A feed structure of a food tumbling machine
By using a staggered distribution of saw gears and a rocker arm linkage structure, the problems of material clumping and adhesion to the inner wall of the food tumbler are solved, achieving efficient crushing and automatic cleaning, and improving feeding efficiency and cleaning convenience.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- HEFEI XIMENGYUAN FOOD CO LTD
- Filing Date
- 2025-06-27
- Publication Date
- 2026-07-07
AI Technical Summary
During food tumbling, the raw materials clump together, making feeding difficult, and some raw materials adhere to the inner wall of the device, causing waste and cleaning problems.
The design employs a staggered saw gear structure. The reverse rotation of the A and B rotating rods drives the staggered saw gears to form a shearing force field, breaking up agglomerated raw materials. The linkage structure of the arc groove and the rocker arm enables automatic cleaning of residues on the inner wall. The electric telescopic rod drives the rocker arm to swing and strike the box wall, which is coordinated with the spring's reset action.
It achieves efficient crushing of agglomerated raw materials, reduces raw material waste, simplifies the cleaning process, and improves feeding efficiency.
Smart Images

Figure CN224461011U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of feeding technology for food tumblers, specifically to a feeding structure for a food tumbler. Background Technology
[0002] The feeding device of a food tumbling machine disclosed in CN215836827U includes a base, with casters fixedly installed at the four opposite corners of the base bottom surface. Two symmetrically arranged fixed plates are fixedly connected to the top surface of the base. An open and horizontally placed gearbox is slidably installed on the outer side of the same side of the two fixed plates. A power mechanism is installed on the bottom surface of the gearbox cavity. The power mechanism is connected to the fixed plates through a meshing mechanism. A material container is rotatably hinged to the upper surface of the gearbox near the fixed plates. An electric hydraulic rod is hinged between the bottom end of the material container away from the fixed plates and the upper surface of the gearbox away from the fixed plates.
[0003] By incorporating a power mechanism, a meshing mechanism, and an electro-hydraulic rod, the material container can be raised and lowered, facilitating loading and unloading by operators. The electro-hydraulic rod also lifts one end of the material container for easy unloading, reducing labor intensity and improving feeding efficiency, thus demonstrating the practicality of the device.
[0004] However, during the food tumbling process, the food raw materials are affected by the air humidity and clump together, which causes inconvenience to the subsequent tumbling operation. At the same time, some raw materials will adhere to the inner wall of the device and cannot participate in the feeding, resulting in waste and inconvenience for subsequent cleaning. This solution is not efficient for feeding food tumbling processing. Utility Model Content
[0005] To address the shortcomings of existing technologies, this utility model provides a feeding structure for a food tumbler, which solves the problems of food raw materials clumping due to air humidity during feeding, causing inconvenience to subsequent tumbling operations, and some raw materials adhering to the inner wall of the device and unable to participate in feeding, resulting in waste and inconvenience for subsequent cleaning.
[0006] To achieve the above objectives, this utility model provides the following technical solution: a feeding structure for a food tumbling machine, comprising a processing box, a drive motor being provided on one side of the processing box, an A rotating rod being fixedly connected to the output end of the drive motor through the side of the processing box, an A gear being fixedly connected to one end of the A rotating rod, a B gear being meshed on one side of the A gear, a B rotating rod being provided on the surface of the B gear, and a B rotating rod being rotatably connected to the inner wall of the processing box through a bearing, and a plurality of sawing gears being provided on the surfaces of the A rotating rod and the B rotating rod, the sawing gears being distributed alternately in pairs;
[0007] The processing box has a square groove on its front side, and an electric telescopic rod is provided on the surface of the square groove. Clamping plates are provided on both sides of the electric telescopic rod. A rocker arm is movably connected to the inside of one end of the clamping plate group. A rubber rod and a spring are provided on the surface of one end of the rocker arm. One end of the spring is fixedly connected to the surface of the square groove. An arc-shaped block is provided on the surface of the other end of the rocker arm. An arc-shaped groove that matches the arc-shaped block is provided on the surface of the electric telescopic rod.
[0008] In one specific embodiment, a feeding hopper is provided on the top of the processing box, and the other side of gear A and gear B is rotatably connected to the other inner wall of the processing box via bearings.
[0009] In one specific embodiment, the rocker arm is movably connected to the inside of the clamping plate assembly via a bearing, and the rubber rod is disposed on the surface of one end of the rocker arm.
[0010] In one specific embodiment, the arc-shaped grooves are arranged at equal intervals along the axial direction of the electric telescopic rod, and the arc-shaped blocks and the arc-shaped grooves form a sliding fit.
[0011] In one specific embodiment, the spring is disposed on the surface of the rocker arm, and the two ends of the spring abut against the rocker arm and the inner wall of the square groove, respectively.
[0012] In one specific embodiment, the end of the rubber rod extends to the contact surface of the inner wall of the processing box, and the saw gears are arranged alternately along the length direction of the A rotating rod and the B rotating rod.
[0013] Compared with the prior art, this utility model provides a feeding structure for a food tumbler, which has the following beneficial effects:
[0014] In the technical solution disclosed in this utility model, the staggered distribution structure of the saw gears achieves efficient crushing of agglomerated raw materials, solving the problem of inconvenient processing caused by raw material agglomeration during tumbling. The reverse rotation of the A and B rotating rods drives the staggered saw gears to form a shearing force field, cutting and dispersing the agglomerated raw materials. Through the linkage structure design of the arc groove and the rocker arm, the automatic cleaning function of residues on the inner wall of the treatment box is realized, solving the waste and cleaning problems caused by raw materials adhering to the box wall. When the electric telescopic rod extends and retracts, the arc groove moves the arc block to drive the rocker arm to swing, and the spring stores energy to reset, causing the rubber rod to repeatedly strike the box wall. Attached Figure Description
[0015] The accompanying drawings, which are included to provide a further understanding of this application and form part of this application, illustrate exemplary embodiments of this application and are used to explain this application, but do not constitute an undue limitation of this application. In the drawings:
[0016] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0017] Figure 2 This is a schematic diagram of the processing box structure of this utility model;
[0018] Figure 3 This is a schematic diagram of the saw gear structure of this utility model;
[0019] Figure 4 This is a schematic diagram of the electric telescopic pole structure of this utility model.
[0020] In the diagram: 1. Processing box; 2. Drive motor; 3. A rotating rod; 4. A gear; 5. B gear; 6. B rotating rod; 7. Saw gear; 8. Feed hopper; 9. Electric telescopic rod; 10. Clamping plate assembly; 11. Rocker arm; 12. Rubber rod; 13. Spring; 14. Arc block; 15. Arc groove. Detailed Implementation
[0021] The following will describe in detail the implementation of this application with reference to the accompanying drawings and embodiments, so that the implementation process of how this application uses technical means to solve technical problems and achieve technical effects can be fully understood and implemented accordingly.
[0022] Figures 1-4 In one embodiment of this utility model, a feeding structure for a food tumbling machine includes a processing box 1. A drive motor 2 is provided on one side of the processing box 1. The output end of the drive motor 2 passes through the side of the processing box 1 and is fixedly connected to an A rotating rod 3. One end of the A rotating rod 3 is fixedly connected to an A gear 4. One side of the A gear 4 is meshed with a B gear 5. A B rotating rod 6 is provided on the surface of the B gear 5. One end of the B rotating rod 6 is rotatably connected to the inner wall of the processing box 1 through a bearing. A plurality of sawing gears 7 are provided on the surfaces of the A rotating rod 3 and the B rotating rod 6, and the sawing gears 7 are distributed alternately in pairs.
[0023] The specific problem addressed in this embodiment is: during food tumbling, the raw materials are affected by air humidity and clump together, causing inconvenience to subsequent tumbling operations. Simultaneously, some raw materials adhere to the inner wall of the device, preventing them from participating in the feeding process, leading to waste and subsequent cleaning difficulties. This utility model achieves efficient crushing of clumped raw materials through the staggered distribution structure design of the saw gears 7, solving the problem of processing inconvenience caused by raw material clumping during tumbling. The reverse rotation of A rotating rod 3 and B rotating rod 6 drives the staggered saw gears 7 to form a shearing force field, cutting and dispersing the clumped raw materials. The linkage structure design of the arc groove 15 and rocker arm 11 achieves automatic cleaning of residues on the inner wall of the processing box 1, solving the waste and cleaning problems caused by raw materials adhering to the box wall. When the electric telescopic rod 9 extends or retracts, it drives the rocker arm 11 to swing through the arc groove 15 and the spring 13 stores energy and resets, causing the rubber rod 12 to repeatedly strike the box wall.
[0024] A square groove is formed on the front of the processing box 1. An electric telescopic rod 9 is provided on the surface of the square groove. Clamping plate assemblies 10 are provided on both sides of the electric telescopic rod 9. A rocker arm 11 is movably connected to one end of the clamping plate assemblies 10. A rubber rod 12 and a spring 13 are provided on the surface of one end of the rocker arm 11. One end of the spring 13 is fixedly connected to the surface of the square groove. An arc-shaped block 14 is provided on the surface of the other end of the rocker arm 11. An arc-shaped groove 15 adapted to the arc-shaped block 14 is formed on the surface of the electric telescopic rod 9. In this specific embodiment, the drive motor 2 drives the A rotating rod 3 to drive the A gear 4 to rotate. 4. The meshing B gear 5 drives the B rotating rod 6 to rotate in the opposite direction, so that the interlaced saw gears 7 on the surfaces of the two rotating rods cut and crush the agglomerated raw materials; the electric telescopic rod 9 is simultaneously controlled to extend and retract, and the arc groove 15 on its surface moves the arc block 14 at the end of the rocker arm 11, forcing the rocker arm 11 to swing around the clamping plate group 10, driving the rubber rod 12 to knock off the residue from the inner wall of the processing box 1. The spring 13 provides the rocker arm 11 with the return elasticity. The interlaced saw gears 7 form a bidirectional shearing force field, which efficiently crushes the agglomerated raw materials. The telescopic rod and the rocker arm 11 realize vibration to prevent residue and reduce material waste.
[0025] In this specific embodiment, a feeding hopper 8 is provided on the top of the processing box 1, and the other side of gear A 4 and gear B 5 is rotatably connected to the other inner wall of the processing box 1 through bearings;
[0026] Raw materials enter the processing box 1 through the top feeding hopper 8. Gear A 4 and gear B 5 are supported on the inner wall of the processing box 1 by double-sided bearings to ensure the stability of the high-speed rotation of the double rotating rods.
[0027] In this specific embodiment, the rocker arm 11 is movably connected to the inside of the clamping plate assembly 10 via a bearing, and the rubber rod 12 is disposed on the surface of one end of the rocker arm 11;
[0028] The rocker arm 11 is movably connected to the inside of the clamping plate assembly 10 through a bearing to form a fulcrum, and the rubber rod 12 is fixed to the end of the rocker arm 11 and periodically impacts the box wall as it swings.
[0029] In this specific embodiment, the arc-shaped grooves 15 are arranged at equal intervals along the axial direction of the electric telescopic rod 9, and the arc-shaped block 14 and the arc-shaped grooves 15 form a sliding fit.
[0030] When the electric telescopic rod 9 extends or retracts, the arc-shaped grooves 15 arranged at equal intervals on its surface form a continuous sliding fit with the arc-shaped block 14 of the rocker arm 11, driving high-frequency oscillation.
[0031] In this specific embodiment, the spring 13 is disposed on the surface of the rocker arm 11, and the two ends of the spring 13 abut against the rocker arm 11 and the inner wall of the square groove, respectively.
[0032] Spring 13 is sleeved on the surface of rocker arm 11, with one end abutting against rocker arm 11 and the other end abutting against the inner wall of square groove. It accumulates and releases elastic potential energy when rocker arm 11 swings.
[0033] In this specific embodiment, the end of the rubber rod 12 extends to the inner wall contact surface of the processing box 1, and the saw gears 7 are arranged alternately along the length direction of the A rotating rod 3 and the B rotating rod 6;
[0034] The rubber rod 12 extends to the inner wall of the processing box 1 to achieve full coverage of the impact, and the saw gears 7 are arranged alternately along the length of the two rotating rods to form a continuous crushing zone.
[0035] Working principle: After the raw material enters the processing box 1 from the feeding hopper 8, the drive motor 2 drives the A gear 4 to rotate through the A rotating rod 3 and meshes with the B gear 5 to drive the B rotating rod 6 to rotate in the opposite direction, so that the saw gears 7 distributed in pairs on the surfaces of the two rotating rods can cut and crush the raw material in a coordinated manner; at the same time, the electric telescopic rod 9 is started to reciprocate and extend, and the arc groove 15 on its surface moves the arc block 14 at the end of the rocker arm 11, forcing the rocker arm 11 to swing around the clamping plate group 10 and repeatedly strike the inner wall of the processing box 1 through the rubber rod 12. The spring 13 abuts against the rocker arm 11 and the inner wall of the square groove to provide a restoring elastic force to enhance the vibration. The residual raw material shaken off participates in the crushing operation and is then transported to the tumbler.
[0036] 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 in the field. Since this utility model is mainly used to protect mechanical devices, the control method and circuit connection will not be explained in detail.
[0037] It should be noted that, in this document, the terms “comprising,” “including,” or any other variations thereof are intended to cover non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements includes not only those elements but also other elements not expressly listed, or elements inherent to such process, method, article, or apparatus.
[0038] 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 feeding structure for a food tumbling machine, comprising a processing chamber (1), characterized in that: A drive motor (2) is provided on one side of the processing box (1). The output end of the drive motor (2) passes through the side of the processing box (1) and is fixedly connected to the A rotating rod (3). One end of the A rotating rod (3) is fixedly connected to the A gear (4). One side of the A gear (4) is meshed with the B gear (5). The surface of the B gear (5) is provided with the B rotating rod (6). One end of the B rotating rod (6) is rotatably connected to the inner wall of the processing box (1) through a bearing. Several sawing gears (7) are provided on the surfaces of the A rotating rod (3) and the B rotating rod (6). The sawing gears (7) are distributed alternately in pairs. The processing box (1) has a square groove on its front side. An electric telescopic rod (9) is provided on the surface of the square groove. Clamping plates (10) are provided on both sides of the electric telescopic rod (9). A rocker arm (11) is movably connected to the inside of one end of the clamping plate group (10). A rubber rod (12) and a spring (13) are provided on the surface of one end of the rocker arm (11). One end of the spring (13) is fixedly connected to the surface of the square groove. An arc-shaped block (14) is provided on the surface of the other end of the rocker arm (11). An arc-shaped groove (15) adapted to the arc-shaped block (14) is opened on the surface of the electric telescopic rod (9).
2. The feeding structure of a food tumbling machine according to claim 1, characterized in that: The top of the processing box (1) is provided with a feeding hopper (8), and the other side of the A gear (4) and B gear (5) is rotatably connected to the other inner wall of the processing box (1) through bearings.
3. The feeding structure of a food tumbling machine according to claim 1, characterized in that: The rocker arm (11) is movably connected to the inside of the clamping plate assembly (10) via a bearing, and the rubber rod (12) is disposed on the surface of one end of the rocker arm (11).
4. The feeding structure of a food tumbling machine according to claim 1, characterized in that: The arc-shaped grooves (15) are arranged at equal intervals along the axial direction of the electric telescopic rod (9), and the arc-shaped block (14) and the arc-shaped grooves (15) form a sliding fit.
5. The feeding structure of a food tumbling machine according to claim 1, characterized in that: The spring (13) is disposed on the surface of the rocker arm (11), and the two ends of the spring (13) abut against the rocker arm (11) and the inner wall of the square groove, respectively.
6. The feeding structure of a food tumbling machine according to claim 1, characterized in that: The end of the rubber rod (12) extends to the inner wall contact surface of the processing box (1), and the saw gear (7) is arranged alternately along the length direction of the A rotating rod (3) and the B rotating rod (6).