Solving an Aluminum Bracket Failure

ASM Failure Analysis Case Histories: Failure Modes and Mechanisms Pub Date : 2019-06-01 DOI:10.31399/asm.fach.modes.c9001734

B. K. Young

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Abstract

An aircraft engine in which an in-flight fire had occurred was dismantled and examined. A bracket assembly fabricated from 2024 aluminum, one of several failed components, was of prime interest because of apparent heat damage. Scanning electron microscopy was used to compare laboratory-induced fractures made at room and elevated temperatures with the bracket failure. The service failure exhibited grain separation and loss of delineation of the grain boundaries due to melting. SEM revealed deep voids between grains and tendrils that connected grains, which resulted from surface tension during melting. Microscopic examination of polished, etched section through the fractured surface verified intergranular separation and breakdown of grain facets. The absence of any reduction of thickness on the bracket assembly at the point of fracture, along with evidence of intense heat at this point, indicated that little stress had been applied to the part. Comparisons of the service failure and laboratory-induced failures in conjunction with macroscopic and metallographic observations showed that the bracket assembly failed because an intense, localized flame had melted the material.

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解决铝制支架故障

在飞行中发生火灾的飞机发动机被拆除并进行了检查。一个由2024铝制成的支架组件，是几个失效部件之一，由于明显的热损伤而引起了人们的主要兴趣。扫描电子显微镜用于比较室温和高温下实验室诱发的断裂与支架破坏。服务失效表现为晶粒分离和由于熔化而失去晶界的划定。扫描电镜显示，由于熔化过程中的表面张力，晶粒之间和连接晶粒的卷须之间存在很深的空隙。通过断裂面对抛光、蚀刻断面进行显微检查，证实了颗粒切面的晶间分离和破裂。在断裂点的支架组件上没有任何厚度的减少，并且在这一点上有强烈的热量的证据，表明对该部分施加的应力很小。结合宏观和金相观察，对使用故障和实验室引起的故障进行了比较，结果表明，支架组件的故障是由于强烈的局部火焰熔化了材料。

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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ASM Failure Analysis Case Histories: Failure Modes and Mechanisms

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