Organic fertilizer fermentation device
By combining the design of adjusting columns, pushing columns, insert blocks, and insertion holes, the problem of uneven mixing in the organic fertilizer fermentation device is solved, the materials are fully mixed, and the fermentation quality and equipment stability are improved.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- IMMEDIATELY FERTILIZER AGRICULTURAL TECHNOLOGY (HUBEI) CO LTD
- Filing Date
- 2025-07-11
- Publication Date
- 2026-07-10
AI Technical Summary
Existing organic fertilizer fermentation devices have deficiencies in stirring function and operation, resulting in material stratification and clumping, and failure to be fully and evenly stirred, which affects the uniformity of fermentation reaction and the quality stability of organic fertilizer.
An organic fertilizer fermentation device is adopted. Through the combined design of adjusting column, pushing column, insert block and insertion hole, the stirring rod can be flexibly connected and driven by the driving mechanism. This ensures that the stirring rod can be stably and evenly stirred in the fermentation device, preventing material stratification and agglomeration.
It improves the mixing effect, ensures full contact between materials and microorganisms, enhances the uniformity of fermentation reaction and the quality stability of organic fertilizer, and extends the service life of the equipment.
Smart Images

Figure CN224478049U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the technical field of organic fertilizer fermentation devices, and in particular to an organic fertilizer fermentation device. Background Technology
[0002] As global agriculture shifts towards green and sustainable development, organic fertilizers have become an indispensable production material in modern agriculture due to their advantages such as improving soil structure, enhancing the quality of agricultural products, and reducing chemical fertilizer pollution.
[0003] Regarding the above-mentioned and existing related technologies, the inventors believe that the following defects often exist: In the current field of organic fertilizer production, organic fertilizer fermentation equipment is a key piece of equipment, and its performance directly affects the fermentation quality and production efficiency of organic fertilizer. However, existing organic fertilizer fermentation equipment has obvious deficiencies in terms of stirring function and related operation. On the one hand, the stirring effect is not ideal. Most current equipment adopts a relatively simple stirring method, and the structure and movement trajectory of the stirring rod are fixed, making it difficult to fully and evenly stir the organic materials at different positions and layers in the fermentation tank. Summary of the Invention
[0004] The technical problem to be solved by this utility model is that in the existing technology, during the fermentation process, organic materials will exhibit phenomena such as stratification and clumping due to their own characteristics. The existing stirring device cannot effectively break up these stratifications and clumping, resulting in insufficient contact between the material and microorganisms, which leads to uneven and incomplete fermentation reaction, and thus affects the fertilizer efficiency and quality stability of organic fertilizer. To address this, we propose an organic fertilizer fermentation device.
[0005] To achieve the above objectives, this application adopts the following technical solution: an organic fertilizer fermentation device, comprising a fermentation device body: a driving mechanism is installed at the bottom of the fermentation device body, a connecting shaft is installed at the top of the driving mechanism through the bottom of the fermentation device body, an adjusting column is rotatably connected inside the connecting shaft, a stirring rod is provided inside the adjusting column, adjusting holes are provided at both ends of the adjusting column, arc blocks are fixedly connected at both ends inside the connecting shaft, a push column is slidably connected inside the adjusting holes, an insert block is fixedly connected to the side of the push column away from the arc block, and an insert hole is provided inside the stirring rod.
[0006] Preferably, the outer diameter surface of the adjusting column is provided with two guide grooves, and the inner wall of the connecting shaft is fixedly connected with two ring blocks.
[0007] Preferably, the size of the plug is adapted to the size of the socket, and the surface of the plug is inserted into the interior of the socket.
[0008] Preferably, a first spring is fixedly connected to the side of the push post away from the arc block, and the side of the first spring away from the push post is fixedly connected to the inside of the adjustment hole.
[0009] Preferably, the adjusting hole has sliding grooves on both sides, and the push column has sliders fixedly connected to both sides, with the surface of the sliders slidingly connected to the inside of the sliding grooves.
[0010] Preferably, limiting holes are provided on both sides of the connecting shaft, and limiting grooves are provided on both sides of the adjusting column. A limiting rod is slidably connected inside the limiting groove. A second spring is fixedly connected to the side of the limiting rod near the inside of the limiting groove, and the side of the second spring away from the limiting rod is fixedly connected to the inside of the limiting groove.
[0011] Preferably, limiting grooves are provided on both sides of the limiting groove, and limiting blocks are fixedly connected to both sides of the limiting rod, with the surface of the limiting block slidingly connected to the inside of the limiting groove.
[0012] The technical effects and advantages of this utility model are as follows:
[0013] In this invention, the operator inserts a stirring rod into the adjusting column. After the stirring rod is fully inserted, the operator rotates the adjusting column. As the adjusting column moves, it drives the push column to move as well. The operator rotates the adjusting column so that the push column contacts the thicker end of the arc block. This causes the arc block to push the push column, which in turn drives the insert block to be inserted into the insertion hole, thus defining the adjusting hole. The driving mechanism then drives the connecting shaft to stir and mix the organic fertilizer inside the fermentation device. Attached Figure Description
[0014] The disclosure of this utility model is illustrated with reference to the accompanying drawings. It should be understood that the drawings are for illustrative purposes only and are not intended to limit the scope of protection of this utility model. In the drawings, the same reference numerals are used to refer to the same parts:
[0015] Figure 1 This is a schematic diagram of the main structure of this utility model;
[0016] Figure 2 This is a schematic diagram of the connecting shaft structure of this utility model;
[0017] Figure 3 This is a partial cross-sectional view of the present invention.
[0018] Figure 4 This is a partial exploded view of the connecting shaft of this utility model;
[0019] Figure 5 This is a partial cross-sectional view of the connecting shaft of this utility model.
[0020] Legend: 1. Fermentation device body; 2. Drive mechanism; 3. Connecting shaft; 4. Adjusting column; 5. Stirring rod; 6. Adjusting hole; 7. Arc block; 8. Push column; 9. Insertion block; 10. Insertion hole; 11. Guide groove; 12. Ring block; 13. First spring; 14. Slide groove; 15. Sliding block; 16. Limiting hole; 17. Limiting groove; 18. Limiting rod; 19. Limiting groove; 20. Limiting block; 21. Second spring. Detailed Implementation
[0021] It is readily understood that, based on the technical solution of this utility model, those skilled in the art can propose various interchangeable structural methods and implementation methods without changing the essential spirit of this utility model. Therefore, the following specific embodiments and accompanying drawings are merely exemplary descriptions of the technical solution of this utility model, and should not be regarded as the entirety of this utility model or as a limitation or restriction on the technical solution of this utility model.
[0022] Reference Figures 1-5 As shown, this utility model provides a technical solution: an organic fertilizer fermentation device, including a fermentation device body 1; a drive mechanism 2 is installed at the bottom of the fermentation device body 1, and a connecting shaft 3 is installed at the top of the drive mechanism 2 through the bottom of the fermentation device body 1; an adjusting column 4 is rotatably connected inside the connecting shaft 3; a stirring rod 5 is provided inside the adjusting column 4; adjusting holes 6 are provided at both ends of the adjusting column 4; arc blocks 7 are fixedly connected to both ends inside the connecting shaft 3; a push column 8 is slidably connected inside the adjusting hole 6; and an insert is fixedly connected to the side of the push column 8 away from the arc block 7. Block 9, the stirring rod 5 has an insertion hole 10 inside. The operator inserts the stirring rod 5 into the adjusting column 4. After the stirring rod 5 is fully inserted, the operator rotates the adjusting column 4. While the adjusting column 4 is moving, it also drives the push column 8 to move. The operator rotates the adjusting column 4 so that the push column 8 contacts the thicker end of the arc block 7. The arc block 7 pushes the push column 8 to drive the insertion block 9 into the insertion hole 10, thus defining the adjusting hole 6. This drives the driving mechanism 2 to drive the connecting shaft 3 to stir and mix the organic fertilizer inside the fermentation device body 1.
[0023] Reference Figure 4 As shown in this embodiment: two guide grooves 11 are provided on the outer diameter surface of the adjusting column 4, and two ring blocks 12 are fixedly connected to the inner wall of the connecting shaft 3. When the operator rotates the adjusting column 4, the guide grooves 11 on the surface of the adjusting column 4 slide along the trajectory of the ring blocks 12, thereby ensuring the stability of the adjusting column 4 during rotation. In addition, the design of the ring blocks 12 can also effectively prevent the adjusting column 4 from shifting or shaking during rotation, thus improving the stability and durability of the overall structure.
[0024] Reference Figure 5As shown in this embodiment: the size of the plug 9 is adapted to the size of the socket 10, and the surface of the plug 9 is inserted into the interior of the socket 10, so that the plug 9 can be stably inserted into the interior of the socket 10 to achieve a tight fit, ensuring the stability of the structure, and effectively avoiding the loosening or falling off problems that may occur in traditional connection methods, further improving the reliability and durability of the overall equipment.
[0025] Reference Figure 5 As shown in this embodiment: A first spring 13 is fixedly connected to the side of the push column 8 away from the arc block 7. The side of the first spring 13 away from the push column 8 is fixedly connected to the inside of the adjustment hole 6. When the operator makes the arc block 7 contact the push column 8, the arc block 7 gradually pushes the push column 8 and squeezes the first spring 13 to compress and store force, and drives the insert block 9 to be inserted into the insertion hole 10 to limit the adjustment hole 6. When the operator rotates the adjustment column 4 to cancel the contact between the push column 8 and the arc block 7, the first spring 13 pushes the push column 8 to move in the opposite direction under the stored force, and drives the insert block 9 to be pulled out from the insertion hole 10. At this time, the adjustment hole 6 is no longer limited, which makes it convenient for the operator to replace or maintain the adjustment hole 6.
[0026] Reference Figure 5 As shown in this embodiment: sliding grooves 14 are provided on both sides of the inside of the adjustment hole 6, and sliders 15 are fixedly connected to both sides of the push column 8. The surface of the slider 15 is slidably connected to the inside of the sliding groove 14. Through the arrangement between the sliding groove 14 and the slider 15, the push column 8 can slide smoothly inside the adjustment hole 6, increasing the flexibility of operation. At the same time, the sliding connection between the slider 15 and the sliding groove 14 also plays a guiding role, ensuring that the push column 8 can move along the predetermined trajectory during the movement, avoiding the occurrence of deviation or jamming.
[0027] Reference Figure 4 and Figure 5 As shown in this embodiment: limiting holes 16 are provided on both sides of the connecting shaft 3, and limiting grooves 17 are provided on both sides of the adjusting column 4. A limiting rod 18 is slidably connected inside the limiting groove 17. A second spring 21 is fixedly connected to the side of the limiting rod 18 near the inside of the limiting groove 17. The side of the second spring 21 away from the limiting rod 18 is fixedly connected to the inside of the limiting groove 17. After the operator rotates the adjusting column 4 to limit the insertion block 9 with the insertion hole 10, the stirring rod 5 drives the position of the limiting groove 17 to be parallel to the position of the limiting hole 16. Under the action of the rebound force of the second spring 21, the limiting rod 18 is quickly inserted into the inside of the limiting hole 16 to limit the position of the adjusting column 4 and prevent it from rotating during operation.
[0028] Reference Figure 5As shown in this embodiment: limiting grooves 19 are provided on both sides of the limiting groove 17, and limiting blocks 20 are fixedly connected to both sides of the limiting rod 18. The surface of the limiting block 20 is slidably connected to the inside of the limiting groove 19. Through the setting between the limiting groove 19 and the limiting block 20, the stability and smoothness of the structure are further enhanced, the limiting rod 18 is firmly fixed inside the limiting groove 17, and can slide smoothly along the track of the limiting groove 19. This design not only improves the motion accuracy of the overall device, but also greatly extends its service life.
[0029] Working principle: The operator inserts the stirring rod 5 into the adjusting column 4. After the stirring rod 5 is fully inserted, the operator rotates the adjusting column 4. As the adjusting column 4 moves, it also moves the push column 8. Rotating the adjusting column 4 causes the push column 8 to contact the thicker end of the arc block 7, which in turn pushes the push column 8, causing the insertion block 9 to be inserted into the insertion hole 10, thus defining the adjusting hole 6. This also drives the drive mechanism 2 to move the connecting shaft 3 to stir and mix the organic fertilizer inside the fermentation device body 1. When the operator rotates the adjusting column 4, the guide groove 11 on the surface of the adjusting column 4 slides along the trajectory of the ring block 12, thereby ensuring... To ensure the stability of the adjusting column 4 during rotation, the design of the ring block 12 effectively prevents the adjusting column 4 from shifting or shaking during rotation, improving the overall stability and durability of the structure. This allows the insert block 9 to be stably inserted into the socket 10, achieving a tight fit and ensuring the structural stability. It also effectively avoids the loosening or falling off problems that may occur with traditional connection methods, further improving the overall reliability and durability of the equipment. When the operator brings the arc block 7 into contact with the push column 8, the arc block 7 gradually pushes the push column 8 and compresses the first spring 13 to store force, driving the insert block 9 to be inserted into the socket 10 to limit the adjustment hole 6. When the operator rotates the adjusting column 4 to cancel the contact between the push column 8 and the arc block 7, the first spring 13, under its stored force, pushes the push column 8 to move in the opposite direction, and drives the insert block 9 to be pulled out from the insert hole 10. At this time, the adjusting hole 6 is no longer restricted, making it easier for the operator to replace or maintain the adjusting hole 6. Through the setting between the slide groove 14 and the slider 15, the push column 8 can slide smoothly inside the adjusting hole 6, increasing the flexibility of operation. At the same time, the sliding connection between the slider 15 and the slide groove 14 also plays a guiding role, ensuring that the push column 8 can move along the predetermined trajectory during the movement, avoiding deviation or jamming. After the adjusting column 4 limits the insertion block 9 to the insertion hole 10, the stirring rod 5 drives the position of the limiting groove 17 to be parallel to the position of the limiting hole 16. Under the action of the rebound force of the second spring 21, the limiting rod 18 is quickly inserted into the inside of the limiting hole 16, limiting the position of the adjusting column 4 and preventing it from rotating during operation. The setting between the limiting groove 19 and the limiting block 20 further enhances the stability and smoothness of the structure, firmly fixing the limiting rod 18 inside the limiting groove 17, while allowing it to slide smoothly along the track of the limiting groove 19. This design not only improves the motion accuracy of the overall device, but also greatly extends its service life.
[0030] The technical scope of this utility model is not limited to the content described above. Those skilled in the art can make various modifications and variations to the above embodiments without departing from the technical concept of this utility model, and all such modifications and variations should fall within the protection scope of this utility model.
Claims
1. An organic fertilizer fermentation device, characterized in that, The fermentation device body (1) includes a driving mechanism (2) installed at the bottom of the fermentation device body (1), a connecting shaft (3) installed at the top of the driving mechanism (2) through the bottom of the fermentation device body (1), an adjusting column (4) rotatably connected inside the connecting shaft (3), a stirring rod (5) is provided inside the adjusting column (4), adjusting holes (6) are provided at both ends of the adjusting column (4), arc blocks (7) are fixedly connected at both ends inside the connecting shaft (3), a push column (8) is slidably connected inside the adjusting hole (6), an insert block (9) is fixedly connected on the side of the push column (8) away from the arc block (7), and an insert hole (10) is provided inside the stirring rod (5).
2. The organic fertilizer fermentation device according to claim 1, characterized in that: The outer diameter surface of the adjusting column (4) is provided with two guide grooves (11), and the inner wall of the connecting shaft (3) is fixedly connected with two ring blocks (12).
3. The organic fertilizer fermentation device according to claim 1, characterized in that: The size of the plug (9) is adapted to the size of the socket (10), and the surface of the plug (9) is inserted into the interior of the socket (10).
4. The organic fertilizer fermentation device according to claim 1, characterized in that: The push post (8) is fixedly connected to a first spring (13) on the side away from the arc block (7), and the side of the first spring (13) away from the push post (8) is fixedly connected to the inside of the adjustment hole (6).
5. The organic fertilizer fermentation device according to claim 1, characterized in that: The adjustment hole (6) has sliding grooves (14) on both sides, and the push column (8) has sliders (15) fixedly connected to both sides. The surface of the sliders (15) is slidably connected to the inside of the sliding grooves (14).
6. The organic fertilizer fermentation device according to claim 1, characterized in that: The connecting shaft (3) has limiting holes (16) on both sides, and the adjusting column (4) has limiting grooves (17) on both sides. A limiting rod (18) is slidably connected inside the limiting groove (17). A second spring (21) is fixedly connected to the side of the limiting rod (18) near the inside of the limiting groove (17). The side of the second spring (21) away from the limiting rod (18) is fixedly connected to the inside of the limiting groove (17).
7. The organic fertilizer fermentation device according to claim 6, characterized in that: Limiting grooves (19) are provided on both sides of the limiting groove (17), and limiting blocks (20) are fixedly connected to both sides of the limiting rod (18). The surface of the limiting block (20) is slidably connected to the inside of the limiting groove (19).