Aluminum alloy profile processing traction feeding device

By designing a traction feeding device for aluminum alloy profile processing, and utilizing a feeding cylinder and a synchronous motor-driven pulley system, the problem of low efficiency in manual feeding was solved, achieving automated feeding and stable conveying, and improving work efficiency.

CN224336366UActive Publication Date: 2026-06-09JIANGXI NANYA ALUMINIUM CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
JIANGXI NANYA ALUMINIUM CO LTD
Filing Date
2025-07-04
Publication Date
2026-06-09

AI Technical Summary

Technical Problem

In the current aluminum alloy profile processing, manual feeding is inefficient and affects work efficiency.

Method used

Design an aluminum alloy profile processing traction feeding device, including a feeding component, a traction component and a processing component. The device utilizes a feeding cylinder to push a feeding pusher plate, a synchronous motor to drive a belt pulley system and a traction wheel combination to achieve automated feeding and stable conveying.

Benefits of technology

Automated feeding has been achieved, which has improved the feeding efficiency of aluminum alloy profiles, ensured the stability of the conveying process, and reduced the cost of manual operation.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model discloses an aluminum alloy profile processing traction and feeding device, including a base and a connecting mechanism disposed inside the base. The connecting mechanism includes a feeding component, a traction component, and a processing component. The feeding component includes a feeding support plate and a feeding push plate. The traction component includes a driving pulley, a driven pulley, and a feeding belt. The processing component includes a processing platform, a processing support column, and a processing motor. When this utility model is working, the feeding cylinder pushes the feeding push plate to move at the upper limit of the limit rail to feed the material, resulting in high feeding efficiency. The synchronous motor drives the driving pulley to rotate, which in turn drives the driven pulley to rotate through the feeding belt. During the rotation of the two sets of feeding belts, the closely spaced profiles are pulled and transmitted backward. When passing the traction wheels, the eight symmetrically designed traction wheels squeeze the profiles in the middle of the feeding belts, preventing the profiles from changing direction due to shaking during the traction and conveying process. The profiles are continuously squeezed by the traction wheels, making the transportation process more stable.
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Description

Technical Field

[0001] This utility model relates to the field of aluminum alloy processing technology, specifically to a traction feeding device for aluminum alloy profile processing. Background Technology

[0002] Aluminum profiles are aluminum materials with different cross-sections obtained by hot melting and extrusion of aluminum rods. Aluminum profiles are commonly used to make door frames and various partitions. They are lighter, more aesthetically pleasing, and have better fire resistance than steel or wood. During the manufacturing process, aluminum profiles require processing to facilitate subsequent assembly. This processing typically involves operators manually feeding the aluminum profiles, a cumbersome process that significantly impacts work efficiency during loading and unloading.

[0003] For example, application number CN209140464U discloses a novel feeding mechanism for processing metal bars, including a feeding cylinder, a support, a feeding block, ear plates, and a weight. The feeding block is slidably connected to the inner side of the feeding cylinder near the closed end. Ear plates are welded and fixedly installed at the outer ends of two connecting rods. A traction rope connection hole is opened in the middle of the ear plate, and a traction rope is fixedly connected to the inner side of the traction rope connection hole. A limit plate is vertically fixedly installed at the end of the feeding cylinder away from the closed end. A winding roller is rotatably installed at the top of the feeding cylinder near the limit plate, and a weight is fixedly connected to the other end of the traction rope. By slidably connecting the feeding block to the inner side of the feeding cylinder and fixing ear plates to both sides of the feeding block through connecting rods, the metal bar is subjected to force on both sides during feeding, making the feeding stable and facilitating the processing of metal parts during the feeding process.

[0004] However, when using this new type of metal bar processing feeding mechanism, the weight still needs to be manually lifted for feeding, and each feeding requires manual operation, resulting in low feeding efficiency and failing to meet people's needs. Therefore, a traction feeding device for aluminum alloy profile processing is needed. Utility Model Content

[0005] To address the shortcomings of existing technologies, such as manual feeding and low feeding efficiency, this utility model provides a traction feeding device for aluminum alloy profile processing.

[0006] To solve the above-mentioned technical problems, this utility model provides the following technical solution:

[0007] This utility model discloses an aluminum alloy profile processing traction and feeding device, including a base and a connecting mechanism disposed inside the base. The connecting mechanism includes a feeding component, a traction component, and a processing component.

[0008] The feeding assembly includes a feeding support plate, a feeding push plate, and a feeding cylinder. The feeding support plate is welded to the top of the base, and a feeding push plate is provided inside the feeding support plate. A feeding cylinder is fixedly installed on the left side wall of the feeding push plate.

[0009] The traction assembly includes a driving pulley, a driven pulley, and a feeding belt. The driving pulley is located on the right side of the feeding support plate, and the driven pulley is located on the right side of the driving pulley. The driving pulley and the driven pulley are rotatably connected by the feeding belt.

[0010] The processing assembly includes a processing platform, a processing support column, and a processing motor. The processing platform is welded to the right side wall of the base, and the processing support column is fixedly installed on the top of the processing platform. The processing motor is installed on the processing support column.

[0011] As a preferred embodiment of this utility model, a material preparation box is welded to one side of the feeding support plate, a baffle plate is fixedly installed on the material preparation box, a limiting rail is provided on the side wall of the feeding support plate away from the material preparation box, and the feeding push plate is limited and set on the limiting rail.

[0012] As a preferred embodiment of this utility model, a synchronous motor is provided inside the center of the driving pulley, and a rotating column is provided between the driving pulley and the driven pulley. A V-shaped spring damper is fitted on the rotating column, and a movable frame is provided on the rotating column. A traction wheel is installed at the end of the movable frame away from the rotating column. A support column between the rotating column and the traction wheel is welded to the movable frame, and a limiting column on the side of the rotating column away from the traction wheel is fixedly installed on the base.

[0013] As a preferred embodiment of this utility model, one end of the V-shaped spring damper is limited on the support column, and the other end of the V-shaped spring damper is limited on the limiting column.

[0014] As a preferred embodiment of this utility model, two sets of both the driving pulley and the driven pulley are provided. The feeding concave plate between the driving pulley and the driving pulley is embedded in the base, and the driving pulley and the driving pulley are symmetrically arranged about the feeding concave plate. The feeding belt is located directly above the feeding concave plate.

[0015] As a preferred technical solution of this utility model, a total of eight sets of rotating columns, V-shaped spring dampers, movable frames, traction wheels, support columns and limiting columns are provided. The eight sets of rotating columns, V-shaped spring dampers, movable frames, traction wheels, support columns and limiting columns are symmetrically arranged about the feeding concave plate. The outer wall of the traction wheel is set on the inner wall of the feeding belt.

[0016] This utility model has the following beneficial effects:

[0017] By setting up a feeding support plate, a feeding push plate, a feeding cylinder, and a limiting rail, during operation, the aluminum alloy profile to be processed is placed into the material box. The aluminum alloy profile to be processed slides into the inside of the feeding support plate. Then the feeding cylinder starts to work, and the feeding cylinder pushes the feeding push plate to move in a limited position on the limiting rail, avoiding the feeding push plate from shaking and causing inconvenience in pushing the material. It is convenient, fast, and has high pushing efficiency.

[0018] By setting up an active pulley, a driven pulley, a feeding belt, and traction wheels, during operation, the synchronous motor drives the active pulley to rotate, which in turn drives the driven pulley to rotate through the feeding belt. During the rotation of the two sets of feeding belts, the aluminum alloy profiles to be processed are pulled and transported backward. When passing the traction wheels, the eight symmetrically designed traction wheels squeeze the aluminum alloy profiles to be processed in the middle of the feeding belt, preventing the aluminum alloy profiles to be processed from changing direction due to shaking during the traction and transportation process. The profiles are continuously squeezed by the traction wheels, making the transportation process more stable. Attached Figure Description

[0019] Figure 1 This is a schematic diagram of the structure of a traction feeding device for processing aluminum alloy profiles according to this utility model;

[0020] Figure 2 This is a schematic diagram of the feeding assembly of a traction feeding device for aluminum alloy profile processing according to this utility model;

[0021] Figure 3 This is a schematic diagram of the traction component of an aluminum alloy profile processing traction feeding device according to this utility model;

[0022] Figure 4 This is a schematic diagram of a single traction component of an aluminum alloy profile processing traction feeding device according to this utility model;

[0023] Figure 5 This is a schematic diagram of the traction wheel of a traction feeding device for processing aluminum alloy profiles according to this utility model.

[0024] In the diagram: 1. Base; 2. Feeding support plate; 3. Feeding push plate; 4. Feeding cylinder; 5. Driven pulley; 6. Driven pulley; 7. Feeding belt; 8. Processing platform; 9. Processing support column; 10. Processing motor; 11. Material preparation box; 12. Baffle plate; 13. Limiting rail; 14. Synchronous motor; 15. Rotating column; 16. V-type spring damping; 17. Movable frame; 18. Traction wheel; 19. Support column; 20. Limiting column; 21. Feeding concave plate. Detailed Implementation

[0025] The preferred embodiments of the present invention will be described below with reference to the accompanying drawings. It should be understood that the preferred embodiments described herein are for illustration and explanation only and are not intended to limit the present invention.

[0026] Example 1

[0027] like Figure 1-5 As shown, the present invention proposes an aluminum alloy profile processing traction feeding device, which includes a base 1 and a connecting mechanism disposed inside the base 1. The connecting mechanism includes a feeding component, a traction component and a processing component.

[0028] The feeding assembly includes a feeding support plate 2, a feeding push plate 3, and a feeding cylinder 4. The feeding support plate 2 is welded to the top of the base 1. The feeding push plate 3 is installed inside the feeding support plate 2. The feeding cylinder 4 is fixedly installed on the left side wall of the feeding push plate 3. During operation, by setting up the feeding support plate 2, the feeding push plate 3, and the feeding cylinder 4, it is beneficial for the feeding cylinder 4 to push the feeding push plate 3 to push the aluminum alloy profile to be processed inside the feeding support plate 2 onto the feeding belt 7. The feeding does not require manual operation, which reduces processing costs, saves time, and increases efficiency.

[0029] The traction assembly includes a drive pulley 5, a driven pulley 6, and a feeding belt 7. The drive pulley 5 is located on the right side of the loading support plate 2, and the driven pulley 6 is located on the right side of the drive pulley 5. The drive pulley 5 and the driven pulley 6 are rotatably connected by the feeding belt 7. During operation, the aluminum alloy profile to be processed is pushed onto the feeding belt 7 by the loading push plate 3. The drive pulley 5 rotates, which drives the driven pulley 6 to rotate through the feeding belt 7. During the rotation of the two sets of feeding belts 7, the aluminum alloy profile to be processed that is close to it is pulled and transmitted backward.

[0030] Furthermore, a material preparation box 11 is welded to one side of the feeding support plate 2, and a baffle plate 12 is fixedly installed on the material preparation box 11. A limit rail 13 is provided on the side wall of the feeding support plate 2 away from the material preparation box 11, and the feeding push plate 3 is limited and set on the limit rail 13. During operation, the aluminum alloy profile to be processed is placed into the material preparation box 11, and the aluminum alloy profile to be processed slides into the interior of the feeding support plate 2. Then the feeding cylinder 4 starts to work, and the feeding cylinder 4 pushes the feeding push plate 3 to move on the limit rail 13 to avoid the feeding push plate 3 from shaking and causing inconvenience in pushing the material. It is convenient, fast and efficient.

[0031] Furthermore, a synchronous motor 14 is installed inside the center of the drive pulley 5, and a rotating column 15 is installed between the drive pulley 5 and the driven pulley 6. A V-shaped spring damper 16 is fitted on the rotating column 15, and a movable frame 17 is installed on the rotating column 15. A traction wheel 18 is installed at the end of the movable frame 17 away from the rotating column 15. A support column 19 is welded to the movable frame 17 between the rotating column 15 and the traction wheel 18. A limiting column 20 is fixedly installed on the side of the rotating column 15 away from the traction wheel 18 on the base 1. During operation, the aluminum alloy profile to be processed is fed by the feeding push plate 3. The material is pushed onto the feeding belt 7. At the same time, the synchronous motor 14 starts working, driving the drive pulley 5 to rotate, which in turn drives the driven pulley 6 to rotate through the feeding belt 7. During the rotation of the two sets of feeding belts 7, the aluminum alloy profile to be processed is pulled and transported backward. When it passes the traction wheel 18, the eight symmetrically designed traction wheels 18 are lifted a short distance in the direction of transmission. The traction wheel 18 is squeezed by the V-shaped spring damper 16 on the movable frame 17 to prevent the aluminum alloy profile to be processed from changing direction due to shaking during the traction and conveying process.

[0032] Furthermore, one end of the V-shaped spring damper 16 is limited on the support column 19, and the other end of the V-shaped spring damper 16 is limited on the limiting column 20. During operation, by setting the support column 19 and the limiting column 20, it is beneficial for both ends of the V-shaped spring damper 16 to be squeezed on the support column 19 and the limiting column 20, causing the V-shaped spring damper 16 to contract. Since the V-shaped spring damper 16 needs to rebound, it will drive the support column 19 downward, so that the traction wheel 18 squeezes the aluminum alloy profile to be processed in the middle of the feeding belt 7, avoiding the aluminum alloy profile to be processed from changing direction due to shaking during the traction and conveying process.

[0033] Furthermore, both the driving pulley 5 and the driven pulley 6 are provided in two sets. The feeding concave plate 21 between the driving pulley 5 and the driving pulley 6 is embedded in the base 1, and the driving pulley 5 and the driving pulley 6 are symmetrically arranged about the feeding concave plate 21. The feeding belt 7 is located directly above the feeding concave plate 21. During operation, by setting the feeding concave plate 21, the feeding concave plate 21 can be used for profiles with different appearance shapes, thus having a wider range of applications.

[0034] Furthermore, eight sets of rotating columns 15, V-shaped spring dampers 16, movable frames 17, traction wheels 18, support columns 19, and limiting columns 20 are provided. These eight sets of rotating columns 15, V-shaped spring dampers 16, movable frames 17, traction wheels 18, support columns 19, and limiting columns 20 are symmetrically arranged about the feeding concave plate 21. The outer wall of the traction wheel 18 is set on the inner wall of the feeding belt 7. During operation, by setting eight sets of traction wheels 18, the aluminum alloy profile to be processed is continuously squeezed by the traction wheels 18 during the conveying process, thus achieving more stable control operation during the transportation process.

[0035] Example 2

[0036] like Figure 1-5 As shown, the aluminum alloy profile processing traction feeding device proposed in this utility model, compared with embodiment 1, is another implementation of this utility model. The processing components include a processing platform 8, a processing support column 9, and a processing motor 10. The processing platform 8 is welded to the right side wall of the base 1, and the processing support column 9 is fixedly installed on the top of the processing platform 8. The processing motor 10 is installed on the processing support column 9. During operation, when the aluminum alloy profile to be processed is discharged from the driven pulley 6, the driven pulley 6 immediately falls onto the processing platform 8. The processing motor 10 on the processing platform 8 can then perform operations such as pressing and drilling on the aluminum alloy profile to be processed. Loading and unloading are more convenient and faster, and no manual operation is required, reducing the cost of use.

[0037] During operation, the aluminum alloy profile to be processed is first placed into the material preparation box 11. The aluminum alloy profile to be processed slides into the inside of the feeding support plate 2. Then the feeding cylinder 4 starts to work. The feeding cylinder 4 pushes the feeding push plate 3 to move on the limit rail 13 to avoid the feeding push plate 3 from shaking and causing inconvenience in pushing the material. It is convenient, fast and efficient.

[0038] Next, the aluminum alloy profile to be processed is pushed onto the feeding belt 7 by the feeding push plate 3. At the same time, the synchronous motor 14 starts to work, driving the drive pulley 5 to rotate, which in turn drives the driven pulley 6 to rotate through the feeding belt 7. During the rotation of the two sets of feeding belts 7, the aluminum alloy profile to be processed is pulled and transmitted backward. When it passes the traction wheel 18, the eight symmetrically designed traction wheels 18 are lifted a short distance in the transmission direction by force. The traction wheel 18 drives the movable frame 17 to move upward on the rotating column 15, which causes the two ends of the V-shaped spring damper 16 to be squeezed on the support column 19 and the limiting column 20, causing the V-shaped spring damper 16 to contract. Since the V-shaped spring damper 16 needs to rebound, it drives the support column 19 downward, so that the traction wheel 18 squeezes the aluminum alloy profile to be processed in the middle of the feeding belt 7, preventing the aluminum alloy profile to be processed from changing direction due to shaking during the traction and conveying process. During the traction and conveying process of the aluminum alloy profile to be processed from the driving pulley 5 to the driven pulley 6, it is located on the feeding concave plate 21. The feeding concave plate 21 can be used for profiles with different shapes and has a wider range of applications. The profile is continuously squeezed by the traction wheel 18, making the transportation process more stable.

[0039] Finally, when the aluminum alloy profile to be processed is discharged from the driven pulley 6, the driven pulley 6 immediately falls onto the processing platform 8. The processing motor 10 on the processing platform 8 can then perform operations such as pressing and drilling on the aluminum alloy profile to be processed, making loading and unloading more convenient and faster, eliminating the need for manual operation and reducing operating costs.

[0040] Finally, it should be noted that the above description is merely a preferred embodiment of this utility model and is not intended to limit the utility model. Although the utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of this utility model should be included within the protection scope of this utility model.

Claims

1. A traction feeding device for processing aluminum alloy profiles, comprising a base (1) and a connecting mechanism disposed inside the base (1), characterized in that: The connecting mechanism includes a feeding assembly, a traction assembly, and a processing assembly; The feeding assembly includes a feeding support plate (2), a feeding push plate (3) and a feeding cylinder (4). The top of the base (1) is welded with a feeding support plate (2). The feeding push plate (3) is provided inside the feeding support plate (2). The feeding cylinder (4) is fixedly installed on the left side wall of the feeding push plate (3). The traction assembly includes a drive pulley (5), a driven pulley (6) and a feeding belt (7). The drive pulley (5) is provided on the right side of the loading support plate (2), and the driven pulley (6) is provided on the right side of the drive pulley (5). The drive pulley (5) and the driven pulley (6) are rotatably connected by the feeding belt (7). The processing components include a processing platform (8), a processing support column (9), and a processing motor (10). The processing platform (8) is welded to the right side wall of the base (1), and the processing support column (9) is fixedly installed on the top of the processing platform (8). The processing motor (10) is installed on the processing support column (9).

2. The aluminum alloy profile processing traction feeding device according to claim 1, characterized in that: A material preparation box (11) is welded to one side of the feeding support plate (2). A baffle plate (12) is fixedly installed on the material preparation box (11). A limit rail (13) is provided on the side wall of the feeding support plate (2) away from the material preparation box (11). The feeding push plate (3) is limited and set on the limit rail (13).

3. The aluminum alloy profile processing traction feeding device according to claim 1, characterized in that: A synchronous motor (14) is provided inside the center of the active pulley (5), and a rotating column (15) is provided between the active pulley (5) and the driven pulley (6). A V-shaped spring damper (16) is sleeved on the rotating column (15), and a movable frame (17) is provided on the rotating column (15). A traction wheel (18) is installed at the end of the movable frame (17) away from the rotating column (15). A support column (19) provided between the rotating column (15) and the traction wheel (18) is welded to the movable frame (17). A limiting column (20) provided on the side of the rotating column (15) away from the traction wheel (18) is fixedly installed on the base (1).

4. The aluminum alloy profile processing traction feeding device according to claim 3, characterized in that: One end of the V-shaped spring damper (16) is limited on the support column (19), and the other end of the V-shaped spring damper (16) is limited on the limiting column (20).

5. The aluminum alloy profile processing traction feeding device according to claim 1, characterized in that: The active pulley (5) and the driven pulley (6) are each provided in two sets. The feeding concave plate (21) between the active pulley (5) and the driving pulley (5) is embedded in the base (1). The active pulley (5) and the driving pulley (5) are symmetrically arranged about the feeding concave plate (21). The feeding belt (7) is located directly above the feeding concave plate (21).

6. The aluminum alloy profile processing traction feeding device according to claim 3, characterized in that: The rotating column (15), V-shaped spring damper (16), movable frame (17), traction wheel (18), support column (19) and limiting column (20) are provided in eight sets. The eight sets of rotating columns (15), V-shaped spring damper (16), movable frame (17), traction wheel (18), support column (19) and limiting column (20) are symmetrically arranged about the feeding concave plate (21). The outer wall of the traction wheel (18) is set on the inner wall of the feeding belt (7).