Strain energy-based fatigue failure analyses of LB-PBF Inconel 718: Effect of build orientation

Authors

Arash P. Jirandehi, LSU College of Engineering
Behnam Hajshirmohammadi, LSU College of Engineering
Patricio Carrion, Samuel Ginn College of Engineering
M. M. Khonsari, LSU College of Engineering
Nima Shamsaei, Samuel Ginn College of Engineering
Shuai Shao, Samuel Ginn College of Engineering

Document Type

Article

Publication Date

4-1-2022

Abstract

Additively manufactured Inconel 718 parts fabricated in three build orientations (horizontal, vertical, and angled at 45 degrees) are tested in fully-reversed bending fatigue mode. Damping measurements via the Impulse Excitation technique are used to assess the defects content in the microstructure and fractography analysis is performed to detect the root cause of failure. Two micro- and macro-scale methodologies of fatigue damage estimation based on the dissipated heat per cycle and the statistical estimation of micro-plastic strain energies are used to assess fatigue damage. It is shown that at a given stress level, the vertically built specimens endure the most fatigue damage before failure while the diagonally built ones sustain the least. The fatigue life is estimated for arbitrary load amplitudes via a microstructure-sensitive algorithm with acceptable accuracy as compared to the experiments.

Publication Source (Journal or Book title)

Additive Manufacturing

Recommended Citation

Jirandehi, A., Hajshirmohammadi, B., Carrion, P., Khonsari, M., Shamsaei, N., & Shao, S. (2022). Strain energy-based fatigue failure analyses of LB-PBF Inconel 718: Effect of build orientation. Additive Manufacturing, 52 https://doi.org/10.1016/j.addma.2022.102661