A plant pulp concentration and extraction device
By designing a vibration structure for the crushing and sieve components, the problems of clogging of the arc-shaped filter plate and low conveying efficiency were solved, achieving efficient concentration and extraction of plant pulp.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- ANHUI YIKOUWANG HEALTH IND DEVELOPMENT CO LTD
- Filing Date
- 2025-07-28
- Publication Date
- 2026-07-03
AI Technical Summary
In existing plant pulp concentration and extraction equipment, the arc-shaped filter plate is prone to clogging during use, and the viscosity of the plant pulp leads to low conveying efficiency, which affects the concentration and extraction efficiency.
A plant pulp concentration and extraction device was designed, which uses a crushing component and a screen component. Through the cooperation of a drive rod and a convex rod, the screen vibrates and the inner tube moves back and forth to avoid clogging. The concentrated pulp is heated by a heating plate.
It effectively avoids clogging of the screen and branch pipes, and improves the efficiency of transporting and concentrating plant pulp extract.
Smart Images

Figure CN224442353U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of plant pulp extraction technology, specifically to a plant pulp concentration and extraction device. Background Technology
[0002] Plant extract is a concentrated product of natural ingredients that is purified from plants using modern extraction technology. It retains the effective active ingredients of plants and is widely used in skin care, health care and other fields. In order to remove impurities from plant extract and improve its purity, it is necessary to concentrate and extract the plant extract.
[0003] Patent No. 202420909339.2 discloses a plant extraction and concentration device. This device uses an auger to push the impurities after the extract is filtered into a compression cylinder for compression, thereby extracting the extract from the impurities and concentrating it, thus improving the extraction and concentration efficiency.
[0004] However, existing plant pulp concentration and extraction equipment uses arc-shaped filter plates to filter and screen the plant pulp. However, impurities in the plant pulp will adhere to the arc-shaped filter plates, causing blockage. At the same time, the plant pulp has a certain viscosity, and the plant pulp is transported slowly through pipelines, which has a certain impact on the concentration and extraction efficiency of the plant pulp. Therefore, a new plant pulp concentration and extraction equipment is needed. Utility Model Content
[0005] To address the problems in the background art, this utility model provides a plant pulp concentration and extraction device.
[0006] The technical solution adopted by this utility model to solve its technical problem is a plant pulp concentration and extraction device, including a processing box. A hopper is screwed to the top of the processing box, a branch pipe is screwed to the bottom of the processing box, and a box body is screwed to the bottom of the branch pipe. A crushing component for crushing plants is set inside the processing box. A support frame is bolted to the outside of the processing box. A support plate is bolted to the outside of the support frame A. A drive motor B is bolted to the outside of the support plate, and a drive rod is keyed to one side of the drive motor B. A protruding rod is welded to the outside of the drive rod. A toothed sleeve A is splined to the outside of the drive rod, and a synchronous belt is meshed to the outside of the toothed sleeve A. A toothed sleeve B is meshed to the inside of the synchronous belt, and a stirring rod is splined to the inside of the toothed sleeve B. A fixing block is welded to the inner wall of the processing box, and a spring A is welded inside the fixing block. A screen is welded to the end of the spring A. Springs B are symmetrically welded to the bottom inside the processing box. A connecting block is welded to the outside of the spring B, and an inner tube that enters the branch pipe is welded to the inside of the connecting block.
[0007] By adopting the above technical solution, the plants are first put into the processing box through the hopper, and then the crushing component in the processing box crushes the plants. The crushed plants are then sieved through the screen, and the original pulp in the plants flows into the box through the branch pipe. Then the heating plate in the box heats the original pulp, thereby improving the efficiency of plant pulp concentration and extraction.
[0008] When the plant pulp is screened through the screen, the drive motor A outside the support plate drives the drive rod to rotate, and the drive rod drives the externally welded protrusion to rotate. Then the protrusion contacts the bottom of the screen and pushes the screen to move upward inside the fixed block. Then the spring A inside the fixed block is compressed. As the protrusion rotates, after the protrusion moves away from the screen, the spring A inside the fixed block drives the screen to pop down, so that the screen is reset. This facilitates the vibration of the screen and avoids screen blockage.
[0009] When the protruding rod moves away from the screen, it pushes the connecting block below to move. Then, the connecting block drives the inner tube into the branch pipe. At the same time, the spring B at the bottom of the connecting box is compressed to generate elastic force. As the protruding rod moves away from the connecting block, the spring B drives the connecting block to pop up. Then, the connecting block drives the inner tube to move out of the branch pipe, so that the inner tube moves back and forth in the branch pipe, thereby avoiding blockage of the branch pipe and improving the conveying efficiency of the raw slurry.
[0010] Specifically, the crushing assembly includes a drive motor A, a crushing roller A, a crushing roller B, a gear A, and a gear B. The drive motor A, which provides power, is bolted to the outside of the processing box, and the power output end of the drive motor A is keyed to the crushing roller A.
[0011] By adopting the above technical solution, when it is necessary to drive the crushing roller A to rotate, the drive motor outside the processing box converts the received electrical energy into mechanical energy, and the drive motor drives the crushing roller A to rotate.
[0012] Specifically, the crushing roller A is externally splined to a gear A, the gear A is externally meshed to a gear B, and the crushing roller B is internally splined to a gear B.
[0013] By adopting the above technical solution, when the crushing roller B is to be rotated, the gear A outside the crushing roller A meshes with the external gear B and rotates, and then the gear B drives the crushing roller B to rotate.
[0014] Specifically, both spring A and spring B are fitted with rubber sleeves.
[0015] By adopting the above technical solution, both spring A and spring B are fitted with rubber sleeves to prevent spring A and spring B from coming into contact with the liquid in the treatment tank, thereby improving the service life of spring A and spring B.
[0016] Specifically, the input terminals of drive motor A, drive motor B, and heating plate are all electrically connected to the power supply terminal of an external power source.
[0017] By adopting the above technical solution and connecting to an external power source, the electrical equipment can operate normally.
[0018] The beneficial effects of this utility model are:
[0019] (1) The plant pulp concentration and extraction equipment of this utility model, when the plant pulp liquid is screened through the screen, the drive motor A outside the support plate drives the drive rod to rotate, the drive rod drives the externally welded protrusion to rotate, and then the protrusion contacts the bottom of the screen, pushing the screen to move upward inside the fixed block. Then the spring A inside the fixed block is compressed. As the protrusion rotates, after the protrusion moves away from the screen, the spring A inside the fixed block drives the screen to pop down, so that the screen is reset, thereby facilitating the vibration of the screen and avoiding screen blockage.
[0020] (2) In the plant pulp concentration and extraction equipment described in this utility model, when the protruding rod moves away from the screen, the protruding rod pushes the connecting block below to move. Then the connecting block drives the inner tube into the branch pipe. At the same time, the spring B at the bottom of the connecting box is compressed to generate elastic force. As the protruding rod moves away from the connecting block, the spring B drives the connecting block to pop up. Then the connecting block drives the inner tube to move out of the branch pipe, so that the inner tube moves back and forth in the branch pipe, thereby avoiding blockage of the branch pipe and improving the conveying efficiency of the plant pulp liquid. Attached Figure Description
[0021] The present invention will be further described below with reference to the accompanying drawings and embodiments.
[0022] Figure 1 This is a schematic diagram of the overall structure of a plant pulp concentration and extraction device according to the present invention;
[0023] Figure 2 This is a schematic diagram of the crushing component structure of a plant pulp concentration and extraction device according to the present invention;
[0024] Figure 3 This is a schematic diagram of the internal structure of the processing box of a plant pulp concentration and extraction device according to this utility model;
[0025] Figure 4 This is a schematic diagram of the internal structure of the box of a plant pulp concentration and extraction device according to the present invention.
[0026] In the diagram: 1. Hopper; 2. Drive motor A; 3. Support plate; 4. Synchronous belt; 5. Gear sleeve A; 6. Drive rod; 7. Drive motor B; 8. Crushing assembly; 9. Gear sleeve B; 10. Stirring rod; 11. Support frame; 12. Branch pipe; 13. Box body; 15. Processing box; 16. Crushing roller A; 17. Gear A; 18. Crushing roller B; 19. Gear B; 20. Fixing block; 21. Rubber sleeve; 22. Spring A; 23. Screen; 24. Protruding rod; 25. Spring B; 26. Connecting block; 27. Inner tube; 28. Heating plate. Detailed Implementation
[0027] To make the technical means, creative features, objectives and effects of this utility model easier to understand, the present utility model will be further described below in conjunction with specific embodiments.
[0028] To improve the efficiency of plant pulp concentration and extraction, as one embodiment of this utility model, such as... Figures 1 to 4 As shown, the plant pulp concentration and extraction equipment of this utility model includes a processing box 15. A hopper 1 is screwed to the top of the processing box 15, a branch pipe 12 is screwed to the bottom of the processing box 15, and a box body 13 is screwed to the bottom of the branch pipe 12. A crushing component 8 for crushing plants is provided inside the processing box 15. A support frame 11 is bolted to the outside of the processing box 15. A support plate 3 is bolted to the outside of the support frame 11. A drive motor B7 is bolted to the outside of the support plate 3, and a drive rod 6 is keyed to one side of the drive motor B7. A protruding rod 24 is welded on the outside of the drive rod 6. A toothed sleeve A5 is splined to the outside of the toothed sleeve A5, and a synchronous belt 4 is meshed with the outside of the toothed sleeve A5. A toothed sleeve B9 is meshed with the inside of the synchronous belt 4, and a stirring rod 10 is splined to the inside of the toothed sleeve B9. A fixing block 20 is welded to the inner wall of the processing box 15, and a spring A22 is welded inside the fixing block 20. A screen 23 is welded to the end of the spring A22. Springs B25 are symmetrically welded to the bottom inside the processing box 15. A connecting block 26 is welded to the outside of the spring B25, and an inner tube 27 that enters the branch pipe 12 is welded to the inside of the connecting block 26.
[0029] In use, the plant is first put into the processing box 15 through the hopper 1, and then the crushing component 8 in the processing box 15 crushes the plant. The crushed plant is then screened through the screen 23. The original pulp in the plant flows into the box 13 through the branch pipe 12. Then the heating plate 28 in the box 13 heats the original pulp, thereby improving the efficiency of plant pulp concentration and extraction.
[0030] When the plant pulp is screened through the screen 23, the drive motor A2 outside the support plate 3 drives the drive rod 6 to rotate. The drive rod 6 drives the externally welded protrusion 24 to rotate. Then, the protrusion 24 contacts the bottom of the screen 23, pushing the screen 23 to move upward inside the fixed block 20. Then, the spring A22 inside the fixed block 20 is compressed. As the protrusion 24 rotates, after the protrusion 24 moves away from the screen 23, the spring A22 inside the fixed block 20 drives the screen 23 to pop downward, so that the screen 23 is reset. This facilitates the vibration of the screen 23 and avoids the screen 23 from becoming blocked.
[0031] When the protruding rod 24 moves away from the screen 23, it pushes the connecting block 26 below to move. Then, the connecting block 26 drives the inner tube 27 into the branch pipe 12. At the same time, the spring B25 at the bottom of the connecting box is compressed to generate elastic force. As the protruding rod 24 moves away from the connecting block 26, the spring B25 drives the connecting block 26 to pop up. Then, the connecting block 26 drives the inner tube 27 to move out of the branch pipe 12, so that the inner tube 27 moves back and forth in the branch pipe 12, thereby avoiding blockage of the branch pipe 12 and improving the conveying efficiency of the raw slurry.
[0032] To drive the crushing roller A16 to rotate, for example, as shown... Figure 2 As shown, the present invention also includes the following: the crushing assembly 8 includes a drive motor A2, a crushing roller A16, a crushing roller B18, a gear A17, and a gear B19; the processing box 15 is externally bolted to the drive motor A2, which provides power; and the power output end of the drive motor A2 is keyed to the crushing roller A16.
[0033] When in use, when the crushing roller A16 needs to be rotated, the drive motor A2 outside the processing box 15 converts the received electrical energy into mechanical energy, and the drive motor A2 drives the crushing roller A16 to rotate.
[0034] To drive the crushing roller B18 to rotate, for example, as shown... Figure 2 As shown, the present invention also includes a gear A17 externally splined to the crushing roller A16, a gear B19 externally meshing with the gear A17, and a crushing roller B18 internally splined to the gear B19.
[0035] When in use, when the crushing roller B18 is to be rotated, the gear A17 outside the crushing roller A16 meshes with the external gear B19 and rotates, and then the gear B19 drives the crushing roller B18 to rotate.
[0036] To improve the service life of springs A22 and B25, for example, such as Figure 3 As shown, the present invention also includes rubber sleeves 21 fitted onto the outside of both spring A22 and spring B25.
[0037] During use, both springs A22 and B25 are fitted with rubber sleeves 21 to prevent them from coming into contact with the liquid inside the treatment tank 15, thus improving their service life.
[0038] For electrical equipment to function properly, for example, such as Figure 1 , Figure 4 As shown, the present invention also includes that the input terminals of the drive motor A2, drive motor B7 and heating plate 28 are all electrically connected to the power supply terminal of an external power source.
[0039] When in use, the electrical equipment works normally by connecting to an external power source, and all electrical equipment is controlled by the PLC controller.
[0040] In use, the plant is first placed into the processing box 15 through the hopper 1. The drive motor A2 outside the processing box 15, controlled by a PLC controller, converts the received electrical energy into mechanical energy. The drive motor A2 drives the crushing roller A16 to rotate. The gear A17 outside the crushing roller A16 meshes with the external gear B19, causing it to rotate. Subsequently, gear B19 drives the crushing roller B18 to rotate, completing the crushing process. Both the crushing roller A16 and the crushing roller B18 are mounted in the bearing seats of the processing box 15 using deep groove ball bearings. The bearing seats are welded to the inner wall of the processing box 15. The crushed plant then passes through a sieve. Screening is performed by screen 23. The drive motor B7 outside the support plate 3, driven by the PLC controller, rotates the drive rod 6. The drive rod 6 is mounted in the bearing seat of the processing box 15 via a deep groove ball bearing. The bearing seat is welded to the inner wall of the processing box 15 and is sealed. Then, the drive rod 6 drives the externally welded protruding rod 24 to rotate. Subsequently, the protruding rod 24 contacts the bottom of the screen 23, pushing the screen 23 upwards inside the fixed block 20. Then, the spring A22 inside the fixed block 20 is compressed. As the protruding rod 24 rotates and moves away from the screen 23, the spring A22 inside the fixed block 20 drives the screen 23 to rotate. 3. The screen 23 pops out downwards, allowing it to return to its original position, thus facilitating vibration and preventing blockage. As the protruding rod 24 moves away from the screen 23, it pushes the connecting block 26 below to move. The connecting block 26 then drives the inner tube 27 into the branch pipe 12. Simultaneously, the spring B25 at the bottom of the connecting box is compressed, generating elastic force. As the protruding rod 24 moves away from the connecting block 26, the spring B25 drives the connecting block 26 to pop out upwards. Then, the connecting block 26 drives the inner tube 27 out of the branch pipe 12, causing the inner tube 27 to reciprocate within the branch pipe 12, thus preventing blockage. To improve the efficiency of pulp delivery, the pulp from the plant flows into the box 13 through the branch pipe 12. Then, the heating plate 28 inside the box 13 heats the pulp under the action of the PLC controller. At the same time, the toothed sleeve A5 outside the drive rod 6 meshes with the external synchronous belt 4. The synchronous belt 4 meshes with the toothed sleeve B9 to rotate. The toothed sleeve B9 drives the stirring rod 10 to stir inside the box 13. The evaporated gas is discharged from the top pipe of the box 13. The stirring rod 10 is installed in the bearing seat of the box 13 through a deep groove ball bearing. The bearing seat is welded to the inner wall of the box 13 and is sealed, thereby improving the efficiency of plant pulp concentration and extraction.
[0041] The foregoing has shown and described the basic principles, main features, and advantages of this utility model. Those skilled in the art should understand that this utility model is not limited to the above embodiments. The descriptions of the above embodiments and specifications are merely illustrative of the principles of this utility model. Various changes and modifications can be made to this utility model without departing from its spirit and scope, and all such changes and modifications fall within the scope of protection claimed by this utility model. The scope of protection of this utility model is defined by the appended claims and their equivalents.
Claims
1. A plant slurry concentration extraction apparatus, characterized by, The system includes a processing box (15), with a hopper (1) screwed to the top of the processing box (15), a branch pipe (12) screwed to the bottom of the processing box (15), and a box body (13) screwed to the bottom of the branch pipe (12). The processing box (15) contains a crushing assembly (8) for crushing plants. A support frame (11) is bolted to the outside of the processing box (15). A support plate (3) is bolted to the outside of the support frame (11). A drive motor B (7) is bolted to the outside of the support plate (3), and a drive rod (6) is keyed to one side of the drive motor B (7). A protruding rod (24) is welded to the outside of the drive rod (6). 6) A toothed sleeve A (5) is connected to the outer spline, and a synchronous belt (4) is engaged with the outer side of the toothed sleeve A (5). A toothed sleeve B (9) is engaged with the inner side of the synchronous belt (4), and a stirring rod (10) is connected to the inner spline of the toothed sleeve B (9). A fixing block (20) is welded to the inner wall of the processing box (15), and a spring A (22) is welded inside the fixing block (20). A screen (23) is welded to the end of the spring A (22). A spring B (25) is symmetrically welded to the bottom of the processing box (15). A connecting block (26) is welded to the outside of the spring B (25), and an inner tube (27) that enters the branch pipe (12) is welded to the inside of the connecting block (26).
2. A plant sap concentration extraction apparatus according to claim 1, wherein, The crushing assembly (8) includes a drive motor A (2), a crushing roller A (16), a crushing roller B (18), a gear A (17), and a gear B (19). The processing box (15) is externally bolted to the drive motor A (2) which provides power. The power output end of the drive motor A (2) is keyed to the crushing roller A (16).
3. A plant sap concentration extraction apparatus according to claim 2, wherein, The crushing roller A (16) is externally splined to a gear A (17), the gear A (17) is externally meshed to a gear B (19), and the inner side of the gear B (19) is splined to a crushing roller B (18).
4. The plant sap concentration extraction apparatus according to claim 1, wherein Both spring A (22) and spring B (25) are fitted with rubber sleeves (21).
5. The plant pulp concentration and extraction equipment according to claim 2, characterized in that, The input terminals of the drive motor A (2), drive motor B (7) and heating plate (28) are all electrically connected to the power supply terminal of the external power source.