Precision metal parts manufacturing refers to the process of shaping metal materials—such as steel, aluminum, copper, and stainless steel—into high-accuracy, complex components using techniques like turning, milling, grinding, stamping, and CNC machining. The core of this process lies in controlling dimensional tolerances (as tight as ±0.001mm), geometric tolerances, and surface finishes. It is widely applied in industries such as automotive, medical devices, aerospace, and telecommunications.

Common processes include:  CNC Machining: Suitable for complex 3D shapes, offering high precision and flexibility.  Stamping: Ideal for high-volume production of thin-walled metal parts, with high efficiency.  Turning: Primarily used for rotational parts like shafts and sleeves.  Milling: Used for machining planes, curves, slots, and holes.  Wire EDM / EDM: For machining high-hardness materials or complex molds.  Laser Cutting / Waterjet Cutting: Suitable for precision sheet metal blanking.  Surface Treatment: Such as plating, anodizing, sandblasting, and passivation, for corrosion resistance or aesthetics. 

Selection should consider:  Functional Requirements: Strength, hardness, wear resistance, corrosion resistance, conductivity, etc.  Process Suitability: Aluminum (easy to machine, lightweight), stainless steel (corrosion-resistant), copper (good conductivity), titanium alloys (high strength, biocompatible).  Cost and Lead Time: Common materials (e.g., 45# steel, 6061 aluminum) are cost-effective and readily available; specialty alloys (e.g., Inconel, molybdenum) are more expensive and may require pre-ordering.

Material Cost: Raw material type, usage, and market fluctuations.  Complexity of Machining: Number of processes, precision requirements, special treatments (e.g., mirror polishing).  Order Quantity: High volumes can amortize mold/programming costs, reducing unit prices.  Quality Certifications: Certifications like medical (ISO 13485) or automotive (IATF 16949) may increase management costs.  Surface Treatment and Packaging: Special coatings, vacuum packaging, etc., add to the cost.

Standard Tolerance: ±0.1mm or above, suitable for structural parts, housings, etc.  Precision Tolerance: ±0.01mm to ±0.05mm, suitable for mechanical assembly parts.  High-Precision Tolerance: Within ±0.005mm, suitable for critical components in aerospace, optical instruments, etc. Recommendation: Define tolerances based on actual functional needs, as unnecessarily tight tolerances significantly increase costs.