Modeling low cycle fatigue (LCF) of additively manufactured Hastelloy X using An accelerated crystal plasticity fatigue damage model

IF 5.7 2区材料科学 Q1 ENGINEERING, MECHANICAL

International Journal of Fatigue Pub Date : 2025-04-07 DOI:10.1016/j.ijfatigue.2025.108980

Jiahao Cheng , Daniel Ryan , Brandon Kemerling , Patxi Fernandez-Zelaia , Sudhakar Bollapragada , Tyler Boveington , Michael M. Kirka

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Abstract

This paper presents a microstructure-based model for low cycle fatigue (LCF) behavior and life of Nickel-based alloy Hastelloy X manufactured using laser-powder bed fusion (L-PBF) additive manufacturing (AM). AM Hastelloy X, a solution-strengthened alloy, is tested at elevated temperature under fully reversed LCF conditions at different strain levels. A generalized plane strain finite element model is generated from electron backscatter diffraction (EBSD) characterization. The constitutive behavior of the material under fatigue is modeled using crystal plasticity and calibrated with both monotonic tensile and cyclic stress–strain data. The fatigue micro-crack initiation and propagation in the microstructure is modeled using a modified Chaboche fatigue damage model. An embedded boundary condition with a homogenous medium is used to apply the cyclic deformation and prevent numerically introduced over-constraints during fatigue simulation. A ‘cycle-jump’ method is used to accelerate the fatigue simulation and reduce the computational cost. The simulation results are compared to LCF experiments, showing satisfactory matches in cyclic stress behavior and number of cycles to macro-crack initiation for all applied strain ranges. In addition, the model illustrates the potential for quantifying microscale fatigue life impacting factors such as microstructure and surface roughness, which is needed to accurately quantify the reliability of AM components in service.

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用加速晶体塑性疲劳损伤模型模拟增材制造哈氏合金X的低周疲劳

本文建立了一种基于显微组织的模型，用于研究采用激光-粉末床熔合（L-PBF）增材制造（AM）制造的镍基哈氏合金X的低周疲劳（LCF）行为和寿命。AM Hastelloy X是一种溶液强化合金，在不同应变水平下的完全反向LCF条件下进行了高温测试。通过电子背散射衍射（EBSD）表征，建立了广义平面应变有限元模型。材料在疲劳下的本构行为采用晶体塑性建模，并使用单调拉伸和循环应力-应变数据进行校准。采用改进的Chaboche疲劳损伤模型模拟了疲劳微裂纹在微观组织中的萌生和扩展过程。在疲劳模拟过程中，采用均匀介质嵌入边界条件来施加循环变形，防止数值引入的过约束。采用“周期跳变”方法加速了疲劳模拟，降低了计算成本。将模拟结果与LCF实验结果进行了比较，结果表明，在所有应变范围内，循环应力行为和循环次数与宏观裂纹起裂的匹配都很好。此外，该模型还说明了量化微观尺度疲劳寿命影响因素（如微观结构和表面粗糙度）的潜力，这是准确量化服役中的增材制造部件可靠性所需要的。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

International Journal of Fatigue 工程技术-材料科学：综合

CiteScore

10.70

自引率

21.70%

发文量

619

审稿时长

58 days

期刊介绍： Typical subjects discussed in International Journal of Fatigue address: Novel fatigue testing and characterization methods (new kinds of fatigue tests, critical evaluation of existing methods, in situ measurement of fatigue degradation, non-contact field measurements) Multiaxial fatigue and complex loading effects of materials and structures, exploring state-of-the-art concepts in degradation under cyclic loading Fatigue in the very high cycle regime, including failure mode transitions from surface to subsurface, effects of surface treatment, processing, and loading conditions Modeling (including degradation processes and related driving forces, multiscale/multi-resolution methods, computational hierarchical and concurrent methods for coupled component and material responses, novel methods for notch root analysis, fracture mechanics, damage mechanics, crack growth kinetics, life prediction and durability, and prediction of stochastic fatigue behavior reflecting microstructure and service conditions) Models for early stages of fatigue crack formation and growth that explicitly consider microstructure and relevant materials science aspects Understanding the influence or manufacturing and processing route on fatigue degradation, and embedding this understanding in more predictive schemes for mitigation and design against fatigue Prognosis and damage state awareness (including sensors, monitoring, methodology, interactive control, accelerated methods, data interpretation) Applications of technologies associated with fatigue and their implications for structural integrity and reliability. This includes issues related to design, operation and maintenance, i.e., life cycle engineering Smart materials and structures that can sense and mitigate fatigue degradation Fatigue of devices and structures at small scales, including effects of process route and surfaces/interfaces.