Comparative Low-Cycle Fatigue Behavior of HAYNES 244 Alloy and Waspaloy

Volume 7: Industrial and Cogeneration; Manufacturing Materials and Metallurgy Pub Date : 2021-06-07 DOI:10.1115/gt2021-59619

M. Fahrmann

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Abstract

HAYNES® 244® alloy was chiefly developed to address the need for high-strength, low coefficient of thermal expansion (CTE) alloys for seal rings and cases in advanced gas turbine engines. In addition to these attributes, adequate resistance to low-cycle fatigue (LCF) due to cyclic thermal and mechanical loading during service is critical for such applications. The isothermal LCF performance of commercially produced 0.5” (12.5 mm) thick, fully heat treated plate products of 244 alloy was evaluated by means of axial strain-controlled (R = −1) LCF tests covering total strain ranges up to 1.25 % (without dwells), at temperatures ranging from 800–1400°F (427–760°C). In addition, the comparative LCF performance of Waspaloy, a well-established alloy for turbine cases, was evaluated under selected, nominally identical test conditions. S-N curves were constructed and fitted by the Coffin-Manson equation, allowing the delineation of regimes controlled by the elastic and plastic response of the material. Fracture surfaces were examined in the scanning electron microscope to identify fatigue crack initiation sites and crack propagation modes. Differences between the alloys are discussed in terms of tensile strength and cyclic hardening/softening behavior. Implications for fatigue performance of these alloys under cyclic thermal loading conditions are discussed as well.

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haynes244合金与沃斯帕洛合金的低周疲劳性能比较

HAYNES®244®合金主要是为了满足高强度、低热膨胀系数(CTE)合金在先进燃气涡轮发动机密封圈和壳体的需求而开发的。除了这些特性之外，在使用过程中，由于循环热载荷和机械载荷，对低周疲劳(LCF)有足够的抵抗力对于此类应用至关重要。通过轴向应变控制(R = - 1) LCF测试，在800-1400°F(427-760°C)的温度范围内，评估了商业生产的0.5 " (12.5 mm)厚、完全热处理的244合金板产品的等温LCF性能，该测试覆盖了总应变范围高达1.25%(无凹点)。此外，在选定的、名义上相同的试验条件下，对涡轮壳体用的Waspaloy合金的LCF性能进行了比较评估。S-N曲线由Coffin-Manson方程构造和拟合，允许描述由材料的弹性和塑性响应控制的制度。在扫描电子显微镜下观察断口表面，确定疲劳裂纹的起裂部位和裂纹扩展模式。在抗拉强度和循环硬化/软化行为方面讨论了合金之间的差异。讨论了这些合金在循环热载荷条件下的疲劳性能。

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

Volume 7: Industrial and Cogeneration; Manufacturing Materials and Metallurgy

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