TY - JOUR
T1 - Low-alloyed TRIP-steels with optimized strength, forming and welding properties
AU - Traint, Sandra
AU - Pichler, Andreas
AU - Sierlinger, Robert
AU - Pauli, Heinrich
AU - Werner, Ewald A.
PY - 2006
Y1 - 2006
N2 - To obtain the superior strength-ductility-balance of TRIP-grades, a special chemical composition in combination with well adapted processing parameters are a prerequisite. Despite of their excellent formability performance in terms of drawability as characterized by high n- and elongation values, compared to mild steels TRIP-grades are challenging in the press and the body shops. The high strength level in combination with the high work hardening of TRIP-grades result in higher levels of spring back compared to mild steels and higher press forces are required. Furthermore, a higher sensitivity to failure for sharp bending radii and a deterioration of the formability of punched edges is reported for TRIP-grades. While spring back can only be minimized by advanced forming processes supported by new simulation techniques with improved ability to predict spring back, the sensitivity to failure under special forming conditions can be influenced by optimizing microstructural features. Contrary to the forming behaviour, which is influenced significantly by the microstructure, the weldability is mainly governed by the chemical composition and the surface condition of the material. The high carbon content of TRIP-grades compared to mild steels results in a higher hardening potential after welding. Additionally, a fracture behaviour untypical for mild steels after destructive testing of spot welds is sometimes observed for TRIP-grades, which is assessed critically by some OEMs. In this work, after a discussion of the processing conditions, possibilities are demonstrated to improve the forming behaviour by an optimization of the microstructure and the spot weldability by adapting the chemical composition of low-alloyed TRIP grades. First very promising results for TRIP-grades with a minimum tensile strength level of 700 MPa are discussed.
AB - To obtain the superior strength-ductility-balance of TRIP-grades, a special chemical composition in combination with well adapted processing parameters are a prerequisite. Despite of their excellent formability performance in terms of drawability as characterized by high n- and elongation values, compared to mild steels TRIP-grades are challenging in the press and the body shops. The high strength level in combination with the high work hardening of TRIP-grades result in higher levels of spring back compared to mild steels and higher press forces are required. Furthermore, a higher sensitivity to failure for sharp bending radii and a deterioration of the formability of punched edges is reported for TRIP-grades. While spring back can only be minimized by advanced forming processes supported by new simulation techniques with improved ability to predict spring back, the sensitivity to failure under special forming conditions can be influenced by optimizing microstructural features. Contrary to the forming behaviour, which is influenced significantly by the microstructure, the weldability is mainly governed by the chemical composition and the surface condition of the material. The high carbon content of TRIP-grades compared to mild steels results in a higher hardening potential after welding. Additionally, a fracture behaviour untypical for mild steels after destructive testing of spot welds is sometimes observed for TRIP-grades, which is assessed critically by some OEMs. In this work, after a discussion of the processing conditions, possibilities are demonstrated to improve the forming behaviour by an optimization of the microstructure and the spot weldability by adapting the chemical composition of low-alloyed TRIP grades. First very promising results for TRIP-grades with a minimum tensile strength level of 700 MPa are discussed.
KW - Forming behaviour
KW - Mechanical properties
KW - Spot weldability
KW - TRIP-steels
UR - http://www.scopus.com/inward/record.url?scp=33750078970&partnerID=8YFLogxK
U2 - 10.1002/srin.200606442
DO - 10.1002/srin.200606442
M3 - Article
AN - SCOPUS:33750078970
SN - 1611-3683
VL - 77
SP - 641
EP - 649
JO - Steel Research International
JF - Steel Research International
IS - 9-10
ER -