Shortening the heat treatment of third generation advanced high strength steels by forming carbide free bainite in the presence of martensite

Journal Article (2025)
Author(s)

Daniel dos Santos Avila (TU Delft - Team Maria Santofimia Navarro)

Stefan M.C. van Bohemen (Tata Steel Europe Limited)

RM Huizenga (TU Delft - Team Amarante Bottger)

Sven Erik Offerman (TU Delft - Team Erik Offerman)

M.J. Santofimia (TU Delft - Team Maria Santofimia Navarro)

Research Group
Team Maria Santofimia Navarro
DOI related publication
https://doi.org/10.1016/j.msea.2025.148241
More Info
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Publication Year
2025
Language
English
Research Group
Team Maria Santofimia Navarro
Volume number
931
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Abstract

Successful implementation of third generation advanced high strength steels (3rd gen AHSS) can be accelerated by developing steels that can be heat treated in existing industrial lines. Here, we develop new carbide free bainitic (CFB) steels in which bainite formation is accelerated by a 0.2 volume fraction of prior martensite and thus can be realized in 5 min, making them suitable for manufacturing in modern continuous annealing lines for bare steel strips. The resulting microstructure consists of bainitic ferrite, tempered martensite, and retained austenite. Carbon and silicon had the most pronounced effect on the mechanical properties among the studied alloying elements (manganese, niobium, chromium, and molybdenum) because of their influence on the fraction and stability of retained austenite. Our proposed treatment, which we call bainite accelerated by martensite (BAM), showed higher strength and lower global formability than traditional CFB without prior martensite (also called TRIP-assisted bainitic ferrite, TBF) and quenched and partitioned (Q&P) steels. Five of the designed steels showed tensile strength higher than 1370 MPa, a total elongation higher than 8%, and hole expansion capacity higher than 30%, and thus meet the requirements for the strongest commercial grades of complex phase steels with improved formability. This work broadens the possibilities of using existing industrial lines for manufacturing novel 3rd gen AHSS.