Comparison of CNC Machining Materials

Stainless Steel 17-4PH is a high-performance martensitic precipitation hardening stainless steel, featuring excellent corrosion resistance and high strength, making it suitable for a wide range of industrial applications. Its chemical composition and physical properties enable its extensive use in fields such as aerospace, chemical engineering, marine engineering, food processing, and nuclear industry. Through appropriate heat treatment processes, its mechanical properties and corrosion resistance can be further optimized.

Stainless steel 316 combines exceptional corrosion resistance with excellent machinability. This unique balance of “high corrosion resistance + ease of processing” makes it a material of choice for applications demanding the highest levels of reliability. It is widely employed in fields such as chemical processing, food production, and marine engineering, where it consistently meets stringent performance requirements across diverse operating conditions.

Brass is an alloy primarily composed of copper and zinc. This golden-hued material not only exhibits excellent weather resistance and corrosion resistance, but its tensile strength also rivals that of low-carbon steel, demonstrating outstanding mechanical properties. Brass boasts exceptional machinability, enabling it to support higher feed rates during processing operations such as cutting and stamping, while requiring minimal cutting fluid. This combination significantly reduces both processing costs and process complexity.

As a versatile and widely used metallic material,aluminum 6061 alloy is well-known in the industrial field for its excellent mechanical properties and outstanding weldability. The designations “T6” and “T651,” as typical temper conditions of this alloy, correspond to specific heat treatment processes: the T6 process achieves strength enhancement through solution treatment followed by artificial aging, while the T651 process adds a pre-stretching deformation step on this basis to optimize residual stress distribution. The combined effect of these two processes significantly improves the material’s mechanical properties and effectively eliminates internal stresses. Owing to their comprehensive advantages in strength, processability, and corrosion resistance, 6061-T6 and 6061-T651 aluminum alloys are highly favored in fields such as aerospace structural components, automotive parts, shipbuilding, and general machinery processing, emerging as key foundational materials supporting modern industrial manufacturing.