Feeding structure of aluminum alloy component stamping device
By designing the feeding structure of the aluminum alloy parts stamping device, the problem of poor applicability of the existing feeding mechanism when changing specifications or equipment is solved, realizing convenient aluminum alloy parts loading and flexible feeding operation.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- ANHUI FURUIJIA MECHANICAL EQUIP MFG CO LTD
- Filing Date
- 2025-04-29
- Publication Date
- 2026-07-14
AI Technical Summary
Existing automated feeding mechanisms cannot be directly applied when changing the specifications of aluminum alloy sheets or stamping equipment, resulting in abnormal feeding.
A feeding structure for an aluminum alloy parts stamping device was designed, including a machine body, a stamping mechanism, a turntable, a feeding mechanism, and a loading mechanism. The device utilizes an adjustable height support base and a pushing mechanism to achieve two-stage feeding. The L-shaped pushing plate driven by a cylinder and the guide rod, in conjunction with a spring, enable convenient loading of aluminum alloy parts.
It enables convenient feeding of aluminum alloy parts, adapts to the replacement of different specifications of plates and equipment, and improves the flexibility and efficiency of feeding.
Smart Images

Figure CN224487458U_ABST
Abstract
Description
Technical Field
[0001] This application relates to the field of stamping technology, and in particular to the feeding structure of a stamping device for aluminum alloy parts. Background Technology
[0002] Stamping is one of the important processes in the processing of aluminum alloy parts. It involves applying pressure to aluminum alloy sheets using dies and stamping equipment, causing plastic deformation to obtain the desired shape and size. However, there are many problems in the feeding process during the stamping of aluminum alloy parts.
[0003] Currently, many automated feeding mechanisms on the market are designed for specific models of stamping equipment or aluminum alloy sheets of specific sizes. When stamping production requires changing the specifications of the aluminum alloy sheet or replacing the stamping equipment, the existing automated feeding mechanism may not be directly applicable, necessitating complex adjustments or replacement of some key components. For example, an automated feeding mechanism used for stamping 3mm thick aluminum alloy sheets may fail to feed properly when switching to stamping 5mm thick sheets due to improper settings of the feeding roller pressure and spacing. Therefore, to solve the above problems, this application provides a feeding structure for an aluminum alloy parts stamping device. Utility Model Content
[0004] To address the problem of inconvenient adjustment in existing stamping feeding devices, this application provides a feeding structure for an aluminum alloy parts stamping device.
[0005] The aluminum alloy parts stamping device feeding structure provided in this application consists of a machine body, a stamping mechanism, a turntable, a feeding mechanism, and a loading mechanism. The turntable is provided with several processing positions. The loading mechanism includes a vertical plate fixed on the machine body. A vertically adjustable support base is provided on the inner side of the vertical plate. A feeding table is slidably connected to the support base. A material loading structure is provided above the feeding table.
[0006] A pushing mechanism is installed on one side of the feeding table. The pushing mechanism operates in two stages: the first stage pushes the feeding table to the side of the processing position, and the second stage pushes the aluminum alloy sheet on the feeding table to the processing position.
[0007] Aluminum alloy parts are placed using upright plates and a material loading structure. They are loaded autonomously under gravity. A feeding platform is set up, and a pushing mechanism is set up in conjunction with the feeding platform. The pushing mechanism uses two-stage feeding to realize the output of aluminum alloy parts from the material pile and the pushing of them from the feeding platform to the processing position, thereby realizing convenient material loading operations.
[0008] Preferably, the pushing mechanism includes a cylinder whose end is fixed to a support base, and an L-shaped pushing plate is fixed to the cylinder output end.
[0009] Preferably, a guide rod is welded to the pusher plate along its direction of movement, and a sliding spring is mounted on the guide rod. A guide groove is provided on the feeding table for the guide rod to slide into, and the spring is located between the pusher plate and the feeding table.
[0010] Preferably, a slide rail is provided below the feeding platform, and a groove that cooperates with the slide rail is provided on the support base.
[0011] Preferably, the upright plate is also provided with an adjustment groove 2, and the support base is limited by the knob structure 1 and the adjustment groove 2, and also has a height adjustment function.
[0012] Preferably, the material loading structure includes four guide plates, which cover the four corners of the material. The side wall of the upright plate is provided with an adjustment groove. The guide plates are limited by a knob structure and the adjustment groove, and also have a height adjustment function.
[0013] In summary, this application includes the following beneficial technical effects:
[0014] Aluminum alloy parts are placed using upright plates and a material loading structure. They are loaded autonomously under gravity. A feeding platform is set up, and a pushing mechanism is set up in conjunction with the feeding platform. The pushing mechanism uses two-stage feeding to realize the output of aluminum alloy parts from the material pile and the pushing of them from the feeding platform to the processing position, thereby realizing convenient material loading operations. Attached Figure Description
[0015] Figure 1 It is the isometric drawing in Embodiment 1 of this application;
[0016] Figure 2 This is an isometric view of the feeding structure in Embodiment 1 of this application;
[0017] Figure 3 This is an exploded view of the feeding structure in Embodiment 1 of this application;
[0018] Figure 4 This is an internal front view of the feeding structure in Embodiment 1 of this application;
[0019] Figure 5 This is an exploded view of the material platform in Embodiment 1 of this application.
[0020] Explanation of reference numerals in the attached drawings: 1. Machine body; 2. Stamping mechanism; 3. Turntable; 31. Processing station; 4. Unloading mechanism;
[0021] 5. Feeding mechanism; 51. Vertical plate; 511. Adjustment groove one; 512. Adjustment groove two; 52. Support base; 521. Knob structure one; 522. Slide groove; 53. Guide plate; 531. Knob structure two; 54. Push plate; 55. Cylinder; 56. Guide rod; 57. Spring; 58. Feeding table; 581. Guide groove; 59. Slide rail. Detailed Implementation
[0022] The following is in conjunction with the appendix Figure 1 - Figure 5 This application will be described in further detail.
[0023] Example 1:
[0024] The feeding structure of the aluminum alloy parts stamping device is referenced. Figure 1 - Figure 5 The stamping device is composed of a machine body 1, a stamping mechanism 2, a turntable 3, a feeding mechanism 4, and a feeding mechanism 5. The turntable 3 has several processing positions 31. The feeding mechanism 5 includes a vertical plate 51 fixed to the machine body 1. A vertically adjustable support base 52 is provided on the inner side of the vertical plate 51. A feeding table 58 is slidably connected to the support base 52. A material loading structure is provided above the feeding table 58.
[0025] A pushing mechanism is provided on one side of the feeding table 58. The pushing mechanism operates in two stages: the first stage pushes the feeding table 58 to the side of the processing station 31, and the second stage pushes the aluminum alloy sheet on the feeding table 58 to the processing station 31.
[0026] The pushing mechanism includes a cylinder 55 whose end is fixed to a support base 52. An L-shaped pushing plate 54 is fixed to the output end of the cylinder 55. A guide rod 56 is welded on the pushing plate 54 along its direction of movement, and a sliding spring 57 is mounted on the guide rod 56. A guide groove 581 is provided on the feeding table 58 for the guide rod 56 to slide into. The spring 57 is located between the pushing plate 54 and the feeding table 58, and both ends of the spring 57 are fixed to the pushing plate 54 and the feeding table 58, respectively. When the cylinder 55 retracts, its vertical and horizontal sections together push the feeding table 58 and the material above it to move synchronously in one stroke. In the two-stage process, the feeding table 58 is fixed in position because it is in contact with the side of the processing position 31. However, because the guide rod 56 compresses the spring 57, the pushing plate 54 can continue to move forward. The horizontal section of the pushing plate 54 pushes the aluminum alloy sheet on the feeding table 58 forward into the processing position 31. Then the cylinder 55 retracts, causing the feeding table 58 to reset.
[0027] A slide rail 59 is provided below the feeding platform 58, and a groove 522 is provided on the support base 52 to cooperate with the slide rail 59. The slide rail 59 and the groove 522 are used to guide the feeding platform 58 and keep the feeding platform 58 stable after it is pushed out of the support base 52. An adjustment groove 512 is also provided on the upright plate 51. The support base 52 is limited between the knob structure 521 and the adjustment groove 512, and also has a height adjustment function. The material loading structure includes four guide plates 53, which cover the four corners of the material. An adjustment groove 511 is provided on the side wall of the upright plate 51. The guide plates 53 are limited between the knob structure 531 and the adjustment groove 511, and also have a height adjustment function. The two front guide plates 53 have notches at their bottom ends, which allow one aluminum alloy part to pass through at a time, thus ensuring that each output is one aluminum alloy part.
[0028] The foregoing description, with reference to preferred embodiments, illustrates an exemplary implementation of the feeding structure of the aluminum alloy parts stamping device provided by this disclosure. However, those skilled in the art will understand that various modifications and alterations can be made to the above specific embodiments without departing from the spirit of this disclosure, and various combinations can be made to the various technical features and structures proposed in this disclosure without exceeding the protection scope of this disclosure, the protection scope of which is determined by the appended claims.
Claims
1. A feeding structure for an aluminum alloy parts stamping device, comprising a machine body (1), a stamping mechanism (2), a turntable (3), a feeding mechanism (4), and a loading mechanism (5), wherein the turntable (3) is provided with several processing positions (31), characterized in that: The feeding mechanism (5) includes a vertical plate (51) fixed on the machine body (1), a vertically adjustable support seat (52) is provided on the inner side of the vertical plate (51), a feeding table (58) is slidably connected on the support seat (52), and a material filling structure is provided above the feeding table (58). A pushing mechanism is provided on one side of the feeding table (58). The pushing mechanism operates in two stages. The first stage pushes the feeding table (58) to the side of the processing position (31), and the second stage pushes the aluminum alloy sheet on the feeding table (58) to the processing position (31).
2. The feeding structure according to claim 1, characterized in that: The pushing mechanism includes a cylinder (55) whose end is fixed to a support base (52), and an L-shaped pushing plate (54) is fixed to the output end of the cylinder (55).
3. The feeding structure according to claim 2, characterized in that: A guide rod (56) is welded on the pusher plate (54) along its direction of movement, and a sliding spring (57) is mounted on the guide rod (56). A guide groove (581) is provided on the feeding table (58) for the guide rod (56) to slide into, and the spring (57) is located between the pusher plate (54) and the feeding table (58).
4. The feeding structure according to claim 3, characterized in that: The feed table (58) is provided with a slide rail (59) below it, and the support base (52) is provided with a slide groove (522) that cooperates with the slide rail (59).
5. The feeding structure according to claim 4, characterized in that: The upright plate (51) is also provided with an adjustment groove (512). The support base (52) is limited between the knob structure (521) and the adjustment groove (512), and also has a height adjustment function.
6. The feeding structure according to claim 1, characterized in that: The material loading structure includes four guide plates (53), which cover the four corners of the material. The side wall of the upright plate (51) is provided with an adjustment groove (511). The guide plates (53) are limited between the adjustment groove and the knob structure (531), and also have a height adjustment function.