Competitive Fracture Mechanism and Microstructure-Related Life Assessment of GH4169 Superalloy in High and Very High Cycle Fatigue Regimes

IF 3.1 2区材料科学 Q2 ENGINEERING, MECHANICAL

Fatigue & Fracture of Engineering Materials & Structures Pub Date : 2024-10-09 DOI:10.1111/ffe.14451

Muhammad Imran Lashari, Cheng Li, Asif Mahmood, Wei Li

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Abstract

High and very high cycle fatigue tests were performed to examine the microstructure and fracture mechanism of GH4169 superalloy in combination with techniques including electron-backscatter diffraction (EBSD). Fractographic analysis revealed that surface failures are induced by surface flaws, whereas internal failures are caused by pores, facets, and inclusions. The three-dimensional observation shows that fracture surfaces exhibit an irregular texture due to crystallographic mismatch of grains and plastic deformation at the crack tip. Based on EBSD analysis, Euler angles exhibited a complex geometry of grain orientation at the crack tip area, hindering crack propagation as evidenced by lower values of the Schmid factor and misorientation at the crack tip. Furthermore, the threshold values of small and long cracks decrease, whereas the transformation sizes from small to long crack growth increase from surface to internal failure. Finally, a novel microstructure defect-based life prediction model is established, and the predicted results demonstrate a close resemblance to experimental outcomes.

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GH4169 超级合金在高循环和超高循环疲劳状态下的竞争性断裂机制和与微观结构相关的寿命评估

为了研究 GH4169 超合金的微观结构和断裂机理，结合电子背散射衍射 (EBSD) 等技术，进行了高循环和超高循环疲劳试验。断口分析表明，表面失效是由表面缺陷引起的，而内部失效则是由孔隙、刻面和夹杂物引起的。三维观察结果表明，由于晶粒的晶体学错配和裂纹尖端的塑性变形，断裂表面呈现出不规则的纹理。根据 EBSD 分析，欧拉角在裂纹尖端区域显示出复杂的晶粒取向几何形状，阻碍了裂纹的扩展，这一点可以从较低的 Schmid 因子值和裂纹尖端的错误取向得到证明。此外，小裂纹和长裂纹的临界值降低了，而从表面到内部失效，小裂纹到长裂纹增长的转变尺寸增大了。最后，建立了一个基于微结构缺陷的新型寿命预测模型，其预测结果与实验结果非常相似。

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

Fatigue & Fracture of Engineering Materials & Structures 工程技术-材料科学：综合

CiteScore

6.30

自引率

18.90%

发文量

256

审稿时长

4 months

期刊介绍： Fatigue & Fracture of Engineering Materials & Structures (FFEMS) encompasses the broad topic of structural integrity which is founded on the mechanics of fatigue and fracture, and is concerned with the reliability and effectiveness of various materials and structural components of any scale or geometry. The editors publish original contributions that will stimulate the intellectual innovation that generates elegant, effective and economic engineering designs. The journal is interdisciplinary and includes papers from scientists and engineers in the fields of materials science, mechanics, physics, chemistry, etc.