橡胶支座振动响应的混合预测方法

IF 0.8 4区 工程技术 Q4 ACOUSTICS
H. Ucar, I. Basdogan
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引用次数: 1

摘要

在无法直接测量其运行行为的复杂结构上,准确预测其振动响应是设计优化、部件选择和状态监测的重要工程问题。识别作用在结构上的激振力是振动响应预测(VRP)的重要步骤。在由于物理限制而不可能或不实际进行直接测量的情况下,一种常用的方法是根据反向频响函数(FRF)矩阵和在激励力传递经过的点处测量的振动响应向量的乘法来识别激励力。然而,在某些情况下,测量频响几乎是不可能的。在其他可能进行测量的情况下,它们可能容易产生重大错误。此外,由于一个或几个模态主导结构的动力学,反转的频响矩阵可能是病态的。为了提高力识别的步骤和减少实验难度,以往的研究主要集中在调节方法或数值模型上。然而,调节方法会导致额外的测量,并且由于模拟模型与实际系统之间的不一致,仅使用数值模型会降低精度。针对这些问题,本文提出了一种结合数值模拟和实验测量结果的混合VRP方法。建立准确的数值模型和正确选择力识别点是该方法的主要要求。结合橡胶支座的结构被用来演示所提出的方法。数值模型包括橡胶的超弹性和粘弹性建模,以准确地反映系统的行为。力识别点的选择基于一个度量,该度量由整个感兴趣频率的频响矩阵的平均条件数组成。结果表明,所提出的混合方法优于其他替代方法,其中预测仅基于数值结果或实验测量。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Vibration Response Prediction on Rubber Mounts with a Hybrid Approach
Accurate prediction of the vibration response at a point on a complex structure, where the operational behavior cannot be measured directly, is an important engineering problem for design optimization, component selection and condition monitoring. Identifying the exciting forces acting on the structure is a major step in the vibration response prediction (VRP). At the point where direct measurement is impossible or impractical due to physical constraints, a common approach is to identify the exciting forces based on multiplication of an inverted frequency response function (FRF) matrix and a vector of vibration responses measured at the points where the exciting forces are transmitted through. However, in some cases measuring FRFs are almost impossible. In other cases, where measuring is possible, they may be prone to significant errors. Furthermore, the inverted FRF matrix may be ill-conditioned due to the one or few modes that dominate the dynamics of the structure. In order to improve the force identification step and reduce the experimental challenges, previous studies focused on either conditioning methods or numerical models. However, conditioning methods result in additional measurements, and using only numerical models causes reduced accuracy due to incongruities between the simulation model and the real system. Considering these problems, a hybrid VRP methodology that incorporates the numerical modeling and experimental measurement results is proposed in this study. Creating an accurate numerical model and properly selecting the force identification points are the main requirements of the proposed methodology. A structure coupled with rubber mounts is used to demonstrate the proposed methodology. The numerical model includes hyperelastic and viscoelastic modeling of the rubber to represent the system behavior accurately. The selection of force identification points is based on a metric that is composed of the average condition number of the FRF matrix across the whole frequency of interest. The results show that the proposed hybrid methodology is superior to other alternative methods where predictions are solely based on numerical results or experimental measurements.
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来源期刊
International Journal of Acoustics and Vibration
International Journal of Acoustics and Vibration ACOUSTICS-ENGINEERING, MECHANICAL
CiteScore
1.60
自引率
10.00%
发文量
0
审稿时长
12 months
期刊介绍: The International Journal of Acoustics and Vibration (IJAV) is the refereed open-access journal of the International Institute of Acoustics and Vibration (IIAV). The IIAV is a non-profit international scientific society founded in 1995. The primary objective of the Institute is to advance the science of acoustics and vibration by creating an international organization that is responsive to the needs of scientists and engineers concerned with acoustics and vibration problems all around the world. Manuscripts of articles, technical notes and letters-to-the-editor should be submitted to the Editor-in-Chief via the on-line submission system. Authors wishing to submit an article need to log in on the IJAV website first. Users logged into the website are able to submit new articles, track the status of their articles already submitted, upload revised articles, responses and/or rebuttals to reviewers, figures, biographies, photographs, copyright transfer agreements, and send comments to the editor. Each time the status of an article submitted changes, the author will also be notified automatically by email. IIAV members (in good standing for at least six months) can publish in IJAV free of charge and their papers will be displayed on-line immediately after they have been edited and laid-out. Non-IIAV members will be required to pay a mandatory Article Processing Charge (APC) of $200 USD if the manuscript is accepted for publication after review. The APC fee allows IIAV to make your research freely available to all readers using the Open Access model. In addition, Non-IIAV members who pay an extra voluntary publication fee (EVPF) of $500 USD will be granted expedited publication in the IJAV Journal and their papers can be displayed on the Internet after acceptance. If the $200 USD (APC) publication fee is not honored, papers will not be published. Authors who do not pay the voluntary fixed fee of $500 USD will have their papers published but there may be a considerable delay. The English text of the papers must be of high quality. If the text submitted is of low quality the manuscript will be more than likely rejected. For authors whose first language is not English, we recommend having their manuscripts reviewed and edited prior to submission by a native English speaker with scientific expertise. There are many commercial editing services which can provide this service at a cost to the authors.
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