基于频率灵敏度和模态振型的圆柱壳损伤检测

Q4 Engineering
W. Zhi
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引用次数: 0

摘要

将损伤定位保证准则(DLAC)扩展到基于固有频率灵敏度和振型偏差的圆柱壳损伤定位和评估。利用无缺陷有限元模型得到的频率灵敏度计算理论频率变化。通过比较损伤引起的理论频率变化和实测频率变化,可以很容易地得到损伤的轴向位置。对于轴对称壳体,引入模态振型的附加信息来精确定位损伤位置。损伤程度可用一阶近似法估计。通过对自由-自由壳、简支壳和自由夹紧壳几种损伤情况进行损伤定位和损伤定尺,评价了损伤检测方案的可行性和实用性。仿真结果表明,所提出的检测方案能够很好地定位单个或多个损伤位置。还观察到,可以在相对较小的误差内估计损坏程度。验证了该方法在存在测量误差时的鲁棒性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
DAMAGE DETECTION IN CIRCULAR CYLINDRICAL SHELLS BY FREQUENCY SENSITIVITIES AND MODE SHAPES
The damage location assurance criterion (DLAC) is extended to locate and assess damage in a circular cylindrical shell based on natural frequency sensitivities and mode shape deviations. Frequency sensitivities obtained from a defect-free finite element model are applied to calculate the theoretical frequency changes. The axial position of the damage can be easily obtained by comparing the theoretical and measured frequency changes due to damage. For the shell is axis-symmetric, additional information of mode shapes is introduced to locate the exact damage position. The damage extent can be estimated by the first order approximation method. The feasibility and practicality of the damage detection scheme are evaluated by locating and sizing damage for several damage scenarios in the free-free, simple-supports and free-clamped shells, respectively. Simulation results show that the proposed detection scheme can well locate the single or multiple positions of damage. It is also observed that damage extent can be estimated within a relatively small error. The robustness of the proposed method in the presence of measurement errors is demonstrated.
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来源期刊
Journal of Mechanical Strength
Journal of Mechanical Strength Engineering-Mechanical Engineering
CiteScore
0.70
自引率
0.00%
发文量
5969
期刊介绍: Journal of Mechanical Strength is an academic and technical journal governed by China Machinery Industry Federation,sponsored by Zhengzhou Research Institute of Mechanical Engineering Co., Ltd. and Chinese Mechanical Engineering Society. It mainly publishes research articles, reviews and newsletters with innovative, economic and practical application in the fields of machinery, strength, vibration and material strength. Journal of Mechanical Strength was founded in May 1975, bi-monthly issued. The publishing scope covers mechanical structure strength, micro electro mechanical systems (MEMS), reliability, optimization design, mechanical design, calculation methods, fatigue, damage, fracture, vibration, noise, fault diagnosis and monitoring, testing technology, detection and evaluation, testing instruments, experimental stress analysis, residual stress, failure analysis and related interdisciplinary subjects. The aimed readers of the journal are researchers, designers and developers in machinery industry, as well as teachers and students in universities. The journal is included by the Statistical Source Journal of Chinese Scientific and Technological Papers (Key Magazine of China Technology) (since 1989), Chinese Core Journal (since 1992), Important Chinese Journal of Academic Degrees and Postgraduate Education (since 1995), source journal of the Chinese Science Citation Database (since 1996), Science Abstract (UK) (since 1995), China Quality Scientific and Technological Journals (300 journals) (2008), Top 20 Journals of Natural Science of Henan Province (2008), RCCSE China Authoritative Academic Journal (A+) (2012), and Top 20 Journals of Natural Science of Henan Province (2013). The Journal is also indexed by Scopus Database,Chemical Abstract (CA), Japan Science and Technology Agency (JST), and Report of World Journals Clout Index (WJCI) (2021).
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