices (34) are provided with mounting holes (35). The fixing post (36) is installed through between the circular slices (33) and the square slices (34). A feed conveying component (4) is provided below the chopping component (3).
2. The feed delivery device for sheep farming according to claim 1, characterized in that: The drive assembly (2) further includes a support frame (21), a support platform (22), a first bearing seat (24), a feed hood (25), a discharge hopper (26), and a screen (27). The support frame (21) is bolted to the upper surface of the mounting base (11). The support platform (22) is welded to one side of the support frame (21), and the bottom of the support platform (22) is bolted to the upper surface of the mounting base (11). The servo motor (23) is bolted to the support platform (25). 2) On the upper surface, the first bearing seat (24) is bolted to one side of the support frame (21), and one end of the secondary conveyor wheel (233) and the main shaft (32) are both inserted into the inside of the first bearing seat (24). The feed cover (25) is bolted to the top of the support frame (21), and the hopper (26) is bolted to the bottom of the support frame (21). The screen (27) is fixedly installed below the support frame (21) and located at the bottom of the chopping assembly (3).
3. The feed delivery device for sheep farming according to claim 1, characterized in that: The material transfer assembly (4) includes a conveyor belt (41) and a guide plate (42). The conveyor belt (41) is fixedly installed on the upper surface of the mounting base (11) and located below the feed hood (25). The guide plate (42) is installed at an angle on one side of the conveyor belt (41).
4. The feed delivery device for sheep farming according to claim 2, characterized in that: The top of the feed hood (25) is provided with a feed inlet (251), and an arc-shaped cover plate (252) is provided on one side of the feed hood (25).
5. The feed delivery device for sheep farming according to claim 1, characterized in that: The second bearing housing (31) is fixedly installed on the other side of the support frame (21), and the other end of the main shaft (32) is inserted into the interior of the second bearing housing (31).