A material filling structure with vibration function
By using a material filling structure with vibration function, a gear system driven by a servo motor and electric cylinder, and multiple feeding holes, the problem of uneven filling in traditional filling structures is solved, and uniform discharge of raw materials and improved filling accuracy are achieved.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SUZHOU NEW SUN UP PRECISION MOULD CO LTD
- Filing Date
- 2025-08-08
- Publication Date
- 2026-07-03
Smart Images

Figure CN224448857U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the technical field of filling devices, and more specifically, it relates to a raw material filling structure with vibration function. Background Technology
[0002] A vibrating material filling structure is a mechanical structure used for filling raw materials such as powders and granules. Its core feature is the integration of vibration function, which aims to improve the efficiency, uniformity and smoothness of material filling. Traditional material filling structures often result in uneven filling due to design limitations. This shortcoming directly affects product quality, production efficiency and material utilization. Therefore, a new type of vibrating material filling structure is needed. Utility Model Content
[0003] To address the aforementioned technical problems, this utility model provides a raw material filling structure with vibration function, thereby solving the problem of uneven filling often caused by design limitations in existing raw material filling structures during the filling process.
[0004] This utility model discloses a raw material filling structure with vibration function, which is achieved by the following specific technical means:
[0005] A raw material filling structure with vibration function includes a fixed frame, a movable tube, and a feeding tube.
[0006] The lower end of the fixing frame has four sets of round holes, and a set of fixing bolts is respectively installed in the four sets of round holes on the lower side of the fixing frame. The lower side of the fixing frame is connected to a shock-absorbing pad A, and the upper side of the fixing frame is connected to a partition plate A. A feeding pipe is provided at the center end of the partition plate A. A flexible hose is connected to the lower side of the feeding pipe. The upper inner side of the fixing frame is connected to a partition plate B. A sliding groove is provided on the partition plate B. The movable pipe is placed inside the sliding groove on the partition plate B. The flexible hose is placed inside the movable pipe. Two sets of fixing parts are respectively provided on the outer sides of the left and right ends of the movable pipe. The lower outer side of the movable pipe is connected to a fixing plate A. The second feeding pipe is movably clamped on the lower inner side of the movable pipe. The outer side of the second feeding pipe is connected to a fixing plate B. A sealing ring is fitted on the upper outer side of the second feeding pipe.
[0007] Furthermore, a servo motor is installed inside the fixed frame, and an incomplete gear is connected to the motor shaft of the servo motor. A connecting plate is connected to the outer side of the upper end of the movable tube, and a rack is connected to the connecting plate. The rack meshes with the incomplete gear.
[0008] Furthermore, the upper inner side of the fixing frame is connected to four sets of fixing tubes, and a set of connecting rods is fixedly connected to each of the four sets of fixing components. The connecting rods pass through the interior of the fixing tubes, and a circular baffle is fixedly connected to the connecting rods. A set of springs is fitted on each of the four sets of connecting rods, and a set of shock-absorbing pads B is provided on each of the four sets of fixing components.
[0009] Furthermore, the lower end of the fixed plate A is connected to two sets of electric cylinders, and the push rod of the electric cylinder is connected to the upper surface of the fixed plate B.
[0010] Furthermore, the inner side of the feeding pipe 2 is connected to four sets of fixing rods, and an outer shell is connected to the inner side of the four sets of fixing rods. A vibration motor is installed inside the outer shell, and eight sets of auxiliary feeding holes are provided on the outer side of the lower end of the feeding pipe 2.
[0011] Compared with the prior art, the present invention has the following beneficial effects:
[0012] 1. By setting up a second feeding pipe, this utility model can facilitate the discharge of raw materials from multiple directions evenly through the eight sets of auxiliary feeding holes on the lower outer side of the second feeding pipe, combined with the vibration function, thereby improving the uniformity of filling. It is especially suitable for powder and granular raw materials.
[0013] 2. This utility model is equipped with electric cylinders. Two sets of electric cylinders are connected to the lower end of the fixed plate A, and the push rod of the electric cylinder is connected to the upper surface of the fixed plate B. This allows the extension and retraction of the electric cylinders to drive the feeding tube II to move up and down along the inner side of the lower end of the movable tube, thereby adjusting the height of the feeding tube II to meet the needs of different filling depths.
[0014] 3. This utility model sets up a servo motor, and an incomplete gear is connected to the motor shaft of the servo motor. The rack meshes with the incomplete gear. When the incomplete gear rotates, the rack drives the movable tube to make lateral reciprocating motion along the slide groove of the partition B. This is beneficial for the material tube two to make reciprocating motion inside the mold when the filling space is large, further improving the filling uniformity. Attached Figure Description
[0015] Figure 1 This is a schematic diagram of the structure of this utility model.
[0016] Figure 2 This is a cross-sectional structural diagram of the partition B and the movable tube of this utility model.
[0017] Figure 3 This is a schematic diagram of the structure of the partition A and the feed pipe 1 of this utility model.
[0018] Figure 4 This is a cross-sectional structural diagram of the fixing tube of this utility model.
[0019] Figure 5 This is a cross-sectional structural diagram of the movable tube of this utility model.
[0020] Figure 6 This is a cross-sectional structural diagram of the feed tube 2 of this utility model.
[0021] In the diagram, the correspondence between component names and drawing numbers is as follows:
[0022] 1. Fixed frame; 2. Partition A; 3. Feed tube one; 4. Partition B; 5. Movable tube; 501. Connecting plate; 502. Fixing component; 6. Shock-absorbing pad A; 7. Servo motor; 8. Incomplete gear; 9. Rack; 10. Fixed tube; 11. Fixed plate A; 12. Feed tube two; 13. Fixed plate B; 14. Electric cylinder; 16. Flexible hose; 17. Connecting rod; 18. Shock-absorbing pad B; 19. Spring; 20. Housing; 21. Sealing ring. Detailed Implementation
[0023] The embodiments of this utility model will be described in further detail below with reference to the accompanying drawings and examples. The following examples are for illustrative purposes only and should not be construed as limiting the scope of this utility model. Example:
[0024] As attached Figure 1 To be continued Figure 6 As shown:
[0025] This utility model provides a raw material filling structure with vibration function, including a fixed frame 1, a movable tube 5, and a feeding tube 12;
[0026] The lower end of the fixed frame 1 is provided with four sets of round holes, and a set of fixing bolts is respectively installed in the four sets of round holes on the lower side of the fixed frame 1. The lower side of the fixed frame 1 is connected to the shock-absorbing pad A6. The upper side of the fixed frame 1 is connected to the partition plate A2, and the center end of the partition plate A2 is provided with the feed pipe 3. The lower side of the feed pipe 3 is connected to the hose 16. The upper inner side of the fixed frame 1 is connected to the partition plate B4. The partition plate B4 is provided with a sliding groove. The movable pipe 5 is placed inside the sliding groove on the partition plate B4. The hose 16 is placed inside the movable pipe 5. Two sets of fixing parts 502 are respectively provided on the outer sides of the left and right ends of the movable pipe 5. The lower outer side of the movable pipe 5 is connected to the fixing plate A11. The second feed pipe 12 is movably clamped on the lower inner side of the movable pipe 5. The outer side of the second feed pipe 12 is connected to the fixing plate B13. The upper outer side of the second feed pipe 12 is fitted with a sealing ring 21.
[0027] Among them, such as Figure 2 and Figure 4As shown, a servo motor 7 is installed inside the fixed frame 1. An incomplete gear 8 is connected to the motor shaft of the servo motor 7. A connecting plate 501 is connected to the outer side of the upper end of the movable tube 5. A rack 9 is connected to the connecting plate 501. The rack 9 meshes with the incomplete gear 8. Four sets of fixed tubes 10 are connected to the inner side of the upper end of the fixed frame 1. A set of connecting rods 17 is fixedly connected to each of the four sets of fixing parts 502. The connecting rods 17 pass through the interior of the fixed tubes 10. A circular baffle is fixedly connected to the connecting rods 17. A set of springs 19 is fitted on each of the four sets of connecting rods 17. A set of shock-absorbing pads B18 is provided on each of the four sets of fixing parts 502. The rack 9 and the incomplete gear 8 mesh together. When the full gear 8 is engaged, and the incomplete gear 8 rotates, the rack 9 drives the movable tube 5 to reciprocate laterally along the slide groove of the partition B4. The movable tube 5 passes through the connecting rod 17 connected by the fixing member 502 and enters the fixed tube 10 to form a sliding pair structure, ensuring that the movable tube 5 can only move in a straight line in a fixed direction, preventing deviation or shaking, and improving the accuracy of the filling position. The spring 19 is fitted on the connecting rod 17. When the movable tube 5 moves, the spring is compressed or stretched. The elastic force generated can not only buffer the impact of the movement, but also provide the reset power when the incomplete gear 8 and the rack 9 are separated, so that the movable tube 5 can return to the initial position smoothly and form a stable reciprocating cycle.
[0028] Among them, such as Figure 5 As shown, the lower end of the fixed plate A11 is connected to two sets of electric cylinders 14, and the push rod of the electric cylinder 14 is connected to the upper surface of the fixed plate B13. The extension and retraction of the electric cylinder 14 can drive the feeding tube 12 to move up and down along the inner side of the lower end of the movable tube 5, thereby adjusting the height of the feeding tube 12 to meet the needs of different filling depths.
[0029] Among them, such as Figure 6 As shown, four sets of fixing rods are connected inside the feeding pipe 2 12, and a set of outer shell 20 is connected to the inner side of the four sets of fixing rods. A vibration motor is installed inside the outer shell 20. Eight sets of auxiliary feeding holes are provided on the outer side of the lower end of the feeding pipe 2 12. With the vibration function, the raw materials can be discharged evenly from multiple directions, improving the uniformity of filling. It is especially suitable for powder and granular raw materials. When the vibration motor is working, it generates high-frequency vibration, which is transmitted to the raw materials inside and at the outlet through the feeding pipe 2 12, avoiding blockage caused by the stickiness or particle agglomeration of the raw materials.
[0030] The specific usage and function of this embodiment are as follows:
[0031] like Figures 1 to 6As shown, in this utility model, the rack 9 meshes with the incomplete gear 8. When the incomplete gear 8 rotates, the rack 9 drives the movable tube 5 to make a transverse reciprocating motion along the slide groove of the partition B4. The movable tube 5 passes through the connecting rod 17 connected by the fixing member 502 and enters the fixed tube 10 to form a sliding pair structure, ensuring that the movable tube 5 can only move in a straight line in a fixed direction, preventing deviation or shaking, and improving the accuracy of the filling position. The spring 19 is fitted on the connecting rod 17. When the movable tube 5 moves, the spring is compressed or stretched. The elastic force generated can not only buffer the impact of the movement, but also provide the reset power when the incomplete gear 8 and the rack 9 are separated, so that the movable tube 5 can return to the initial position smoothly and form a stable reciprocating cycle.
[0032] Any aspects of this utility model not described in detail are well-known technologies to those skilled in the art.
Claims
1. A raw material filling structure with a vibrating function, characterized by: Includes a fixed frame (1), a movable tube (5), and a discharge tube 2 (12); The lower end of the fixed frame (1) is provided with four sets of round holes, and a set of fixing bolts are respectively installed in the four sets of round holes on the lower side of the fixed frame (1). The lower side of the fixed frame (1) is connected to the shock-absorbing pad A (6), and the upper side of the fixed frame (1) is connected to the partition A (2). The center end of the partition A (2) is provided with a feed pipe 1 (3). The lower side of the feed pipe 1 (3) is connected to the hose (16). The upper inner side of the fixed frame (1) is connected to the partition B (4). The partition B (4) is provided with a sliding groove. The movable tube (5) The inner side of the groove on the partition B (4) is placed, the hose (16) is placed inside the movable tube (5), and two sets of fixing parts (502) are respectively provided on the outer side of the left and right ends of the movable tube (5). The lower end of the movable tube (5) is connected to the fixing plate A (11). The feeding tube two (12) is movably clamped on the inner side of the lower end of the movable tube (5), and the fixing plate B (13) is connected to the outer side of the feeding tube two (12). The upper end of the feeding tube two (12) is fitted with a sealing ring (21).
2. The raw material filling structure with a vibrating function according to claim 1, characterized in that: A servo motor (7) is installed on the inner side of the fixed frame (1). An incomplete gear (8) is connected to the motor shaft of the servo motor (7). A connecting plate (501) is connected to the outer side of the upper end of the movable tube (5). A rack (9) is connected to the connecting plate (501). The rack (9) meshes with the incomplete gear (8).
3. The raw material filling structure with a vibrating function according to claim 1, wherein: The upper inner side of the fixed frame (1) is connected to four sets of fixed tubes (10), and a set of connecting rods (17) are fixedly connected to each of the four sets of fixing parts (502). The connecting rods (17) are inserted into the interior of the fixed tubes (10), and a circular baffle is fixedly connected to the connecting rods (17). A set of springs (19) is fitted on each of the four sets of connecting rods (17), and a set of shock-absorbing pads B (18) is provided on each of the four sets of fixing parts (502).
4. The raw material filling structure with a vibrating function according to claim 1, wherein: The lower end of the fixed plate A (11) is connected to two sets of electric cylinders (14), and the push rod of the electric cylinder (14) is connected to the upper surface of the fixed plate B (13).
5. The raw material filling structure with a vibrating function according to claim 1, wherein: The inner side of the feeding pipe 2 (12) is connected to four sets of fixing rods, and a set of outer shell (20) is connected to the inner side of the four sets of fixing rods. A vibration motor is installed inside the outer shell (20), and eight sets of auxiliary feeding holes are provided on the outer side of the lower end of the feeding pipe 2 (12).