Novel Fatigue Crack Propagation Analysis of Solder Joint Using Singularity of Strain Energy Density in the Crack Tip Near Field

Abstract

This study investigated a singularity parameter of strain energy density by which the path-independent property is guaranteed in the analysis of fatigue crack propagation in a solder joint by using the finite element method. When plastic deformation was dominant, an inverse relationship obeying the HRR singularity theory held with the strain range ΔW, which was calculated using the volume average of the element solutions in an area of arbitrary size around the crack tip and the size of the area L_area. Therefore, the path-independent property was guaranteed using the proportional constant ΔW_c of the inverse relationship. In contrast, the path-independent property of ΔW_c was lost under elasto-plastic deformation where the unloading effects could not be ignored or under creep deformation where the generalized Garofalo law was used for the constitutive equation. In this study, ΔW_{Near field}, which was calculated by extrapolation from ΔW obtained in the first field around the crack tip and the second field inside the first field, was proposed as a new parameter in fatigue crack propagation analysis. ΔW_{Near field} exhibited the path-independent property for various loading conditions and it was demonstrated by FEM analysis using the fatigue data of Sn–5.0Sb measured in a past study that highly accurate fatigue crack propagation analysis of solder joints is possible using ΔW_{Near field}.

Fatigue crack propagation curves for each size of the first field L_area.