Linear Global Stability Analysis of a Laminar Flow Around a Circular Body

2021 12th International Symposium on Advanced Topics in Electrical Engineering (ATEE) Pub Date : 2021-03-25 DOI:10.1109/ATEE52255.2021.9425105

R. Mitruț, D. Bucur, G. Dunca, M. Cervantes

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Abstract

The paper presents the linear global stability analysis of a laminar flow around a circular body at different Reynolds numbers. The results are validated against the literature. The numerical simulations are carried out for both steady state (time independent) and unsteady state (time dependent) flow regimes using the FreeFEM++ software. In the unsteady regime, the flow becomes unsteady when it reached a critical Reynolds number of $\sim 46.5$ and a vortex shedding develops downstream the cylinder. The results of linear global stability analysis for both steady and mean flows are presented. The eigenvalues obtained from the linear stability analysis were compared to the data available in literature. The linear stability analysis of the steady flow correctly predicted the growth rate of the instabilities, but it failed to predict the frequency. The linear stability analysis of the mean flow correctly predicted the frequency of the instabilities, but it underestimated the growth rates. At last, the sensitivity maps of the wavemaker were computed to determine the zone which is more receptive to a modification of the base flow to control the onset of the instability.

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绕圆体层流的线性全局稳定性分析

本文给出了不同雷诺数下绕圆体层流的线性全局稳定性分析。结果与文献相对照。利用FreeFEM++软件对稳态(时间无关)和非定常流态(时间相关)进行了数值模拟。在非定常区，当达到临界雷诺数46.5时，流动变得非定常化，并在筒体下游发生了涡脱落。给出了稳定流和平均流的线性全局稳定性分析结果。将线性稳定性分析得到的特征值与文献资料进行了比较。定常流的线性稳定性分析正确地预测了不稳定性的增长率，但不能预测频率。平均流量的线性稳定性分析正确地预测了不稳定的频率，但低估了增长率。最后，计算了造波器的灵敏度图，以确定更容易接受基流修正以控制不稳定发生的区域。

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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2021 12th International Symposium on Advanced Topics in Electrical Engineering (ATEE)

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