Metal shoe buckle processing integrated forming die

By designing an integrated molding die for metal shoe buckle processing with an automatic feeding and mixing mechanism, the problem of tedious manual feeding in existing technologies has been solved, achieving automated feeding and uniform distribution of the collection box, thus improving production efficiency.

CN224333272UActive Publication Date: 2026-06-09SHISHI HONGJUE HARDWARE PROD CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHISHI HONGJUE HARDWARE PROD CO LTD
Filing Date
2025-07-25
Publication Date
2026-06-09

AI Technical Summary

Technical Problem

Existing one-piece molding dies for metal shoe buckle processing are not convenient for automatic unloading after processing, requiring manual operation, which makes the operation cumbersome.

Method used

A mold structure including a hydraulic rod, a top plate, an upper mold, a lower mold, a magnetic ring, and an auxiliary ejection mechanism was designed. The automatic feeding of shoe buckles is achieved through hydraulic drive and mechanical transmission, and the mixing mechanism ensures smooth feeding and uniform distribution of the collection box.

Benefits of technology

It enables automatic feeding of metal shoe buckles, reduces manual operation, improves processing efficiency, and prevents shoe buckles from accumulating in the collection box through a mixing mechanism, thereby improving production efficiency.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses a metal shoe buckle processing integrated forming die relates to forming die field, including machine body and insert rod, the top of machine body is equipped with hydraulic rod a, the top fixed of hydraulic rod a has the top board, be connected with a plurality of telescopic link between the top board and machine body, the bottom of top board is provided with upper die a with upper die b, the center of machine body top is fixed with lower die. This metal shoe buckle processing integrated forming die, will carry out compression after two groups of shoe buckle respectively complete processing, thereby complete processing, at this moment, shoe buckle will be at the bottom of upper die b, and the upper die b of completing processing will carry out reset, and in the process of resetting, the ejection blanking mechanism in the upper die b will be triggered by the auxiliary ejection mechanism, thereby promoting the shoe buckle of the bottom suction of upper die b to separate, make shoe buckle automatic blanking to the collecting box, and through the mixing mechanism can make the shoe buckle collected in the collecting box complete mixing.
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Description

Technical Field

[0001] This utility model relates to the field of molding die technology, specifically to an integrated molding die for processing metal shoe buckles. Background Technology

[0002] The ring-shaped shoe buckle is made of two pieces of metal. The two sets of shoe buckles need to be stamped separately using an integrated molding die, and then the two sets of shoe buckles are pressed together to form a whole shoe buckle.

[0003] For example, in the announcement number CN210907678U, a mold for one-piece molding of metal shoe buckles is provided. By setting a stamping rod, sleeve rod, magnet, stamping block, and material receiving groove between the upper and lower molds, the mold can be used to punch and snap the shoe buckle into place. This makes it easy to adjust and use, has a good molding effect, improves processing efficiency, and reduces processing steps.

[0004] The integrated molding mold for metal shoe buckle processing in the above scheme requires workers to manually remove the finished shoe buckle from the upper mold after processing and send it into the collection box through the feeding channel. The operation is cumbersome and inconvenient for processing shoe buckles. Utility Model Content

[0005] The purpose of this utility model is to provide an integrated molding die for metal shoe buckle processing, so as to solve the problem mentioned in the background art that the existing integrated molding die for metal shoe buckle processing is not convenient for unloading the processed shoe buckles.

[0006] To achieve the above objectives, this utility model provides the following technical solution: an integrated forming mold for metal shoe buckle processing, comprising a machine body and an insert rod. A hydraulic rod a is installed on the top of the machine body, and a top plate is fixed to the top of the hydraulic rod a. Multiple sets of telescopic rods are connected between the top plate and the machine body. An upper mold a and an upper mold b are provided at the bottom of the top plate, and a lower mold is fixed at the center of the top of the machine body. A driving mechanism is provided inside the top plate, and a fixing plate is fixedly connected to the bottom of the top plate near the upper mold b. Two... The assembly includes an insert rod, an auxiliary ejection mechanism inside the insert rod, an ejection and feeding mechanism inside the upper mold b, a magnetic ring fixedly connected to the bottom of the upper mold b, a feeding channel inside the machine body, a horizontal plate fixed to the bottom of the machine body, a hydraulic rod b fixed to the top of the horizontal plate, a push rod fixedly connected to the top of the hydraulic rod b, and a through groove matching the insert rod inside the upper mold b. The upper mold b and the insert rod form a sliding structure. A connecting plate is slidably connected to the top of the horizontal plate via a slide rail, and a mixing mechanism is provided on one side of the connecting plate.

[0007] Furthermore, the auxiliary ejection mechanism includes a storage slot inside the insertion rod, and a rotating block is rotatably connected to the inner side of the storage slot via a rotating shaft. The drive mechanism includes a motor installed on one side of the top plate, and a threaded rod is fixed to the output end of the motor. The outer side of the threaded rod is threadedly connected to the upper mold a and the upper mold b.

[0008] Furthermore, one side of the storage groove is wedge-shaped, and one side of the rotating block is arc-shaped. The rotating block forms a rotating structure with the insertion rod through a rotating shaft.

[0009] Furthermore, the ejection and unloading mechanism includes a push rod that is slidably connected inside the upper mold b, and a spring is sleeved on the outside of the push rod, with one end of the spring abutting against the inside of the upper mold b.

[0010] Furthermore, the mixing mechanism includes a connecting rod b rotatably connected to one side of the connecting plate via a rotating shaft, one end of the connecting rod b being rotatably connected to a connecting rod a via a rotating shaft, and one end of the connecting rod a being rotatably connected to one side of the top of the hydraulic rod b via a rotating shaft.

[0011] Furthermore, the top of the connecting plate abuts against a collection box, and the connecting plate abuts against the horizontal plate through a sliding structure formed by the slide rail. The connecting rod a forms a rotating structure with the connecting rod b through a rotating shaft.

[0012] Compared with the prior art, the beneficial effects of this utility model are as follows: the one-piece molding mold for metal shoe buckle processing will press together after the two sets of shoe buckles are processed separately to complete the processing. At this time, the shoe buckle will be at the bottom of the upper mold b. The upper mold b will be reset after processing. During the reset process, the ejection and feeding mechanism inside the upper mold b will be triggered by the auxiliary ejection mechanism, thereby pushing the shoe buckle attracted at the bottom of the upper mold b to detach, so that the shoe buckle is automatically fed into the collection box. At the same time, the shoe buckle collected in the collection box can be mixed evenly through the mixing mechanism.

[0013] 1. When processing shoe buckles, the two sets of shoe buckles are processed separately using upper mold a and lower mold. Then, the two sets of shoe buckles are pressed together using upper mold b and lower mold. After processing, upper mold b can drive the shoe buckles to reset. The insert rod will be inserted into the interior of upper mold b during the reset process, and the push rod will be pushed down by rotating block, which will push the shoe buckle attracted at the bottom of the magnetic ring to move, so that the shoe buckle falls into the collection box.

[0014] 2. When the hydraulic rod b moves up and down, it will drive the connecting rod a and connecting rod b to rotate. As a result, the connecting plate at one end will move on the slide rail. During the back and forth movement of the connecting plate, the collection box at the top will shake, thereby mixing the shoe buckles collected inside the collection box. Attached Figure Description

[0015] Figure 1This is a three-dimensional structural diagram of the present invention;

[0016] Figure 2 This is a three-dimensional cross-sectional structural diagram of the present invention;

[0017] Figure 3 This is a three-dimensional structural diagram of the upper mold b of this utility model;

[0018] Figure 4 This is a three-dimensional structural diagram of the insertion rod of this utility model;

[0019] Figure 5 This utility model Figure 3 Enlarged view of point A;

[0020] Figure 6 This is a three-dimensional structural diagram of the collection box of this utility model.

[0021] In the diagram: 1. Machine body; 2. Hydraulic rod a; 3. Top plate; 4. Upper mold a; 5. Upper mold b; 6. Motor; 7. Threaded rod; 8. Fixing plate; 9. Insert rod; 10. Storage slot; 11. Rotating block; 12. Push rod; 13. Spring; 14. Magnetic ring; 15. Lower mold; 16. Hydraulic rod b; 17. Push rod; 18. Connecting rod a; 19. Connecting rod b; 20. Connecting plate; 21. Collection box; 22. Discharge channel; 23. Horizontal plate. Detailed Implementation

[0022] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0023] Example 1: Please refer to Figures 1-5This utility model provides the following technical solution: an integrated forming mold for metal shoe buckle processing, including a body 1 and insert rods 9. A hydraulic rod a2 is installed on the top of the body 1, and a top plate 3 is fixed on the top of the hydraulic rod a2. Multiple sets of telescopic rods are connected between the top plate 3 and the body 1. An upper mold a4 and an upper mold b5 are set at the bottom of the top plate 3. A lower mold 15 is fixed at the center of the top of the body 1. A driving mechanism is set inside the top plate 3. A fixing plate 8 is fixedly connected to the bottom of the top plate 3 near the upper mold b5. Two sets of insert rods 9 are fixedly connected to one side of the fixing plate 8. An auxiliary ejection mechanism is set inside the insert rods 9. An ejection and unloading mechanism is set inside the upper mold b5. A magnetic ring 14 is fixedly connected to the bottom of the upper mold b5. A unloading channel 22 is opened inside the body 1. A horizontal plate 23 is fixed to the bottom of the body 1, and a hydraulic rod b16 is fixed to the top of the horizontal plate 23. A top rod 17 is fixedly connected. The upper mold b5 has a through groove inside that matches the insert rod 9. The upper mold b5 and the insert rod 9 form a sliding structure. The auxiliary ejection mechanism includes a receiving groove 10 inside the insert rod 9. The inner side of the receiving groove 10 is rotatably connected to a rotating block 11 via a rotating shaft. The drive mechanism includes a motor 6 mounted on one side of the top plate 3. The output end of the motor 6 is fixed with a threaded rod 7. The outer side of the threaded rod 7 is threadedly connected to the upper mold a4 and the upper mold b5. One side of the receiving groove 10 is wedge-shaped, and one side of the rotating block 11 is arc-shaped. The rotating block 11 and the insert rod 9 form a rotating structure via a rotating shaft. The ejection and unloading mechanism includes a push rod 12 slidably connected inside the upper mold b5. A spring 13 is sleeved on the outer side of the push rod 12. One end of the spring 13 abuts against the inner side of the upper mold b5. The upper mold b5 has a sliding groove inside that matches the push rod 12. The push rod 12 and the upper mold b5 form a sliding structure.

[0024] Please see Figures 1-5This integrated molding die for metal shoe buckles operates as follows: A set of shoe buckles is placed into the lower die 15, with the upper die a4 positioned directly above it. Hydraulic rod a2 is then activated, causing the upper die a4 to move downwards. The upper die a4 presses the shoe buckles in the lower die 15, bringing the bottom of the buckle into contact with the ejector rod 17, thus completing the stamping process. Then, hydraulic rod b16 is activated, causing the ejector rod 17 to move upwards, ejecting the shoe buckle for easy removal. After removal, the buckle is placed into the bottom of the upper die b5, where it attracts the magnetic ring 14. Then, another set of shoe buckles can be placed into the lower die. In step 15, a second stamping is performed. After stamping is completed, motor 6 is activated to drive the threaded rod 7 to rotate, causing the threaded rod 7 to engage in threaded transmission with the upper mold a4 and upper mold b5, thus moving the upper mold a4 and upper mold b5. At this time, the upper mold b5 will move directly above the lower mold 15. Then, hydraulic rod a2 is activated to move the upper mold b5 downwards. The upper mold b5 will also move the shoe buckle attached to the magnetic ring 14 downwards, pressing it against the shoe buckle that was just stamped in the lower mold 15. After pressing is completed, hydraulic rod a2 is activated to move the top plate 3 upwards, and motor 6 is activated to reverse the threaded rod 7, causing the upper mold b5 to reset. The upper mold b5 will then... After the shoe buckle is reset by dynamic pressing, the insert rod 9 will be inserted into the upper mold b5 during the reset process. When the wedge-shaped surface at the top of the push rod 12 inside the upper mold b5 contacts the rotating block 11, it will push the rotating block 11 to rotate clockwise. However, due to the obstruction of the wedge-shaped surface on one side of the storage groove 10, it will not rotate. Therefore, it will squeeze the push rod 12 during movement, causing the push rod 12 to squeeze the outer spring 13 and move downward. The push rod 12 is located on both sides of the magnetic ring 14. In the unpush-out state, it will not cross the bottom surface of the magnetic ring 14. At this time, the push rod 12 that is pushed out will push the magnetic ring 14. The shoe buckle, which is attracted to the bottom of the iron ring 14, moves and falls into the bottom unloading channel 22. It is then guided into the collection box 21 through the unloading channel 22, completing the automatic unloading of the shoe buckle. It should be noted that when the upper mold b5 moves to the top of the lower mold 15, the push rod 12 will press one side of the rotating block 11. At this time, the rotating block 11 will rotate counterclockwise and will not be obstructed. It can rotate into the storage slot 10 without obstructing the moving push rod 12. Therefore, the push rod 12 will not move down. In this way, the shoe buckles processed in the one-piece molding mold of metal shoe buckle processing can be automatically unloaded.

[0025] Example 2:

[0026] Please see Figure 1 , Figure 2 and Figure 6Based on Embodiment 1, a mixing and distribution structure for shoe buckles in the collection box 21 is also disclosed. The specific structure is as follows: a connecting plate 20 is slidably connected to the top of the horizontal plate 23 via a slide rail, and a mixing mechanism is provided on one side of the connecting plate 20. The mixing mechanism includes a connecting rod b19 rotatably connected to one side of the connecting plate 20 via a rotating shaft. One end of the connecting rod b19 is rotatably connected to a connecting rod a18 via a rotating shaft. One end of the connecting rod a18 is rotatably connected to one side of the top of the hydraulic rod b16 via a rotating shaft. The top of the connecting plate 20 abuts against the collection box 21. The connecting plate 20 and the horizontal plate 23 form a sliding structure abutting against each other via a slide rail. The connecting rod a18 and the connecting rod b19 form a rotating structure via a rotating shaft.

[0027] Please see Figure 1 , Figure 2 and Figure 6 The integrated molding mold for metal shoe buckles has a single cutting position during the shoe buckle cutting process. As a result, the shoe buckles tend to accumulate in a small portion of the collection box 21 and pile up, which can easily lead to overflow. However, there are still empty spaces in other parts of the collection box 21. Therefore, in order to make full use of the space in the collection box 21, a set of connecting rods a18 is set on one side of the hydraulic rod b16. When the hydraulic rod b16 moves up and down, it drives the connecting rods a18 to rotate and pulls the connecting rod b19 to rotate as well. The connecting rod b19 will then pull the connecting plate 20 at one end to move on the slide rail. During the back and forth movement of the connecting plate 20, the top of the collection box 21 will shake, thereby mixing the shoe buckles collected inside the collection box 21 and preventing them from piling up in some places. In this way, the space in the collection box 21 can be fully utilized.

[0028] The contents not described in detail in this specification are existing technologies known to those skilled in the art.

[0029] Although the present invention 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 the present invention should be included within the protection scope of the present invention.

Claims

1. A metal shoe buckle processing integrated forming mold, comprising a body (1) and a plug rod (9), wherein a hydraulic rod a (2) is installed on the top of the body (1), a top plate (3) is fixed on the top of the hydraulic rod a (2), and multiple sets of telescopic rods are connected between the top plate (3) and the body (1), an upper mold a (4) and an upper mold b (5) are provided at the bottom of the top plate (3), and a lower mold (15) is fixed at the center of the top of the body (1); characterized in that The top plate (3) is equipped with a drive mechanism inside. A fixed plate (8) is fixedly connected to the bottom of the top plate (3) near the upper mold b (5). Two sets of insert rods (9) are fixedly connected to one side of the fixed plate (8). An auxiliary ejection mechanism is provided inside the insert rods (9). An ejection and unloading mechanism is provided inside the upper mold b (5). A magnetic ring (14) is fixedly connected to the bottom of the upper mold b (5). A unloading channel (22) is opened inside the machine body (1). A horizontal plate (23) is fixed to the bottom of the machine body (1). A hydraulic rod b (16) is fixed to the top of the horizontal plate (23). A top rod (17) is fixedly connected to the top of the hydraulic rod b (16). The connecting plate (20) is slidably connected to the top of the horizontal plate (23) via a slide rail, and a mixing mechanism is provided on one side of the connecting plate (20).

2. The metal shoe buckle processing integrated forming die according to claim 1, characterized in that: The auxiliary ejection mechanism includes a storage slot (10) inside the insert rod (9), and a rotating block (11) is rotatably connected to the inner side of the storage slot (10) via a rotating shaft. The driving mechanism includes a motor (6) installed on one side of the top plate (3), and a threaded rod (7) is fixed to the output end of the motor (6). The outer side of the threaded rod (7) is threadedly connected to the upper mold a (4) and the upper mold b (5).

3. The metal shoe buckle processing integrated forming die according to claim 2, characterized in that: One side of the storage slot (10) is wedge-shaped, and one side of the rotating block (11) is arc-shaped. The rotating block (11) forms a rotating structure with the insert rod (9) through the rotating shaft.

4. The metal shoe buckle processing integrated forming die according to claim 1, characterized in that: The ejection and unloading mechanism includes a push rod (12) that is slidably connected inside the upper mold b (5). A spring (13) is sleeved on the outside of the push rod (12), and one end of the spring (13) abuts against the inside of the upper mold b (5).

5. The metal shoe buckle processing integrated forming die according to claim 1, characterized in that: The mixing mechanism includes a connecting rod b (19) rotatably connected to one side of the connecting plate (20) via a rotating shaft. One end of the connecting rod b (19) is rotatably connected to a connecting rod a (18) via a rotating shaft. One end of the connecting rod a (18) is rotatably connected to one side of the top of the hydraulic rod b (16) via a rotating shaft.

6. The metal shoe buckle processing integrated forming die according to claim 5, characterized in that: The top of the connecting plate (20) abuts against the collection box (21). The connecting plate (20) and the horizontal plate (23) form a sliding structure abutting each other through the slide rail. The connecting rod a (18) and the connecting rod b (19) form a rotating structure through the rotating shaft.