Livestock feed impurity removing mechanism

By combining the screening cylinder, the impurity removal tube, and the magnetic tube with the support components and threaded connections, the problem of easy screen damage is solved, achieving efficient impurity removal and reduced maintenance costs.

CN224475322UActive Publication Date: 2026-07-10FUHAI TOWN BIG TAIL SHEEP LTD LIABILITY COMPAN

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
FUHAI TOWN BIG TAIL SHEEP LTD LIABILITY COMPAN
Filing Date
2025-06-11
Publication Date
2026-07-10

AI Technical Summary

Technical Problem

In current livestock feed production, screens are easily damaged, resulting in impurities that cannot be effectively intercepted, affecting the impurity removal effect and incurring high maintenance costs.

Method used

The system employs a support assembly, a screening assembly, a motor, bearings, a first impurity removal assembly, a second impurity removal assembly, and a third impurity removal assembly. The screening cylinder, the first impurity removal tube, the magnetic tube, and the second impurity removal tube are combined via threaded connections to achieve multi-layer screening and magnetic impurity removal. Damaged parts can be replaced individually, reducing maintenance costs.

Benefits of technology

It improves the impurity removal effect, reduces maintenance costs, and ensures that the screening components can still work effectively even when partially damaged, avoiding the need for complete replacement.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses a kind of livestock feed impurity removal mechanism belong to feed impurity removal technical field, including supporting assembly, screening subassembly, motor, bearing, first impurity removal subassembly, second impurity removal subassembly and third impurity removal subassembly, the supporting assembly includes support frame;The utility model, when the device is used for a long time, first impurity removal subassembly, second impurity removal subassembly or third impurity removal subassembly is damaged, only needs to continue to use the device after the damaged part is disassembled and replaced, reduce the maintenance cost of the device, and because first impurity removal subassembly, second impurity removal subassembly and third impurity removal subassembly are threadedly connected in screening barrel, when first impurity removal subassembly or third impurity removal subassembly is damaged, screening subassembly can continue to be impurity removal structure and carry out impurity removal operation to feed, so that feed is not easy to be affected by first impurity removal subassembly or third impurity removal subassembly damage and influence its impurity removal quality.
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Description

Technical Field

[0001] This utility model belongs to the field of feed impurity removal technology, specifically relating to a livestock feed impurity removal mechanism. Background Technology

[0002] During the feed production process, various impurities, such as stones, metal scraps, and straw fragments, are often mixed into the raw materials. These impurities not only affect the nutritional balance of the feed, but may also damage the digestive system of livestock and poultry, or even cause diseases. Therefore, an efficient and reliable impurity removal mechanism has become an indispensable key link in the livestock feed production process.

[0003] During long-term use, the screen is constantly subjected to the impact and friction of feed particles. Especially when processing feed with high hardness or containing sharp impurities, the screen is prone to damage. Once the screen is damaged, impurities may not be effectively intercepted and will mix into the feed, affecting the impurity removal effect. Moreover, after the screen is broken, the entire impurity removal structure needs to be replaced, which increases maintenance costs. Therefore, a livestock feed impurity removal mechanism is needed to solve the above problems. Utility Model Content

[0004] The purpose of this invention is to provide a livestock feed impurity removal mechanism to solve the problems mentioned in the background art.

[0005] To achieve the above objectives, this utility model provides the following technical solution: a livestock feed impurity removal mechanism, comprising a support assembly, a screening assembly, a motor, a bearing, a first impurity removal assembly, a second impurity removal assembly, and a third impurity removal assembly, wherein the support assembly comprises a support frame, and the support frame has a first through groove and a second through groove.

[0006] The screening assembly includes a screening cylinder, which is rotatably connected to a support frame. The screening cylinder has a plurality of first screen holes and a plurality of second screen holes. The screening cylinder is connected to a feed pipe.

[0007] The screening cylinder is connected to the motor, and the motor is connected to the support frame;

[0008] The bearing is connected inside the support frame and outside the screening cylinder;

[0009] The first impurity removal component includes a first impurity removal tube, which is threadedly connected to the screening cylinder. The first impurity removal tube has a plurality of first impurity removal holes inside, and a first threaded groove is provided at one end of the first impurity removal tube.

[0010] The second impurity removal component includes a magnetic tube, both ends of which are connected to threaded rings, one of which is threadedly connected to a first threaded groove.

[0011] The third impurity removal component includes a second impurity removal tube, which has a plurality of second impurity removal holes. One end of the second impurity removal tube has a second threaded groove, and another threaded ring is threadedly connected to the second threaded groove. The magnetic tube and the second impurity removal tube are both threadedly connected to the screening cylinder.

[0012] As a preferred embodiment, the two ends of the magnetic tube overlap with the sides of the first and second impurity removal tubes respectively.

[0013] As a preferred embodiment, the position of the first screen hole corresponds to the position of the first impurity removal hole, and the size of the first screen hole is the same as the size of the first impurity removal hole.

[0014] As a preferred embodiment, the position of the second screen hole corresponds to the position of the second impurity removal hole, and the size of the second screen hole is the same as the size of the second impurity removal hole.

[0015] As a preferred embodiment, the first sieve hole and the first impurity removal hole are located directly above the first through groove, and the second sieve hole and the second impurity removal hole are located directly above the second through groove.

[0016] As a preferred embodiment, the screening cylinder is inclined, and the first impurity removal tube, the magnetic tube, and the second impurity removal tube are also inclined.

[0017] Compared with the prior art, the beneficial effects of this utility model are:

[0018] In this invention, the impurity removal structure of the device is formed by the threaded connection of a first impurity removal component, a second impurity removal component, and a third impurity removal component. When the device is used for a long time and the first, second, or third impurity removal component is damaged, the device can continue to be used simply by disassembling and replacing the damaged part, which reduces the maintenance cost of the device. Furthermore, since the first, second, and third impurity removal components are threadedly connected inside the screening cylinder, when the first or third impurity removal component is damaged, the screening component can continue to perform impurity removal on the feed as an impurity removal structure, making it less likely that the impurity removal quality of the feed will be affected by the damage to the first or third impurity removal component.

[0019] This utility model, by providing a first threaded groove, a second threaded groove, and a threaded ring, with the two threaded rings respectively threadedly connected in the first threaded groove and the second threaded groove, allows the threaded ring threaded in the first threaded groove to connect the first impurity removal tube and the magnetic tube together, and the threaded ring threaded in the second threaded groove can connect the second impurity removal tube and the magnetic tube together. Attached Figure Description

[0020] Figure 1 This is a three-dimensional structural diagram of the present invention from the front view;

[0021] Figure 2 This is a side-view three-dimensional structural schematic diagram of the present invention;

[0022] Figure 3 This is a frontal three-dimensional cross-sectional structural diagram of the present invention;

[0023] Figure 4 This is a partial frontal three-dimensional structural schematic diagram of the present invention.

[0024] In the diagram: 1. Support assembly; 11. Support frame; 12. First through groove; 13. Second through groove; 2. Screening assembly; 21. Screening cylinder; 22. Feed pipe; 23. First screen hole; 24. Second screen hole; 3. Motor; 4. Bearing; 5. First impurity removal assembly; 51. First impurity removal pipe; 52. First impurity removal hole; 53. First threaded groove; 6. Second impurity removal assembly; 61. Magnetic tube; 62. Threaded ring; 7. Third impurity removal assembly; 71. Second impurity removal pipe; 72. Second impurity removal hole; 73. Second threaded groove. Detailed Implementation

[0025] The present invention will be further described below with reference to the embodiments.

[0026] The following embodiments are used to illustrate the present invention, but should not be used to limit the scope of protection of the present invention. The conditions in the embodiments can be further adjusted according to specific conditions, and simple improvements to the method of the present invention under the premise of the concept of the present invention are all within the scope of protection claimed by the present invention.

[0027] Please see Figure 1-4 This utility model provides a livestock feed impurity removal mechanism, including a support component 1, a screening component 2, a motor 3, a bearing 4, a first impurity removal component 5, a second impurity removal component 6 and a third impurity removal component 7. The support component 1 includes a support frame 11, and a first through groove 12 and a second through groove 13 are provided in the support frame 11.

[0028] The screening assembly 2 includes a screening cylinder 21, which is rotatably connected to the support frame 11. The screening cylinder 21 has a plurality of first screen holes 23 and a plurality of second screen holes 24. The screening cylinder 21 is connected to the feed pipe 22.

[0029] The screening cylinder 21 is connected to the motor 3, and the motor 3 is connected to the support frame 11. By setting the motor 3, the working motor 3 can drive the screening cylinder 21 to rotate.

[0030] The bearing 4 is connected inside the support frame 11 and outside the screening cylinder 21. By setting the bearing 4, the screening cylinder 21 can be limited and fixed inside the support frame 11.

[0031] The first impurity removal component 5 includes a first impurity removal tube 51, which is threadedly connected to the screening cylinder 21. The first impurity removal tube 51 has a plurality of first impurity removal holes 52 inside it, and a first threaded groove 53 is provided at one end of the first impurity removal tube 51.

[0032] The second impurity removal component 6 includes a magnetic tube 61, with threaded rings 62 connected to both ends of the magnetic tube 61, one of which is threadedly connected to the first threaded groove 53.

[0033] The third impurity removal component 7 includes a second impurity removal tube 71, which has several second impurity removal holes 72. One end of the second impurity removal tube 71 has a second threaded groove 73, and another threaded ring 62 is threaded into the second threaded groove 73. The magnetic tube 61 and the second impurity removal tube 71 are both threaded into the screening cylinder 21. By providing the first threaded groove 53, the second threaded groove 73 and the threaded ring 62, since the two threaded rings 62 are respectively threaded into the first threaded groove 53 and the second threaded groove 73, the threaded ring 62 threaded into the first threaded groove 53 can connect the first impurity removal tube 51 and the magnetic tube 61 together, and the threaded ring 62 threaded into the second threaded groove 73 can connect the second impurity removal tube 71 and the magnetic tube 61 together.

[0034] The two ends of the magnetic tube 61 are respectively connected to the side of the first impurity removal tube 51 and the second impurity removal tube 71 that are close to each other. The position of the first screen hole 23 corresponds to the position of the first impurity removal hole 52. The size of the first screen hole 23 is the same as the size of the first impurity removal hole 52. The position of the second screen hole 24 corresponds to the position of the second impurity removal hole 72. The size of the second screen hole 24 is the same as the size of the second impurity removal hole 72. The first screen hole 23 and the first impurity removal hole 52 are located directly above the first through groove 12. The second screen hole 24 and the second impurity removal hole 72 are located directly above the second through groove 13. The screening cylinder 21 is inclined. The first impurity removal tube 51, the magnetic tube 61 and the second impurity removal tube 71 are inclined.

[0035] The working principle and usage process of this utility model are as follows: When the device needs to be used, the first storage bucket and the second storage bucket are moved into the first through groove 12 and the second through groove 13 respectively, and the first storage bucket and the second storage bucket are moved directly below the plurality of first impurity removal holes 52 and the plurality of second impurity removal holes 72 respectively.

[0036] Feed is poured into the screening cylinder 21 through the feed pipe 22. The feed falls into the screening cylinder 21 and the motor 3 is controlled to work. The working motor 3 drives the screening cylinder 21 to rotate in the bearing 4. Under the action of the tilted and rotating screening cylinder 21, the feed moves sequentially into the first impurity removal pipe 51, the magnetic pipe 61 and the second impurity removal pipe 71.

[0037] Feed of the correct size passes through the first impurity removal hole 52 and the first sieve hole 23 and falls into the first storage bucket placed in the first channel 12;

[0038] Then the magnetic tube 61 filters the metal impurities in the feed, and the feed moves into the second impurity removal tube 71. Larger impurities in the second impurity removal tube 71 can pass through the second impurity removal hole 72 and the second screen hole 24 and move into the second storage bucket in the second channel 13. Then, larger feed can be discharged from the bottom of the screening cylinder 21.

[0039] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. A livestock feed impurity removal mechanism, comprising a support assembly (1), a screening assembly (2), a motor (3), a bearing (4), a first impurity removal assembly (5), a second impurity removal assembly (6), and a third impurity removal assembly (7), characterized in that: The support assembly (1) includes a support frame (11), and the support frame (11) has a first through groove (12) and a second through groove (13). The screening assembly (2) includes a screening cylinder (21), which is rotatably connected to the support frame (11). The screening cylinder (21) has a plurality of first screen holes (23) and a plurality of second screen holes (24) inside. The screening cylinder (21) is connected to the feed pipe (22). The screening cylinder (21) is connected to the motor (3), and the motor (3) is connected to the support frame (11); The bearing (4) is connected inside the support frame (11) and outside the screening cylinder (21); The first impurity removal component (5) includes a first impurity removal tube (51), which is threadedly connected to the screening cylinder (21). The first impurity removal tube (51) has a plurality of first impurity removal holes (52) inside, and a first threaded groove (53) is provided at one end of the first impurity removal tube (51). The second impurity removal component (6) includes a magnetic tube (61), both ends of which are connected to threaded rings (62), one of which is threadedly connected to a first threaded groove (53). The third impurity removal component (7) includes a second impurity removal tube (71), which has a plurality of second impurity removal holes (72). One end of the second impurity removal tube (71) has a second threaded groove (73), and another threaded ring (62) is threadedly connected to the second threaded groove (73). The magnetic tube (61) and the second impurity removal tube (71) are both threadedly connected to the screening cylinder (21).

2. The livestock feed impurity removal mechanism according to claim 1, characterized in that: The two ends of the magnetic tube (61) overlap with the sides of the first impurity removal tube (51) and the second impurity removal tube (71) respectively.

3. The livestock feed impurity removal mechanism according to claim 1, characterized in that: The position of the first sieve hole (23) corresponds to the position of the first impurity removal hole (52), and the size of the first sieve hole (23) is the same as the size of the first impurity removal hole (52).

4. The livestock feed impurity removal mechanism according to claim 1, characterized in that: The position of the second sieve hole (24) corresponds to the position of the second impurity removal hole (72), and the size of the second sieve hole (24) is the same as the size of the second impurity removal hole (72).

5. The livestock feed impurity removal mechanism according to claim 1, characterized in that: The first sieve hole (23) and the first impurity removal hole (52) are located directly above the first through groove (12), and the second sieve hole (24) and the second impurity removal hole (72) are located directly above the second through groove (13).

6. The livestock feed impurity removal mechanism according to claim 1, characterized in that: The screening cylinder (21) is inclined, and the first impurity removal tube (51), magnetic tube (61) and second impurity removal tube (71) are inclined.