System reliability analysis with the response surface method

J. Gyekenyesi, B. Strack, E. Zampino, S. Pai
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引用次数: 1

Abstract

The reliability of a simple turbomachinery model was calculated to demonstrate the application of a newly developing system integration tool, Probabilistic Design and Analysis Framework(PRODAF), along with efficient probabilistic methods using a response surface method. The model represents a system consisting of hypothetical turbine components. The parts include a blade, disk, and shaft with an applied angular velocity. All the components were modeled with the properties of the nickel alloy, Inconel 718. A response surface was calculated for the system of components to improve probabilistic computational efficiency. In addition, a fast probability integration method, Advanced First Order Reliability Method (AFORM), was used for the probabilistic analysis in order to provide an efficient analysis as possible. Geometric dimensions, the applied load, and material yield strength were varied for this study. The probability of failure was determined using the maximum first principal stress response and the material yield strength. A simple G function using the difference between strength and loading stress was used to determine failure limits. The probabilistic sensitivity of the failure response relative to the individual variables was determined also with material yield strength having the greatest influence. The model was recreated with every iteration of the probabilistic analysis in order to vary the geometry. As a result, the response surface method has a significant impact on improving computational efficiency and enabling reliability analysis with rapid turnaround.
用响应面法分析系统可靠性
为了演示新开发的系统集成工具概率设计与分析框架(PRODAF)以及基于响应面法的高效概率方法的应用,对一个简单涡轮机械模型进行了可靠性计算。该模型代表了一个由假设的涡轮部件组成的系统。这些部件包括叶片、圆盘和具有应用角速度的轴。所有部件都具有镍合金Inconel 718的性能。为了提高概率计算效率,对组件系统进行了响应面计算。此外,为了提供尽可能高效的分析,采用了一种快速概率积分方法——高级一阶可靠性法(AFORM)进行概率分析。在这项研究中,几何尺寸、施加的载荷和材料的屈服强度是不同的。失效概率由最大第一主应力响应和材料屈服强度确定。使用强度与加载应力之差的简单G函数来确定破坏极限。破坏响应的概率敏感性相对于个别变量也确定了材料屈服强度有最大的影响。在概率分析的每一次迭代中,模型都被重新创建,以改变几何形状。因此,响应面法对提高计算效率和实现快速周转的可靠性分析具有重要影响。
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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