Precision Stamping
This process involves molding plastic around pre-inserted components like metal pins, bushings, or threaded inserts. It improves part strength, reduces assembly costs, and enhances product longevity—widely used in automotive, electronics, and medical devices.
- How It Works:
- Inserting the Component: The first step involves placing an insert (such as a metal part, electrical connector, or threaded insert) into a mold cavity. These inserts are usually pre-manufactured and can include components like metal fasteners, electrical contacts, or even other molded plastic components. The inserts may be held in place manually or using automated robots, depending on the production setup.
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- Enhanced Strength and Durability
- Insert injection molding combines the strength of metal inserts with the flexibility and versatility of plastic, creating parts that are both robust and lightweight. This makes the parts ideal for high-performance applications in industries like automotive and aerospace.
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- Cost-Effective Production
- Insert injection molding combines the strength of metal inserts with the flexibility and versatility of plastic, creating parts that are both robust and lightweight. This makes the parts ideal for high-performance applications in industries like automotive and aerospace.
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- Recision and High Quality
- Insert injection molding combines the strength of metal inserts with the flexibility and versatility of plastic, creating parts that are both robust and lightweight. This makes the parts ideal for high-performance applications in industries like automotive and aerospace.
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- Improved Design Flexibility
- Insert injection molding combines the strength of metal inserts with the flexibility and versatility of plastic, creating parts that are both robust and lightweight. This makes the parts ideal for high-performance applications in industries like automotive and aerospace.
