Finite element model to investigate the dynamic instability of ring stiffened conical shells subjected to flowing fluid

IF 3.5 3区工程技术 Q1 MATHEMATICS, APPLIED

Finite Elements in Analysis and Design Pub Date : 2024-07-31 DOI:10.1016/j.finel.2024.104221

Mohammadamin Esmaeilzadehazimi, Aouni A. Lakis, Mohammad Toorani

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引用次数: 0

Abstract

In this study, the vibration stability (i.e., static divergence) and critical velocity of fluid-conveying, ring-stiffened, truncated conical shells are investigated under various boundary conditions. The shell is characterized using Sanders’ theory, while the fluid is modeled using a velocity potential approach with the impermeability condition at the fluid-shell interface. Using linear superposition, the natural frequencies corresponding to each flow velocity are determined by satisfying the dynamic characteristic equation and boundary conditions. Critical velocities are identified where the natural frequencies vanish, indicating static divergence. Parametric studies are conducted to investigate the effect of ring stiffeners on the critical velocities with respect to the semi-cone angle, number of rings, and boundary conditions. The proposed model is validated through comparison with published data. It is found that the rings significantly affect the stability of the cone under different boundary conditions. Instability in stiffened shells occurs at higher critical fluid velocities than in unstiffened shells across all boundary conditions. An increase in the vertex angle leads to a decrease in critical flow discharge.

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研究受流动液体作用的环形加劲锥壳动态不稳定性的有限元模型

本研究探讨了在各种边界条件下，流体输送环形加固截顶锥形壳体的振动稳定性（即静态发散）和临界速度。壳体采用桑德斯理论进行表征，而流体则采用速度势能法建模，在流体-壳体界面上采用不渗透条件。利用线性叠加法，通过满足动态特性方程和边界条件，确定了每种流速对应的固有频率。临界速度被确定为固有频率消失的地方，表明静态发散。进行了参数研究，以探讨半锥角、环数和边界条件对临界速度的影响。通过与已公布的数据进行比较，验证了所提出的模型。研究发现，在不同的边界条件下，环形加劲件对锥体的稳定性有很大影响。在所有边界条件下，加劲壳体的不稳定性发生在临界流体速度高于非加劲壳体时。顶角增大会导致临界流体排量减小。

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来源期刊

Finite Elements in Analysis and Design 工程技术-力学

CiteScore

4.80

自引率

3.20%

发文量

审稿时长

27 days

期刊介绍： The aim of this journal is to provide ideas and information involving the use of the finite element method and its variants, both in scientific inquiry and in professional practice. The scope is intentionally broad, encompassing use of the finite element method in engineering as well as the pure and applied sciences. The emphasis of the journal will be the development and use of numerical procedures to solve practical problems, although contributions relating to the mathematical and theoretical foundations and computer implementation of numerical methods are likewise welcomed. Review articles presenting unbiased and comprehensive reviews of state-of-the-art topics will also be accommodated.