TY - JOUR
T1 - Fracture mechanisms of Al-steel resistance spot welds: The role of intermetallic compound phases
AU - Cho, Donghyuk
AU - Ghassemi-Armaki, Hassan
AU - Stoughton, Thomas B.
AU - Carlson, Blair E.
AU - Sung, Hyun-Min
AU - Hwang, Jihoon
AU - Legarth, Brian N.
AU - Whan Yoon, Jeong
PY - 2024
Y1 - 2024
N2 - This study explores the mechanical and metallographic characteristics of Al-Steel dissimilar resistance spot welds (RSW), with a particular focus on the intermetallic compound (IMC) phases and their impact on fracture mechanisms. Detailed metallographic analyses and novel miniature lap shear tests with in-situ Digital Image Correlation techniques were conducted to observe the crack propagation behavior. The findings revealed that the IMC phases significantly influence the crack path and fracture mechanisms, leading to variations in fracture energy. Specifically, three distinct IMC phases were identified at the weld interface, each exhibiting unique structural and mechanical properties, with corresponding fracture energies of approximately 0.03 kJ/m2, 1.1 kJ/m2, and 7.5 kJ/m2. These variations highlight the critical role of the IMC phase in determining the fracture behavior of the weld. The study further supported the development and validation of a finite element (FE) model, incorporating a Cohesive Zone Model to simulate debonding behavior and the Hosford-Mean fracture criterion to predict ductile fracture in the Al fusion zone, thereby successfully linking local material characteristics to mechanical properties.
AB - This study explores the mechanical and metallographic characteristics of Al-Steel dissimilar resistance spot welds (RSW), with a particular focus on the intermetallic compound (IMC) phases and their impact on fracture mechanisms. Detailed metallographic analyses and novel miniature lap shear tests with in-situ Digital Image Correlation techniques were conducted to observe the crack propagation behavior. The findings revealed that the IMC phases significantly influence the crack path and fracture mechanisms, leading to variations in fracture energy. Specifically, three distinct IMC phases were identified at the weld interface, each exhibiting unique structural and mechanical properties, with corresponding fracture energies of approximately 0.03 kJ/m2, 1.1 kJ/m2, and 7.5 kJ/m2. These variations highlight the critical role of the IMC phase in determining the fracture behavior of the weld. The study further supported the development and validation of a finite element (FE) model, incorporating a Cohesive Zone Model to simulate debonding behavior and the Hosford-Mean fracture criterion to predict ductile fracture in the Al fusion zone, thereby successfully linking local material characteristics to mechanical properties.
KW - Cohesive zone model (CZM)
KW - Dissimilar welding
KW - Ductile fracture
KW - Heat affected zone (HAZ)
KW - Intermetallic compound (IMC)
U2 - 10.1016/j.engfracmech.2024.110520
DO - 10.1016/j.engfracmech.2024.110520
M3 - Journal article
SN - 0013-7944
VL - 311
JO - Engineering Fracture Mechanics
JF - Engineering Fracture Mechanics
M1 - 110520
ER -