Comparison of Low Cycle Fatigue Crack Propagation Methods for Turbine
Exhaust Case 2024-01-6002
The aerospace industry heavily relies on NASGRO as a standard method for crack
propagation analysis, despite encountering challenges due to variations in
stress gradients across flight missions. In response to this issue, this paper
introduces a pioneering methodology that integrates stress gradients at each
time point throughout a mission, computed cycle by cycle using NASGRO. The study
meticulously evaluates the feasibility and efficacy of this approach against
established industry-standard procedures, focusing on the critical topic of low
cycle fatigue (LCF) and underscoring the significance of damage-tolerant design
principles. The methodology encompasses the design of an H-sector in Ansys
Workbench, the execution of stress analysis for a typical flight mission
profile, and the systematic extraction of stress gradients for each cycle at the
pivotal crack nucleation point. Subsequently, NASGRO is employed to estimate
life cycles using both industry-standard baseline methodologies and a
per-gradient approach facilitated by Python scripting. The comparative analysis
encompasses variations in starting crack size, geometry, and time complexity,
offering a comprehensive assessment of the advantages and limitations of each
life estimation technique. The findings of the study significantly contribute to
the advancement of damage tolerance design in aerospace applications, furnishing
invaluable insights into more precise crack propagation life estimates. These
insights carry immediate implications for enhancing the safety and reliability
of aircraft components, thereby facilitating the continual refinement of
industry standards.