Micro Plastic Injection Mold for 0.1mm Precision Medical Parts

1. Traditional Machining Methods

CNC Machining (Computer Numerical Control)

• Process: Uses computer-controlled milling, turning, or grinding to shape mold steel (e.g., P20, H13).

• Advantages: High precision, excellent surface finish, suitable for complex geometries.

• Applications: Prototype molds, medium-to-high production molds.

Electrical Discharge Machining (EDM)

• Process: Uses electrical sparks to erode metal, ideal for hard materials or intricate details.

• Wire EDM: Cuts precise contours using a thin wire.

• Sink EDM: Creates cavities and complex 3D shapes with an electrode.

• Advantages: No mechanical stress, works with hardened steel.

Grinding & Polishing

• Process: Achieves ultra-smooth surfaces for high-gloss plastic parts.

• Applications: Optical lenses, automotive parts, and cosmetic components.

2. Additive Manufacturing (3D Printing)

Metal 3D Printing (SLM/DMLS)

• Process: Laser sintering of metal powders (e.g., tool steel, aluminum) to create molds with conformal cooling channels.

• Advantages: Faster cooling, reduced cycle times, and complex geometries.

• Limitations: Higher cost, limited size.

Indirect Mold Making

• Process: 3D print a plastic or wax pattern, then use investment casting to produce a metal mold.

• Materials: Suitable for aluminum or low-melting-point alloys.

3. Rapid Tooling Techniques

Aluminum Molds

• Process: CNC-machined from softer aluminum (e.g., 7075).

• Advantages: Faster production, lower cost.

• Limitations: Shorter lifespan (10,000–100,000 cycles).

Silicone & Soft Tooling

• Process: 3D-printed or cast silicone molds for low-melting-point plastics (e.g., urethane).

• Applications: Prototyping, small-batch production.