A device for producing groundnut oil
By designing a sedimentation device for small-scale sesame oil production, the container is made to swing back and forth in a regular manner, which solves the problem of low sedimentation efficiency and achieves more efficient sedimentation and production.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SICHUAN XINDA MINGYANG FOOD CO LTD
- Filing Date
- 2025-04-18
- Publication Date
- 2026-06-23
AI Technical Summary
In traditional small-scale sesame oil production, the static sedimentation method is inefficient and affects production efficiency.
Design a sedimentation device for small-scale sesame oil production. Through the cooperation of the drive plate and the support frame, the container is made to swing back and forth in a regular manner, ensuring that the sesame seeds after grinding and stirring are in motion, thus accelerating the sedimentation process.
It improves sedimentation efficiency, ensures the production efficiency of sesame oil, and has greater practicality and applicability.
Smart Images

Figure CN224388150U_ABST
Abstract
Description
Technical Field
[0001] This application relates to the field of small-batch sesame oil production technology, specifically to a sedimentation device for small-batch sesame oil production. Background Technology
[0002] Sesame oil, also known as sesame seed oil, is extracted from sesame seeds. Small-batch sesame oil refers to sesame oil produced by water displacement processing, which has a stronger and purer aroma. During the production of small-batch sesame oil, the sesame seeds after grinding and stirring need to be settled. The traditional sedimentation method usually adopts static sedimentation, which has low sedimentation efficiency, thus affecting the production efficiency of small-batch sesame oil. Therefore, a sedimentation device for small-batch sesame oil production is proposed. Utility Model Content
[0003] The purpose of this application is to solve the technical problem that traditional sedimentation methods usually employ static sedimentation, which has low sedimentation efficiency and thus affects the production efficiency of sesame oil. This application provides a sedimentation device for sesame oil production.
[0004] To achieve the above objectives, this application specifically adopts the following technical solution:
[0005] A sedimentation device for producing sesame oil by small-scale grinding includes a base, a drive plate slidably mounted on the base, a first rack, a second rack, and a third rack arranged symmetrically in sequence on the drive plate, a drive rod rotatably mounted on the base, and a notched gear on the drive rod that meshes with both the first and second racks, a support frame hinged to the base, a drive gear meshing with the third rack on the hinge shaft of the support frame, a placement groove for placing containers on the support frame, and a fixing mechanism for fixing or releasing the containers on the support frame.
[0006] Furthermore, a support member is provided between the base and the support frame to support the support frame.
[0007] Furthermore, the support member includes multiple support wheels that are rotatably mounted on the support frame, and the base is constructed with an arc-shaped groove, with the support wheels rolling and overlapping the arc-shaped groove.
[0008] Furthermore, the fixing mechanism includes fixing rods that are slidably mounted on the support frame and abut against the outer wall of the container. The fixing rods are provided with fixing plates that abut against the top of the container. The support frame is provided with a driving member for driving the multiple fixing rods to slide synchronously.
[0009] Furthermore, the driving component includes a drive motor mounted on a support frame, a first bevel gear ring mounted on the output shaft of the drive motor, and a lead screw mounted on the support frame in the same number as the fixed rods and in a one-to-one threaded engagement, with a first bevel gear on the lead screw meshing with the first bevel gear ring.
[0010] Furthermore, the fixing plate is slidably mounted on the fixing rod, and a threaded screw that passes through the fixing plate is rotatably mounted on the fixing rod.
[0011] Furthermore, the support frame is provided with a drive unit for driving multiple screws to rotate synchronously.
[0012] Furthermore, the drive unit includes a second bevel gear ring and a plurality of spline rods rotatably mounted on a support frame. A fixed motor with an output shaft connected to one of the spline rods is mounted on the support frame. A second bevel gear meshing with the second bevel gear ring is mounted on the spline rod. A connecting rod is rotatably mounted on the fixed rod. A spline groove is provided on the connecting rod. The spline rod and the spline groove are slidably engaged. The connecting rod and the screw are connected by a bevel gear pair transmission.
[0013] The beneficial effects of this application are as follows:
[0014] This application abandons the traditional static sedimentation method. During use, the container can be swung back and forth regularly, keeping the sesame seeds in motion after grinding and stirring, which makes the fixed matter settle faster, thereby improving the sedimentation efficiency and ensuring the production efficiency of sesame oil. Therefore, it is more practical. Attached Figure Description
[0015] Figure 1 This is a three-dimensional structural view of this application;
[0016] Figure 2 This application Figure 1 Enlarged view of point A in the middle;
[0017] Figure 3 This application Figure 1 Enlarged view of point B in the middle;
[0018] Figure 4 This is a three-dimensional sectional view of this application;
[0019] Figure 5 This application Figure 4 Enlarged view of point C in the middle;
[0020] Figure 6 This application Figure 4 Enlarged view of point D in the middle;
[0021] Figure 7 This application Figure 4 Enlarged view of point E in the middle.
[0022] Reference numerals: 1. Base; 2. Drive plate; 3. First rack; 4. Second rack; 5. Third rack; 6. Drive rod; 7. Gear missing; 8. Support frame; 9. Drive gear; 10. Placement slot; 11. Support wheel; 12. Arc groove; 13. Fixing rod; 14. Fixing plate; 15. Drive motor; 16. First bevel gear ring; 17. Lead screw; 18. First bevel gear; 19. Screw; 20. Second bevel gear ring; 21. Spline rod; 22. Fixing motor; 23. Second bevel gear; 24. Connecting rod; 25. Spline groove; 26. Bevel gear pair. Detailed Implementation
[0023] To make the objectives, technical solutions, and advantages of the embodiments of this application clearer, the technical solutions of the embodiments of this application will be clearly and completely described below with reference to the accompanying drawings.
[0024] like Figures 1-4 As shown in one embodiment of this application, a sedimentation device for small-scale sesame oil production includes a base 1. A drive plate 2 is slidably mounted on the base 1, sliding horizontally. A first rack 3, a second rack 4, and a third rack 5 are symmetrically distributed sequentially on the drive plate 2. All three racks are horizontal and fixed to the drive plate 2, arranged symmetrically from bottom to top. A drive rod 6 is rotatably mounted on the base 1, horizontally positioned. A missing gear 7 meshes with both the first rack 3 and the second rack 4. A vertically oriented and fixedly mounted on a drive rod 6, a bearing frame 8 is hinged on a base 1. The hinge axis of the bearing frame 8 is horizontal. A drive gear 9 that meshes with a third rack 5 is provided on the hinge axis of the bearing frame 8. The drive gear 9 is vertical and fixed on the hinge axis of the bearing frame 8. A placement groove 10 for placing a container is constructed on the bearing frame 8. A fixing mechanism for fixing or unfixing the container is provided on the bearing frame 8. In this embodiment, the container refers to a large pot commonly used in the production of sesame oil. The large pot holds the sesame seeds after grinding and stirring. The shape of the placement groove 10 corresponds to the shape of the large pot. The fixing mechanism is used to fix or unfix the large pot.
[0025] In the initial state, the support frame 8 is horizontal, the drive plate 2 is in the initial position, and the missing gear 7 meshes with the first rack 3. In use, the sesame seeds after grinding and stirring are placed in the container and placed in the placement trough 10. The container is fixed by the fixing mechanism. At this time, the support frame 8 and the container form a corresponding whole, driving the drive rod 6 to rotate. In actual use, a motor should be installed on the base 1 and the output shaft of the motor should rotate with the drive rod 6. The drive rod 6 drives the missing gear 7 to rotate. The missing gear 7 will repeatedly mesh with the first rack 3 and the second rack 4, thereby causing the drive plate 2 to slide back and forth, driving the third rack 5 to move together. Through the meshing action of the third rack 5 and the drive gear 9, the support frame 8 is driven to swing back and forth. Compared with the static sedimentation method, the sedimentation efficiency is improved, thereby ensuring the production efficiency of the small-brick sesame oil. After sedimentation, the container is released from the fixing mechanism and taken out of the placement trough 10.
[0026] In summary, this application abandons the traditional static sedimentation method. During use, the container can be swung back and forth regularly, keeping the sesame seeds in motion after grinding and stirring, which allows the fixed matter to settle faster, thereby improving sedimentation efficiency and ensuring the production efficiency of sesame oil. Therefore, it is more practical.
[0027] like Figure 3 As shown, in some embodiments, a support member is provided between the base 1 and the support frame 8 to support the support frame 8;
[0028] Referring to the above, when the support frame 8 swings back and forth, the support member supports the support frame 8 without affecting the normal movement of the support frame 8, thereby improving the stability of use.
[0029] like Figure 3 As shown, in some embodiments, the support includes a plurality of support wheels 11 rotatably mounted on the support frame 8, the axis of the support wheels 11 is in the horizontal direction, the plurality of support wheels 11 are arranged in an array along the horizontal direction, and an arc groove 12 is constructed on the base 1, the support wheels 11 and the arc groove 12 roll and overlap.
[0030] Referring to the above, when the support frame 8 swings back and forth, multiple support wheels 11 roll back and forth together in the arc groove 12, thereby supporting the support frame 8 without affecting its movement.
[0031] like Figures 5-7As shown, in some embodiments, the fixing mechanism includes fixing rods 13 that are slidably disposed on the support frame 8 and abut against the outer wall of the container. The fixing rods 13 are vertical and slide in the horizontal direction. Multiple fixing rods 13 are distributed in a ring array. Fixing plates 14 that abut against the top of the container are disposed on the fixing rods 13. The fixing plates 14 are horizontal. The support frame 8 is provided with a driving member for driving multiple fixing rods 13 to slide synchronously. Synchronous sliding here refers to synchronously moving closer to or away from the placement slot 10.
[0032] Referring to the above, in the initial state, all the fixing rods 13 are far away from the placement groove 10. In use, the driving component drives the multiple fixing rods 13 to slide synchronously until they all approach the placement groove 10, until all the fixing rods 13 abut against and overlap with the outer wall of the container. The multiple fixing rods 13 together limit the container in the horizontal direction, and the multiple fixing plates 14 abut against and overlap with the top of the container. The multiple fixing plates 14 together limit the container in the vertical direction, thereby fixing the container. Conversely, the driving component drives the multiple fixing rods 13 to slide synchronously until they all move away from the placement groove 10, the multiple fixing rods 13 move away from the outer wall of the container, and the multiple fixing plates 14 move away from the top of the container, thereby releasing the container from fixation.
[0033] like Figures 5-7 As shown, in some embodiments, the driving component includes a drive motor 15 mounted on a support frame 8. The drive motor 15 is fixed on the support frame 8 and its output shaft is vertical. A first bevel gear ring 16 is mounted on the output shaft of the drive motor 15. The first bevel gear ring 16 is horizontal and fixed on the output shaft of the drive motor 15. A lead screw 17, which is the same number as the fixed rod 13 and is threadedly engaged with it, is rotatably mounted on the support frame 8. The lead screw 17 is horizontal and a first bevel gear 18 that meshes with the first bevel gear ring 16 is mounted on the lead screw 17. The first bevel gear 18 is vertical and fixed on the lead screw 17.
[0034] Referring to the above, when in use, the drive motor 15 is turned on and the output shaft rotates forward, driving the first bevel gear ring 16 to rotate. Multiple first bevel gears 18 will rotate due to meshing, driving multiple lead screws 17 to rotate synchronously. Multiple fixed rods 13 will slide synchronously to approach the placement groove 10 due to the thread action. Conversely, when the output shaft of the drive motor 15 is reversed, multiple fixed rods 13 will slide synchronously to move away from the placement groove 10 due to the thread action.
[0035] like Figures 6-7 As shown, in some embodiments, the fixing plate 14 is slidably disposed on the fixing rod 13, the fixing plate 14 slides in the vertical direction, and the fixing rod 13 is rotatably provided with a screw 19 threaded through the fixing plate 14, the screw 19 being in the vertical direction;
[0036] Referring to the above, in the initial state, the fixing plate 14 is away from the support frame 8. When the fixing rod 13 abuts against the outer wall of the container, it drives the screw 19 to rotate forward. The fixing plate 14 slides downwards towards the support frame 8 due to the thread action until the fixing plate 14 abuts against the top of the container. Conversely, it drives the screw 19 to rotate in reverse. The fixing plate 14 slides upwards away from the support frame 8 and the top of the container due to the thread action. This allows it to be used for containers of different sizes, fixing containers of different sizes and improving the flexibility and applicability of use.
[0037] like Figures 5-6 As shown, in some embodiments, the support frame 8 is provided with a drive unit for driving multiple screws 19 to rotate synchronously;
[0038] Referring to the above, during use, the drive unit drives multiple screws 19 to rotate synchronously, thereby enabling multiple fixed plates 14 to slide synchronously, making it more convenient to use.
[0039] like Figures 5-6 As shown, in some embodiments, the drive unit includes a second bevel ring 20 and a plurality of spline rods 21 rotatably mounted on a support frame 8. The second bevel ring 20 and the spline rods 21 are both horizontal. A fixed motor 22 with an output shaft connected to one of the spline rods 21 is mounted on the support frame 8. The fixed motor 22 is fixed on the support frame 8. A second bevel gear 23 that meshes with the second bevel ring 20 is mounted on the spline rod 21. The second bevel gear 23 is vertical and fixed on the spline rod 21. A connecting rod 24 is rotatably mounted on the fixed rod 13. The connecting rod 24 is horizontal and has a spline groove 25. The spline rod 21 and the spline groove 25 are in a sliding fit. The connecting rod 24 and the screw 19 are connected by a bevel gear pair 26. The bevel gear pair 26 includes two meshing bevel gears, which are respectively fixed on the connecting rod 24 and the screw 19.
[0040] Referring to the above, when the fixed rod 13 slides, it drives the connecting rod 24 to move together. The spline rod 21 and the spline groove 25 slide in a horizontal direction. In use, the fixed motor 22 is activated, and the output shaft rotates forward, driving one of the spline rods 21 and the second bevel gear 23 fixed on it to rotate together. The second bevel gear 23 will rotate due to meshing, and the other multiple second bevel gears 23 will also rotate due to meshing and drive the other multiple spline rods 21 to rotate. When the spline rod 21 rotates, it drives the connecting rod 24 to rotate through the cooperation with the spline groove 25. When the connecting rod 24 rotates, it drives the screw 19 to rotate through the bevel gear pair 26, and the fixed plate 14 slides downward. Conversely, when the output shaft of the fixed motor 22 rotates in reverse, the fixed plate 14 slides upward, so as to drive multiple screws 19 to rotate synchronously.
[0041] The above description of the disclosed embodiments enables those skilled in the art to make or use this application. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the general principles defined herein may be implemented in other embodiments without departing from the spirit or scope of this application. Therefore, this application is not to be limited to the embodiments shown herein, but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.
Claims
1. A sedimentation device for small-scale sesame oil production, characterized in that, The device includes a base (1), on which a drive plate (2) is slidably mounted. The drive plate (2) is provided with a first rack (3), a second rack (4), and a third rack (5) arranged symmetrically in sequence. A drive rod (6) is rotatably mounted on the base (1). A missing gear (7) is provided on the drive rod (6) and meshes with both the first rack (3) and the second rack (4). A support frame (8) is hinged on the base (1). A drive gear (9) meshes with the third rack (5) on the hinge shaft of the support frame (8). A placement slot (10) for placing containers is constructed on the support frame (8). A fixing mechanism for fixing or releasing the containers is provided on the support frame (8).
2. The sedimentation device for small-scale sesame oil production according to claim 1, characterized in that, A support member is provided between the base (1) and the support frame (8) to support the support frame (8).
3. The sedimentation device for small-scale sesame oil production according to claim 2, characterized in that, The support includes multiple support wheels (11) that are rotatably mounted on the support frame (8), and an arc groove (12) is constructed on the base (1), with the support wheels (11) rolling and overlapping with the arc groove (12).
4. The sedimentation device for small-scale sesame oil production according to claim 1, characterized in that, The fixing mechanism includes fixing rods (13) that are slidably mounted on the support frame (8) and all of them abut against and overlap with the outer wall of the container. The fixing rods (13) are provided with fixing plates (14) that abut against and overlap with the top of the container. The support frame (8) is provided with a driving member for driving multiple fixing rods (13) to slide synchronously.
5. The sedimentation device for small-scale sesame oil production according to claim 4, characterized in that, The driving component includes a drive motor (15) mounted on a support frame (8). The output shaft of the drive motor (15) is provided with a first bevel gear ring (16). The support frame (8) is rotatably provided with a lead screw (17) that is the same number as the fixed rod (13) and is threadedly engaged with it. The lead screw (17) is provided with a first bevel gear (18) that meshes with the first bevel gear ring (16).
6. The sedimentation device for small-scale sesame oil production according to claim 4, characterized in that, The fixing plate (14) is slidably mounted on the fixing rod (13), and the fixing rod (13) is rotatably mounted with a screw (19) threaded through the fixing plate (14).
7. The sedimentation device for small-scale sesame oil production according to claim 6, characterized in that, The support frame (8) is provided with a drive unit for driving multiple screws (19) to rotate synchronously.
8. The sedimentation apparatus for small-scale sesame oil production according to claim 7, characterized in that, The drive unit includes a second bevel ring (20) and a plurality of spline rods (21) rotatably mounted on a support frame (8). A fixed motor (22) with an output shaft connected to one of the spline rods (21) is mounted on the support frame (8). A second bevel gear (23) meshes with the second bevel ring (20) is mounted on the spline rod (21). A connecting rod (24) is rotatably mounted on the fixed rod (13). A spline groove (25) is provided on the connecting rod (24). The spline rod (21) and the spline groove (25) are slidably fitted. The connecting rod (24) and the screw (19) are connected by a bevel gear pair (26).