1. Material Property Basics: Why It's Generally Stampable
: Typically >=295MPa, which is lower than high-strength steels (e.g., Q355NH), meaning it has better ductility and can withstand plastic deformation during stamping.
: Standard requirements specify elongation >=23% (for thickness <=16mm), indicating good "stretchability"-a key trait to resist cracking when bent or shaped.
2. Key Factors That May Increase Cracking Risk
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Excessive stamping force or speed, which can cause sudden stress concentration beyond the material's bearing capacity.
Insufficient lubrication: Dry stamping increases friction between the die and steel, leading to localized overheating and brittle cracking.
Poor die design: Sharp corners, narrow gaps, or uneven pressure distribution in the die can create stress points.
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Residual internal stress in the steel (e.g., from improper annealing after rolling) can be released during stamping, triggering cracks.
Surface flaws (e.g., scratches, oxide scale) act as stress concentrators, where cracks easily initiate.
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Complex shapes with deep drawing, sharp bends (e.g., bend radius < 1.5× material thickness), or high deformation rates (e.g., multi-pass stamping without intermediate annealing) raise risk.
3. Recommendations to Avoid Cracking
: Use moderate stamping force/speed, and apply steel-compatible lubricants (e.g., mineral oil-based lubricants) to reduce friction.
: Increase bend radii (>=2× material thickness for safety), avoid sharp edges, and ensure uniform pressure.
Pre-treat the material: If the steel has residual stress, perform stress-relief annealing (e.g., 600–650℃ for 1–2 hours) before stamping; remove surface oxide scale via pickling or sandblasting.
: For complex parts, conduct small-batch stamping tests to verify process feasibility before mass production.



