Selection of Tool Steels for Precision & Special Applications
High-precision manufacturing in electronics, aerospace, and medical devices demands extremely tight mold tolerances and surface finish specifications. Structural defects such as non-metallic inclusions, carbide segregation, or porosity can cause mold failure, while surface pinholes may compromise mirror polishing results.
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Recommendations for Tool Steel Selection
Dimensional Stability and Deep Cryogenic Treatment
Micron-level dimensional stability depends on the phase equilibrium between martensite and retained austenite. Retained austenite is metastable and transforms into unquenched martensite during service time or under stress, causing volume expansion and mold distortion. Deep cryogenic treatment (DCT, -80°C to -196°C) promotes near-complete martensitic transformation, stabilizing the microstructure. Additionally, this process facilitates the precipitation of fine η-carbides, further enhancing the material’s wear resistance.
Polishing Performance and ESR Process Advantages
For SPI A1 or A2 grade mirror polishing requirements, polishing performance directly determines mold finish quality. Surface defects like “pinhole” or “orange peel” primarily result from non-metallic inclusions (oxides) shedding or compositional segregation. Conventional electric furnace steels, with their higher inclusion content, struggle to meet high-grade polishing requirements. The Electro-Slag Remelting (ESR) process employs liquid-metal chemical refining to effectively remove oxides and sulfides, ensuring a uniform, pure microstructure. Steel processed via ESR achieves defect-free, optical-grade polished surfaces.
Comparison Table
| Grade | Inclusion Cleanliness | Polishability | Wear Resistance | Ideal Application |
| Standard D2 | Moderate (May contain large carbides/oxides) | Good (Limited by segregation) | High (Large Cr-carbides) | General blanking, Forming, |
| D2-ESR | High (Sulfur & oxides reduced) | Excellent (Resists pitting/orange peel) | High (Better toughness than Std D2) | Coining dies, High-polish molds, |
| M2 (HSS) | High (Fine carbide distribution) | Good | Very High (High hot hardness) | Lamination dies, Powder compaction, |
FAQ
Coining dies require steels with high compressive yield strength and a pure microstructure to prevent deformation and surface defects. Modified 52100 or D2, refined by electroslag remelting (ESR), are typically selected to ensure mirror-polishing results.
Select steels with high hardness and uniform carbide distribution, such as M2 high-speed steel or D2, to resist scoring and sticking. These materials must withstand abrasive wear and compressive loads reaching 600–800 MPa.
High-speed steels like M2 and M4, or powder metallurgy grades, are best for stamping silicon steel laminations. They resist micro-chipping and edge rounding caused by hard silicon oxide particles more effectively than standard cold-work steels.
Micro forming requires steels with ultrafine grain structures and no macroscopic segregation to prevent localized failure. Applications typically use steels produced via Electroslag Remelting (ESR) or Vacuum Arc Remelting (VAR) for high material purity.
Use steel processed by Electroslag Remelting (ESR), which removes oxides and sulfides that cause “orange peel” or pinholes. ESR ensures the uniform, pure microstructure necessary for defect-free, optical-grade mirror polishing.
Apply deep cryogenic treatment (DCT) at -80°C to -196°C to promote near-complete martensitic transformation. This stabilizes the microstructure by reducing metastable retained austenite, which causes volume expansion and mold distortion.
Standard D2 contains moderate inclusions and offers good polishability, while D2-ESR has high cleanliness with reduced sulfur and oxides. D2-ESR provides excellent polishability, resists pitting, and offers higher toughness than standard D2.