发动机叶片侵蚀-张力耦合下侵蚀率的预测模型

IF 5.3 1区 工程技术 Q1 ENGINEERING, MECHANICAL Wear Pub Date : 2024-11-02 DOI:10.1016/j.wear.2024.205621
Yu Zhang , Yun-Fei Jia , Xin-Wei Sun , Zhen-Hua Fang , Jian-Jun Yan , Cheng-Cheng Zhang , Li Xin , Xian-Cheng Zhang
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引用次数: 0

摘要

固体颗粒侵蚀对航空发动机性能的影响对航空安全构成了潜在威胁。准确预测叶片的侵蚀率对于评估发动机的运行寿命至关重要。发动机叶片在运行过程中会受到离心力的作用,从而在拉伸应力的作用下产生侵蚀。本研究设计了一种专门的侵蚀-拉伸耦合试验装置,以探索拉伸应力对受到气固侵蚀的试样的影响。施加相当于屈服强度 60% 的轴向拉伸载荷可促使侵蚀角为 60° 的铝合金试样的侵蚀速率增加 90.2%。此外,流固耦合模拟系统分析了试样在各种侵蚀和拉伸条件下的表面应力分布。随后,我们提出了一种新型侵蚀模型,该模型采用了创新的加速因子,考虑了材料屈服强度、Von Mises 应力分布和侵蚀坑体积。该模型能准确预测圆柱形和简化发动机叶片试样在各种加载条件下的侵蚀率,与实验侵蚀率的偏差小于 18.1%。所构建的侵蚀模型可简明、准确地预测拉伸应力下气固侵蚀试样的侵蚀率。
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A prediction model of erosion rate under erosion-tension coupling for engine blade
The influence of solid particle erosion on aero-engine performance poses a potential threat to aviation safety. Accurate prediction of erosion rates for blades is crucial for assessing the engine's operational lifespan. Engine blades experience centrifugal forces during operation, resulting in erosion under tensile stress. This study has designed a specialized erosion-tension coupling test apparatus to explore the effect of tensile stress on specimens subjected to gas-solid erosion. Applying an axial tensile load equivalent to 60 % of the yield strength prompts a 90.2 % increase in erosion rate for aluminum alloy specimens at a 60° erosion angle. Additionally, fluid-structure interaction simulations systematically analyze the surface stress distribution of specimens under various erosion and tension conditions. Subsequently, a novel erosion model is proposed, incorporating an innovative acceleration factor that considers material yield strength, Von Mises stress distribution, and erosion crater volume. This developed model accurately predicts erosion rates under various loading conditions for cylindrical and simplified engine blade specimens, with a deviation from experimental erosion rates of less than 18.1 %. The constructed erosion model provides a concise and accurate prediction of erosion rates for specimens subjected to gas-solid erosion under tensile stress.
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来源期刊
Wear
Wear 工程技术-材料科学:综合
CiteScore
8.80
自引率
8.00%
发文量
280
审稿时长
47 days
期刊介绍: Wear journal is dedicated to the advancement of basic and applied knowledge concerning the nature of wear of materials. Broadly, topics of interest range from development of fundamental understanding of the mechanisms of wear to innovative solutions to practical engineering problems. Authors of experimental studies are expected to comment on the repeatability of the data, and whenever possible, conduct multiple measurements under similar testing conditions. Further, Wear embraces the highest standards of professional ethics, and the detection of matching content, either in written or graphical form, from other publications by the current authors or by others, may result in rejection.
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