TY - EJOU AU - Suzuki, Kiyoaki T. AU - Dancette, Sylvain AU - Tokita, Shun AU - Sato, Yutaka S. TI - Hybrid Inverse Modeling Technique to Determine the Fracture Properties of Intermetallic Layer Formed at Al/Steel Dissimilar Weld Interface T2 - The International Conference on Computational \& Experimental Engineering and Sciences PY - 2024 VL - 31 IS - 2 SN - 1933-2815 AB - Dissimilar welding of aluminum (Al) alloy to steel has been a long-running scientific and technological problem mainly for the automotive industry. It would allow to achieve new designs of optimized vehicle structures combining strength, lightweight and energy absorption ability. However, the weld strength is limited because of a brittle intermetallic layer (IML) formed at the weld interface. In our previous study, we demonstrated a significant improvement in weld strength by the addition of Ni to aluminum alloy. However, the effect of Ni addition on the fracture properties of IML remains unexplored. Moreover, additional Ni should also affect the yield strength and deformability of Al alloy itself. Hence, in this study, a hybrid inverse modeling technique was used to determine the fracture properties of IML. Digital image correlation (DIC) was used to measure the displacement field across the sample surface during tensile shear tests. Finite element model (FEM) with a cohesive zone model (CZM) was used to model the fracture through the IML between Al and steel. Displacement filed experimentally measured by DIC was applied to the FEM to precisely determine the CZM parameters, i.e. interfacial strength and fracture energy of IML. This hybrid DIC-FEM inverse modeling technique was used to analyze different Al/steel welds with varying composition of Al alloys (A1050 and Al-Ni). From a wide range of tentative interfacial strength and fracture energy for the CZM, this study clarified that the interfacial strength of IML formed at Al-Ni/steel weld was higher than that of A1050/steel one without Ni addition. KW - Dissimilar welding; Al/steel welds; intermetallic layer; cohesive zone model; digital image correlation DO - 10.32604/icces.2024.012072