A component forming mechanism

By introducing an adjustment component into the diode forming machine, the cumbersome operation caused by the through bolt method is solved, and the flexible adjustment and stability of the tool position are realized, thereby improving the flexibility of diode lead cutting.

CN224487491UActive Publication Date: 2026-07-14KANGSHI MICROELECTRONICS TECH (WUXI) CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
KANGSHI MICROELECTRONICS TECH (WUXI) CO LTD
Filing Date
2025-07-10
Publication Date
2026-07-14

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Abstract

The utility model discloses a component forming mechanism, including the multiple axle stem of installation between main part and support, the multiple axle stem is installed with the bending mould, the bottom of multiple axle stem and between main part and support symmetry is installed with the shearing assembly, the shearing assembly is by the support, the sheath, the cutter and is composed, through the adjusting assembly of design, the diode forming machine in the former component forming machine improves in the use process, because diode has multiple package, makes the length shearing length of pin inconsistent, the cutter position for diode pin shearing is adjusted, adopts the mode of through -penetrating bolt, makes when dismounting all need the help of tool, there is the phenomenon of cumbersome operation, through the internal setting adjusting assembly of shearing assembly, under the condition that guaranteeing the stability of using after adjusting, optimization adjusting step, and satisfy diode pin length can arbitrary shearing, increase the use flexibility.
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Description

Technical Field

[0001] This utility model belongs to the field of component processing technology, and specifically relates to a component forming mechanism. Background Technology

[0002] The diode forming machine, a type of component forming machine, is a specialized piece of equipment used for processing diode leads. Its core function is to form and cut diode leads to adapt the diodes to the requirements of circuit board installation.

[0003] In existing component forming machines, diode forming machines bend and cut the diode leads using a bending mold and a shearing assembly. Because diodes have various packages, the lead lengths can be inconsistent during cutting. Currently, the method of fixing the cutter by bolting through the sheath into the support rod is cumbersome. Therefore, this utility model proposes a component forming mechanism. Utility Model Content

[0004] The purpose of this utility model is to provide a component forming mechanism to solve the problem of cumbersome operation caused by adjusting the position of the tool by means of through bolts as mentioned in the background art.

[0005] To achieve the above objectives, the present invention provides the following technical solution: a component forming mechanism, comprising multiple shafts installed between a main body and a support, a bending mold mounted on the multiple shafts, and a shearing assembly symmetrically installed at the bottom of the multiple shafts and between the main body and the support. The shearing assembly consists of a support rod, a sheath, and a cutter. The sheath is disposed at the end of the support rod, and the cutter is installed at the end of the sheath.

[0006] Preferably, an adjustment assembly is provided at the connection between the inner side of the support rod and the inner side of the sheath. The adjustment assembly consists of a screw, a rotating groove, a limiting assembly, a retaining groove, a fixing assembly, and a threaded groove. The rotating groove is located on the inner side of the sheath, the threaded groove is located on the inner side of the support rod, the retaining groove is located at the end of the sheath, the screw passes through the inner side of the threaded groove, one end of the screw is engaged with the inner side of the rotating groove, and the other end of the screw passes through the bracket to the outside. The limiting assembly is located at the connection between the end of the support rod and the inner side of the sheath, and the fixing assembly is located on the side of the bracket.

[0007] Preferably, the limiting component consists of a limiting groove and a limiting block. The limiting groove is opened at the end of the sheath, and the inner side of the rotating groove, the inner side of the limiting groove, and the inner side of the slot are in a communicating state.

[0008] Preferably, the end surface of the screw is in contact with the inner wall of the rotating groove, and the screw has a cylindrical structure.

[0009] Preferably, the fixing component consists of a fixing block, a fixing groove, and a sleeve. The sleeve is fitted onto the surface of the screw and fits against the side of the bracket. The fixing groove is opened on the side of the bracket. The fixing block is disposed inside the fixing groove. The fixing block and the fixing groove are in an engaged state.

[0010] Preferably, the sleeve is a hollow cylindrical structure.

[0011] Preferably, silicone seats are provided between the fixing block and the fixing groove, and between the screw and the sleeve.

[0012] Compared with the prior art, the beneficial effects of this utility model are:

[0013] By designing an adjustment component, the original diode forming machine for component forming was improved. Due to the various packages of diodes, the lead lengths could not be cut consistently. The tool position for cutting diode leads was adjusted using through bolts, requiring tools for both assembly and disassembly, leading to cumbersome operation. Furthermore, the fixed position of the through bolts limited the cuttable length, restricting flexibility. By incorporating an adjustment component within the cutting assembly, the adjustment process is optimized while maintaining stability after adjustment, allowing for arbitrary cutting of diode lead lengths and increasing operational flexibility. Attached Figure Description

[0014] Figure 1 This is a schematic diagram of the structure of this utility model;

[0015] Figure 2 This is a schematic diagram of the internal structure of the shearing component of this utility model;

[0016] Figure 3 This is a schematic diagram of the installation of the strut and sheath of this utility model;

[0017] In the diagram: 1. Main body; 2. Shearing assembly; 21. Support rod; 211. Screw; 212. Rotating groove; 213. Limiting assembly; 2131. Limiting groove; 2132. Limiting block; 214. Slot; 215. Fixing assembly; 2151. Fixing block; 2152. Fixing groove; 2153. Sleeve; 216. Threaded groove; 22. Sheath; 23. Cutting tool; 3. Bracket; 4. Bending die. Detailed Implementation

[0018] 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.

[0019] Please see Figures 1 to 3 This utility model provides a technical solution: a component forming mechanism, including multiple shafts installed between a main body 1 and a support 3, with bending molds 4 mounted on the shafts. A shearing assembly 2 is symmetrically installed at the bottom of the shafts between the main body 1 and the support 3. The shearing assembly 2 consists of a support rod 21, a sheath 22, and a cutter 23. The sheath 22 is located at the end of the support rod 21, and the cutter 23 is installed at the end of the sheath 22. An adjustment assembly is provided at the connection between the inner side of the support rod 21 and the inner side of the sheath 22. The adjustment assembly consists of a screw 211, a rotating groove 212, and a limiting... The bracket 213 comprises a positioning component 213, a slot 214, a fixing component 215, and a threaded groove 216. A rotating groove 212 is located inside the sheath 22, a threaded groove 216 is located inside the support rod 21, a slot 214 is located at the end of the sheath 22, a screw 211 passes through the inner side of the threaded groove 216, one end of the screw 211 is engaged with the inner side of the rotating groove 212, and the other end of the screw 211 passes through the bracket 3 to the outside. The positioning component 213 is located at the connection between the end of the support rod 21 and the inner side of the sheath 22. The fixing component 215 is located on the side of the bracket 3. The bracket 3 is designed to be adjustable... The original diode forming machine, due to the various diode packages, had inconsistent lead cutting lengths. The cutter 23 used for cutting the diode leads was adjusted using through bolts, requiring tools for both assembly and disassembly, leading to cumbersome operation. Furthermore, the fixed position of the through bolts limited the cutting length flexibility. By incorporating an adjustment component internally into the cutting assembly 2, the adjustment is optimized while maintaining stability after adjustment. The steps are such that the diode pin length can be arbitrarily cut, increasing the flexibility of use. The limiting component 213 consists of a limiting groove 2131 and a limiting block 2132. The limiting groove 2131 is opened at the end of the sheath 22. The inner side of the rotating groove 212, the inner side of the limiting groove 2131, and the inner side of the slot 214 are in a connected state. The limiting component 213 limits the angle at the engagement point of the support rod 21 and the sheath 22, ensuring the stability of the tool 23 during use. The end surface of the screw 211 is in a close fit with the inner wall of the rotating groove 212. The screw 211 has a cylindrical structure.

[0020] In this embodiment, preferably, the fixing component 215 consists of a fixing block 2151, a fixing groove 2152, and a sleeve 2153. The sleeve 2153 is fitted onto the surface of the screw 211 and fits against the side of the bracket 3. The fixing groove 2152 is opened on the side of the bracket 3. The fixing block 2151 is disposed inside the fixing groove 2152. The fixing component 215 fixes the position of the screw 211 after use, ensuring the stability of the tool 23 after position adjustment. The fixing block 2151 and the fixing groove 2152 are in a snap-fit ​​state. The sleeve 2153 has a hollow cylindrical structure. Silicone seats are provided between the fixing block 2151 and the fixing groove 2152, and between the screw 211 and the sleeve 2153.

[0021] The working principle and usage process of this utility model are as follows: During the processing of diodes in electronic components, a diode forming machine is used to form and cut the diode leads. During operation, the bending mold 4 and the shearing assembly 2 are used to bend and shear the diode leads, thereby completing the diode forming process. When it is necessary to adjust the position of the shearing tool 23, the sleeve 2153 is pulled outward, causing the sleeve 2153 to move on the surface of the screw 211, and the fixing block 2151 and the fixing groove 2152 are separated, so that the screw 211 loses its limit. Then, the screw 211 is rotated. Through the threaded connection between the screw 211 and the support rod 21, the rotation of the screw 211 causes the sheath 22 to move on the end surface of the support rod 21, thereby adjusting the position of the tool 23. Then, the sleeve 2153 is pressed forward, so that the fixing block 2151, the fixing groove 2152 and the inner side of the sleeve 2153 are fixed to the surface of the screw 211 by the silicone block.

[0022] 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 component forming mechanism, comprising multiple shafts installed between a main body (1) and a support (3), characterized in that: A bending die (4) is installed on multiple shafts. A shearing assembly (2) is symmetrically installed at the bottom of multiple shafts and between the main body (1) and the bracket (3). The shearing assembly (2) consists of a support rod (21), a sleeve (22), and a cutter (23). The sleeve (22) is located at the end of the support rod (21), and the cutter (23) is installed at the end of the sleeve (22).

2. The component forming mechanism according to claim 1, characterized in that: An adjustment assembly is provided at the connection between the inner side of the support rod (21) and the inner side of the sheath (22). The adjustment assembly consists of a screw (211), a rotating groove (212), a limiting assembly (213), a slot (214), a fixing assembly (215), and a threaded groove (216). The rotating groove (212) is located on the inner side of the sheath (22), the threaded groove (216) is located on the inner side of the support rod (21), the slot (214) is located at the end of the sheath (22), the screw (211) passes through the inner side of the threaded groove (216), one end of the screw (211) is inserted into the inner side of the rotating groove (212), and the other end of the screw (211) passes through the bracket (3) to the outside. The limiting assembly (213) is located at the connection between the end of the support rod (21) and the inner side of the sheath (22), and the fixing assembly (215) is located on the side of the bracket (3).

3. The component forming mechanism according to claim 2, characterized in that: The limiting component (213) consists of a limiting groove (2131) and a limiting block (2132). The limiting groove (2131) is opened at the end of the sheath (22). The inner side of the rotating groove (212), the inner side of the limiting groove (2131), and the inner side of the slot (214) are in a connected state.

4. The component forming mechanism according to claim 2, characterized in that: The end surface of the screw (211) is in contact with the inner wall of the rotating groove (212), and the screw (211) is a cylindrical structure.

5. The component forming mechanism according to claim 2, characterized in that: The fixing component (215) consists of a fixing block (2151), a fixing groove (2152), and a sleeve (2153). The sleeve (2153) is fitted onto the surface of the screw (211) and fits against the side of the bracket (3). The fixing groove (2152) is opened on the side of the bracket (3). The fixing block (2151) is located inside the fixing groove (2152). The fixing block (2151) and the fixing groove (2152) are in a snap-fit ​​state.

6. The component forming mechanism according to claim 5, characterized in that: The sleeve (2153) has a hollow cylindrical structure.

7. The component forming mechanism according to claim 5, characterized in that: Silicone seats are provided between the fixing block (2151) and the fixing groove (2152) and between the screw (211) and the sleeve (2153).