A chicken feed stirring device
By setting a detachable storage bin on the mounting frame and combining it with a linear displacement and tilting mechanism, the problem of inconvenient cleaning and maintenance caused by fixed installation of storage bins is solved, realizing convenient operation and efficient mixing of the storage bin, and improving production efficiency and chicken feed quality.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- CHENGKOU QIHANG AGRI DEV CO LTD
- Filing Date
- 2025-07-08
- Publication Date
- 2026-07-14
Smart Images

Figure CN224485779U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the technical field of feed mixing devices, specifically a chicken feed mixing device. Background Technology
[0002] Chicken feed generally includes natural chicken feed and formulated chicken feed. Natural chicken feed refers to single-type raw materials such as rice, wheat, sweet potato, and papaya without special treatment. Formulated chicken feed refers to a mixture of various natural feeds, salt, and dicalcium phosphate, which are then made into pelleted feed suitable for chickens at different stages. Each type of chicken feed has its own advantages and disadvantages. In the production process of mixed chicken feed, the mixing device is an indispensable piece of equipment. An existing chicken feed mixing device with the publication number CN221815884 U uses a circular storage tank to store various raw materials. This circular storage tank has a significant drawback: the storage tank is fixedly installed on the gantry and cannot be disassembled. This makes it very inconvenient to clean, maintain, or replace the storage tank, increases the labor intensity of workers, and affects production efficiency. Utility Model Content
[0003] This utility model mainly provides a chicken feed mixing device, which solves the problem that the existing technology has a feed storage tank that is fixedly installed on the gantry frame and cannot be disassembled for cleaning, maintenance or replacement.
[0004] To solve the above-mentioned technical problems, the present invention adopts the following technical solution:
[0005] A chicken feed mixing device includes a mounting frame with multiple compartments arranged in a straight line. Each compartment is detachably connected to a storage bin. A first linear displacement mechanism is provided on the mounting frame above each storage bin, with a first displacement frame and a lifting mechanism. The lower end of the lifting mechanism is provided with a clamping mechanism for holding the storage bin. A second linear displacement mechanism is provided on the mounting frame below each storage bin, with a second displacement frame. A mixing bin is rotatably connected to the displacement frame, and a turning mechanism for rotating the mixing bin is provided. A mixing mechanism is provided on the mixing bin. A feeding channel is provided at the lower end of each storage bin, with a feeding valve on the feeding channel. The mixing bin has an inlet / outlet, with inlet / outlet valves on the inlet / outlet. Specifically, the material discharge channel of the storage silo can be equipped with structures similar to those in existing technology, such as electric push rods and telescopic tubes. The area of the inlet and outlet should be larger than the area of the discharge channel and the telescopic tube, allowing the telescopic tube to enter the range of the inlet and outlet pipes for stable material discharge. Specifically, the tilting mechanism can use a drag chain cable arrangement. Specifically, since the tilting mechanism needs to drive the mixing silo to rotate, and the tilting silo is equipped with a mixing mechanism, the power supply for the mixing mechanism can be separately located on the mixing silo as an independent power supply. Its control method can also be achieved through signal connection, effectively avoiding cable tangling. Here, "multiple" refers to two or more. In use, when different feeds need to be mixed, the second linear displacement mechanism moves the mixing chamber below each storage silo. At this time, the mixing chamber, driven by the tilting mechanism, positions its inlet and outlet at the top and, under the linear displacement, reaches the position below the desired storage silo's discharge inlet, thus connecting the two and opening the discharge valve and inlet / outlet valves to allow material to enter the mixing chamber. Once all material has entered, the discharge valve and inlet / outlet valves close; the mixing mechanism and tilting mechanism then activate. The mixing mechanism stirs the material in the mixing chamber, while the tilting mechanism drives the mixing chamber to rotate reciprocally or horizontally. The rotation mechanism enables rapid mixing of materials. After completion, the tilting mechanism drives the mixing chamber to rotate, causing its inlet and outlet ports to shift downwards, and then the inlet and outlet valves are opened to discharge materials. When the storage hopper on the mounting frame needs to be loaded, replaced, cleaned, or maintained, the first linear displacement mechanism drives the lifting mechanism and clamping mechanism to move to the corresponding storage hopper. When the lifting mechanism drives the clamping mechanism to descend and clamps the storage hopper, the connection between the storage hopper and the mounting frame is disconnected, so that each component, in conjunction with the lifting mechanism, can lower the storage hopper to the ground, thus facilitating the corresponding maintenance operations of the storage hopper.This structure, employing multiple compartments arranged in a straight line on the mounting frame, allows for the detachable connection of a storage bin to each compartment. This detachable connection facilitates cleaning, maintenance, and replacement by staff, and also allows for pre-filling of the storage bins, reducing labor intensity. The first and second linear displacement mechanisms control the displacement of the mixing bin and the clamping mechanism, ensuring the mixing bin moves accurately to receive materials beneath each storage bin, and the clamping mechanism precisely positions the storage bins. Combined with the on / off control of the discharge valve and inlet / outlet valves, automated and precise material transfer is achieved, avoiding material spillage and waste caused by manual operation. The mixing bin is equipped with a mixing mechanism and a tilting mechanism. The mixing mechanism provides basic mixing power, while the tilting mechanism drives the mixing bin to reciprocate or rotate horizontally. The combined action of these two motions creates a multi-dimensional, all-around mixing effect within the mixing bin, significantly improving mixing uniformity and efficiency compared to a single mixing method, ensuring stable chicken feed quality.
[0006] Furthermore, a fixing frame is provided on the mounting bracket on the left and right sides of each of the storage compartments. A fixing screw is threadedly connected to the fixing frame and a fixing guide rod is slidably connected to it. A positioning block is rotatably connected to the inner end of the fixing screw. The positioning block is fixedly connected to the inner end of the fixing guide rod. Fixing grooves that cooperate with the positioning blocks on the same side are opened on the left and right sides of the storage compartment. A fixing plate is provided on the outer end of the fixing guide rod. A fixing motor for driving the fixing screw to rotate is provided on the fixing plate. The output end of the fixing motor is fixedly connected to the outer end of the fixing screw. In use, during installation of the storage silo, the lifting and clamping mechanisms elevate the silo to its corresponding position, aligning the fixing slots on both sides of the silo with the positioning blocks on the mounting frame. Rotating the fixing screw, which is threaded into the mounting frame, causes it to move inward, sliding the positioning blocks along the guide rod towards the storage silo until they are embedded in the fixing slots, thus firmly fixing the storage silo to the mounting frame. When disassembly for maintenance or replacement is required, after the clamping mechanism holds the silo, rotating the fixing screw in the opposite direction disengages the positioning blocks from the fixing slots, releasing the connection between the storage silo and the mounting frame. This structure is simple and easy to operate. The sliding cooperation between the threaded fixing screw and the guide rod allows for quick installation and disassembly of the storage silo, facilitating cleaning, maintenance, and replacement.
[0007] Furthermore, the first and second linear displacement mechanisms have the same structure. The first linear displacement mechanism includes a linear displacement screw rotatably connected to the mounting frame and a linear displacement guide rod fixedly connected to the mounting frame, as well as a first motor mounted on the mounting frame for driving the linear displacement screw to rotate. The first displacement frame is threadedly connected to the linear displacement screw and slidably connected to the linear displacement guide rod. Specifically, outwardly extending frames are symmetrically arranged on the lower side of the mounting frame, and the components of the second linear displacement mechanism are arranged on the two outwardly extending frames. Due to the arrangement of the outwardly extending frames, their width is greater than the width of the lifting mechanism, allowing the lifting mechanism to move up and down within the inner space of the grain storage bin after being clamped by the clamping mechanism. At the same time, with the width of the outwardly extending frames, the width of the second displacement frame is also large enough to allow the mixing bin to rotate within the inner opening of the second displacement frame under the drive of the tilting mechanism. In operation, when the first displacement frame needs to be moved, the first motor is started, driving the linear displacement screw to rotate. Since the first displacement frame is threadedly connected to the linear displacement screw, it moves axially along the screw under the action of the threaded transmission. Simultaneously, the linear displacement guide rod provides guidance and support for the movement of the first displacement frame, restricting its rotation and ensuring smooth movement along a straight line. The second linear displacement mechanism operates on the same principle, used to move the mixing chamber along a straight line on the mounting frame, allowing it to move below different storage silos to receive materials. This structure, employing a combination of screw drive and guide rod guidance, provides high transmission accuracy and stability, accurately controlling the movement positions of the first displacement frame and the mixing chamber, ensuring precision in material conveying and mixing. The first motor driving the screw rotation provides a high degree of automation, reducing manual operation and improving work efficiency.
[0008] Furthermore, the lifting mechanism includes lifting cylinders symmetrically arranged on the first displacement frame. Each lifting cylinder has a lifting block at its output end, and a lifting guide rod is mounted on the lifting block. The lifting guide rod is slidably connected to the first displacement frame, and an anti-detachment block is mounted on the lifting guide rod. Each lifting block is equipped with a clamping mechanism. In use, when the storage bin needs to be operated, the lifting cylinders are activated, and the output end of the lifting cylinders extends and retracts, causing the lifting blocks to move up and down. When the lifting blocks move, they cause the lifting guide rods to slide on the first displacement frame, where the lifting guide rods act as guides, ensuring smooth lifting and lowering of the lifting blocks. The anti-detachment block prevents the lifting guide rods from detaching from the first displacement frame, ensuring the safety and reliability of the lifting mechanism's operation. Through the extension and retraction control of the lifting cylinders, the clamping mechanism can accurately reach the position of the storage bin for clamping or releasing operations. This structure utilizes a cylinder-driven lifting mechanism, which features fast response and smooth lifting action. It can quickly move the clamping mechanism to the required height, improving the efficiency of storage bin maintenance and replacement operations. The lifting guide rod and anti-detachment block enhance the stability and safety of the lifting process, preventing shaking or detachment and ensuring the safety of equipment and personnel.
[0009] Furthermore, the clamping mechanism includes an L-shaped clamping arm mounted on the lifting block and a clamping cylinder for driving the clamping arm to open and close; the storage bin is provided with a clamping groove that cooperates with the L-shaped clamping arm. In use, when the lifting mechanism drives the clamping mechanism to descend to the storage bin position, the clamping cylinder is activated, and the output end of the clamping cylinder pushes or pulls the L-shaped clamping arm, causing the two L-shaped clamping arms to close together in the middle; then the L-shaped clamping arm is embedded in the clamping groove of the storage bin, and the storage bin is tightly clamped by the clamping force; when it is necessary to release the storage bin, the clamping cylinder moves in the opposite direction, and the L-shaped clamping arm opens, releasing the clamp on the storage bin. With this structure, the clamping mechanism drives the L-shaped clamping arms through the clamping cylinder, which can generate a large clamping force to ensure that the storage bin will not fall off during transportation and to ensure operational safety. The symmetrically arranged L-shaped clamping arms cooperate with the clamping grooves to clamp firmly and distribute the force evenly. This clamping method is simple to operate and quick to act, which facilitates the rapid assembly and disassembly of the storage bin and improves the maintainability and work efficiency of the equipment.
[0010] Furthermore, the tilting mechanism includes rotating shafts symmetrically arranged on the outside of the mixing chamber and rotatably connected to the second displacement frame, and a second motor mounted on the second displacement frame. The second motor drives either of the rotating shafts to rotate. In use, when stirring the material in the mixing chamber, the second motor is started, driving the rotating shafts to rotate. Since the rotating shafts are fixedly connected to the outside of the mixing chamber, the rotation of the shafts causes the mixing chamber to tilt around its axis. By controlling the forward and reverse rotation and the rotation speed of the second motor, the mixing chamber can be reciprocated or rotated horizontally, ensuring thorough mixing of the material within the mixing chamber during the tilting process. After stirring is complete, the tilting mechanism rotates the mixing chamber to a suitable angle, positioning its inlet and outlet downwards for material discharge. Using this structure, the tilting mechanism, driven by a motor, drives the rotating shafts to tilt the mixing chamber, enabling various stirring methods and improving the uniformity and efficiency of material mixing. The symmetrically arranged rotating shafts ensure smoother rotation of the mixing chamber, guaranteeing the stirring effect. This mechanism has a simple structure, can work in conjunction with the tilting mechanism, achieves high mixing efficiency, realizes automated stirring operations, and improves production efficiency.
[0011] Beneficial effects: 1. By arranging multiple compartments in a straight line on the mounting frame, each compartment can be detachably connected to a storage bin. These detachable bins facilitate cleaning, maintenance, and replacement by staff, and also allow for pre-filling, reducing labor intensity. 2. The first and second linear displacement mechanisms control the displacement of the mixing bin and the clamping mechanism, ensuring the mixing bin accurately moves to the bottom of each storage bin to receive materials, and the clamping mechanism precisely positions the storage bins. Combined with the on / off control of the discharge valve and inlet / outlet valves, automated and precise material transfer is achieved, avoiding material spillage and waste caused by manual operation. 3. The mixing bin is equipped with a mixing mechanism and a tilting mechanism. The mixing mechanism provides basic mixing power, while the tilting mechanism drives the mixing bin to reciprocate or rotate horizontally. The two motion modes work together to create a multi-dimensional, all-around mixing effect within the mixing bin. Compared to a single mixing method, this significantly improves mixing uniformity and efficiency, ensuring stable chicken feed quality. Attached Figure Description
[0012] Figure 1 This is a schematic diagram of the device in this embodiment from an oblique angle.
[0013] Figure 2 This is a top view schematic diagram of the device in this embodiment;
[0014] Figure 3 This is a side view of the device in this embodiment;
[0015] Figure 4 This embodiment Figure 1 Enlarged diagram of A in the middle;
[0016] Figure 5 This embodiment Figure 1 Enlarged diagram of B in the middle;
[0017] Figure 6 This is a front view schematic diagram of the device in this embodiment.
[0018] Reference numerals in the attached drawings: 1. Mounting frame; 2. Storage bin; 3. First linear displacement mechanism; 3. Linear displacement screw; 301. Linear displacement guide rod; 302. First motor; 303. First displacement frame; 4. Lifting mechanism; 5. Lifting cylinder; 501. Lifting block; 502. Lifting guide rod; 503. Clamping mechanism; 6. L-shaped clamping arm; 601. Clamping cylinder; 602. Second linear displacement mechanism; 7. Second displacement frame; 8. Mixing bin; 9. Tilting mechanism; 10. Mixing mechanism; 11. Discharge channel; 12. Discharge valve; 13. Inlet / outlet; 14. Inlet / outlet valve; 15. Fixing frame; 16. Positioning block; 17. Fixing motor; 18. Detailed Implementation
[0019] The following will provide a more detailed description of the technical solution of a chicken feed mixing device according to the present invention, with reference to the embodiments.
[0020] In the description of this utility model, it should be noted that, unless otherwise explicitly specified and limited, the terms "installation," "connection," and "joining" should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral connection; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium; and they can refer to the internal connection of two components. Those skilled in the art can understand the specific meaning of the above terms in this utility model based on the specific circumstances.
[0021] As shown in Figures 1 to 6, a chicken feed mixing device according to this embodiment includes a mounting frame 1. Multiple compartments are arranged in a straight line on the mounting frame 1. Each compartment is detachably connected to a storage bin 2. A first linear displacement mechanism 3 is provided on the mounting frame 1 above the storage bin 2. A first displacement frame 4 is provided on the first linear displacement mechanism 3, and a lifting mechanism 5 is provided on the first displacement frame 4. A clamping mechanism 6 for clamping the storage bin 2 is provided at the lower end of the lifting mechanism 5. A second linear displacement mechanism 7 is provided on the mounting frame 1 below the storage bin 2. A second displacement frame 8 is provided on the second linear displacement mechanism 7. A mixing bin 9 is rotatably connected to the second displacement frame 8, and a flipping mechanism 10 for rotating the mixing bin 9 is provided. A mixing mechanism 11 is provided on the mixing bin 9. A feeding channel 12 is provided at the lower end of the storage bin 2, and a feeding valve 13 is provided on the feeding channel 12. The storage bin 2 is provided with an inlet / outlet port 14, and an inlet / outlet valve 15 is provided on the inlet / outlet port 14. A fixing frame 16 is provided on the mounting frame 1 on the left and right sides of each of the bins. A fixing screw is threadedly connected to the fixing frame 16 and a fixing guide rod is slidably connected to the fixing screw. A positioning block 17 is rotatably connected to the inner end of the fixing guide rod. Fixing grooves that cooperate with the positioning block 17 on the same side are opened on the left and right sides of the storage bin 2. The first linear displacement mechanism 3 and the second linear displacement mechanism 7 have the same structure. The first linear displacement mechanism 3 includes a linear displacement screw 301 rotatably connected to the mounting frame 1 and a linear displacement guide rod 302 fixedly connected to the mounting frame 1, as well as a first motor 303 mounted on the mounting frame 1 for driving the linear displacement screw 301 to rotate. The first displacement frame 4 is threadedly connected to the linear displacement screw 301, and the first displacement frame 4 is slidably connected to the linear displacement guide rod 302. Specifically, outward extension frames are symmetrically arranged on the lower side of the mounting frame 1, and the components of the second linear displacement mechanism 7 are arranged on the two outward extension frames. Because the width of the outward extension frame is greater than the width of the lifting mechanism 5, the lifting mechanism 5 can move up and down in the inner space of the storage bin 2 after it is clamped by the clamping mechanism 6. At the same time, the width of the second displacement frame 8 is also large enough under the width of the outward extension frame, so that the mixing bin 9 can be flipped in the inner opening of the second displacement frame 8 under the drive of the flipping mechanism 10.The lifting mechanism 5 includes a lifting cylinder 501 mounted on the first displacement frame 4. A lifting block 502 is mounted at the output end of the lifting cylinder 501. A lifting guide rod 503 is mounted on the lifting block 502 and is slidably connected to the first displacement frame 4. An anti-detachment block is mounted on the lifting guide rod 503. The clamping mechanism 6 includes two L-shaped clamping arms 601 symmetrically mounted on the lifting block 502 and a clamping cylinder 602 for driving the clamping arms to open and close. The storage bin 2 has clamping grooves that cooperate with the L-shaped clamping arms 601. The flipping mechanism 10 includes rotating shafts symmetrically mounted on the outside of the mixing bin 9 and rotatably connected to the second displacement frame 8, and a second motor mounted on the second displacement frame 8. The second motor drives either of the rotating shafts to rotate. Specifically, the material discharge channel 12 of the storage silo 2 can be equipped with structures such as electric push rods and telescopic tubes similar to those in the prior art, and the area of the inlet / outlet 14 is larger than the area of the material discharge channel 12 and the telescopic tube, so that the telescopic tube can enter the range of the inlet / outlet 14 for stable material discharge. Specifically, the tilting mechanism 10 can be arranged using a drag chain cable. Specifically, since the tilting mechanism 10 needs to drive the mixing silo 9 to rotate, and the mixing silo 9 is equipped with a mixing mechanism 11, the power supply of the mixing mechanism 11 can be set separately on the mixing silo 9 as an independent power supply, and its control method can also be achieved by signal connection, effectively avoiding cable tangling.
[0022] In use, when different feeds need to be mixed, the second linear displacement mechanism 7 drives the mixing chamber 9 to move below each storage chamber 2. At this time, the mixing chamber 9, driven by the tilting mechanism 10, positions its inlet / outlet 14 above, and under the linear displacement, reaches the position below the desired discharge port of the storage chamber 2, thus connecting the two and opening the discharge valve 13 and the inlet / outlet valve 15 to allow material to enter the mixing chamber 9. After all the material has entered, the discharge valve 13 and the inlet / outlet valve 15 close. The mixing mechanism 11 and the tilting mechanism 10 start. The mixing mechanism 11 stirs the material in the mixing chamber 9, and the tilting mechanism 10 drives the mixing chamber 9 to reciprocate or rotate horizontally, thereby achieving rapid mixing of the material. After completion, the tilting mechanism 10 drives the mixing chamber 9 to rotate, moving its inlet / outlet 14 downward, and then opening the inlet / outlet valve 15 to discharge the material. When the storage chamber 2 on the mounting frame 1... When operations such as loading, replacement, cleaning, and maintenance are required, the first linear displacement mechanism 3 drives the lifting mechanism 5 and the clamping mechanism 6 to move to the corresponding storage bin 2. After the lifting mechanism 5 drives the clamping mechanism 6 to descend and clamps the storage bin 2, the connection between the storage bin 2 and the mounting frame 1 is disconnected. This allows each component to move the storage bin 2 to the ground in coordination with the lifting mechanism 5, thus facilitating the corresponding maintenance and other operations of the storage bin 2. This structure utilizes multiple compartments arranged in a straight line on the mounting frame 1, each with a detachable storage bin 2. The detachable storage bins 2 facilitate cleaning, maintenance, and replacement by staff, and also allow for pre-loading, reducing labor intensity. The first and second linear displacement mechanisms 3 and 7 control the displacement of the mixing chamber 9 and the clamping mechanism 6, ensuring the mixing chamber 9 accurately moves to the bottom of each storage bin 2 to receive materials, and the clamping mechanism 6 precisely positions the storage bins 2. Combined with the on / off control of the discharge valve 13 and the inlet / outlet valves 15, automated and precise material transfer is achieved, avoiding material spillage and waste caused by manual operation. The mixing chamber 9 is equipped with a mixing mechanism 11 and a tilting mechanism 10. The mixing mechanism 11 provides basic mixing power, while the tilting mechanism 10 drives the mixing chamber 9 to reciprocate or rotate horizontally. These two motions work together to ensure the material is properly loaded into the mixing chamber 9. It creates a multi-dimensional and all-round mixing effect, which significantly improves the mixing uniformity and efficiency compared to a single stirring method, ensuring the stability of chicken feed quality.
[0023] The control method of this utility model is automatic control through a controller. The control circuit of the controller can be implemented by simple programming by those skilled in the art. The power supply is also common knowledge or conventional technology in the field. Therefore, this utility model will not explain the control method and circuit connection in detail.
[0024] 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 chicken feed mixing device, characterized in that: The device includes a mounting frame with multiple compartments arranged in a straight line. Each compartment is detachably connected to a storage bin. A first linear displacement mechanism is installed on the mounting frame above each storage bin, and a first displacement frame is installed on the first linear displacement mechanism. A lifting mechanism is installed on the first displacement frame, and a clamping mechanism for holding the storage bin is installed at the lower end of the lifting mechanism. A second linear displacement mechanism is installed on the mounting frame below each storage bin, and a second displacement frame is installed on the second linear displacement mechanism. A mixing bin is rotatably connected to the displacement frame, and a turning mechanism for rotating the mixing bin is provided. A mixing mechanism is installed on the mixing bin. A discharge channel is provided at the lower end of each storage bin, and a discharge valve is installed on the discharge channel. An inlet and outlet are provided on the mixing bin, and inlet and outlet valves are installed on the inlet and outlet.
2. The chicken feed mixing device according to claim 1, characterized in that: A fixing frame is provided on the mounting bracket on the left and right sides of each of the aforementioned compartments. A fixing screw is threadedly connected to the fixing frame and a fixing guide rod is slidably connected to it. A positioning block is rotatably connected to the inner end of the fixing screw, and the positioning block is fixedly connected to the inner end of the fixing guide rod. Fixing grooves that mate with the positioning blocks on the same side are opened on the left and right sides of the storage compartment. A fixing plate is provided on the outer end of the fixing guide rod, and a fixing motor for driving the fixing screw to rotate is provided on the fixing plate. The output end of the fixing motor is fixedly connected to the outer end of the fixing screw.
3. The chicken feed mixing device according to claim 1, characterized in that: The first linear displacement mechanism and the second linear displacement mechanism have the same structure; the first linear displacement mechanism includes a linear displacement screw rotatably connected to the mounting frame and a linear displacement guide rod fixedly connected to the mounting frame, and a first motor disposed on the mounting frame for driving the linear displacement screw to rotate. The first displacement frame is threadedly connected to the linear displacement screw and slidably connected to the linear displacement guide rod.
4. The chicken feed mixing device according to claim 1, characterized in that: The lifting mechanism includes lifting cylinders symmetrically arranged on the first displacement frame. The output end of the lifting cylinder is provided with a lifting block. The lifting block is provided with a lifting guide rod. The lifting guide rod is slidably connected to the first displacement frame. The lifting guide rod is provided with an anti-detachment block. Each lifting block is provided with a clamping mechanism.
5. The chicken feed mixing device according to claim 4, characterized in that: The clamping mechanism includes an L-shaped clamping arm disposed on the lifting block and a clamping cylinder for driving the clamping arm to open and close; the storage bin is provided with a clamping groove that cooperates with the L-shaped clamping arm.
6. The chicken feed mixing device according to claim 1, characterized in that: The flipping mechanism includes rotating shafts symmetrically arranged on the outside of the mixing chamber and rotatably connected to the second displacement frame, and a second motor arranged on the second displacement frame, the second motor being used to drive any of the rotating shafts to rotate.