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Stability Analysis of a Film Flow Down an Incline in the Presence of a Floating Flexible Membrane

  • M. Sani
  • H. Behera
  • S. GhoshEmail author
Conference paper
  • 10 Downloads
Part of the Springer Proceedings in Mathematics & Statistics book series (PROMS, volume 308)

Abstract

The present study deals with the effects of floating flexible membrane on the instability of a gravity-driven flow down an incline. Linear stability of the flow system is explored using normal-mode analysis. Free surface gravity-driven flow is unstable at much lower Reynolds numbers. Instability of such a flow can be controlled either by changing behavioral of the lower wall or by altering the surface waves at the free surface which is done here by including a floating flexible membrane at the top of the liquid layer. Influence of membrane tension is taken into account in terms of stress jump at the free surface. The Orr-Sommerfeld system of the flow is solved numerically using spectral collocation method. The results displays a destabilizing role of membrane tension for a wide range of parameters. The growth rate of the perturbation waves increases with an increase of membrane tension and the critical Reynolds number becomes smaller. Therefore, it is possible to enhance the instability of the flow system with help of membrane properties, which may be useful in Ocean engineering and coating industries.

Keywords

Hydrodynamic stability Film flow Floating membrane Orr-Sommerfeld analysis 

Notes

Acknowledgements

HB and SG are thankful to SERB, DST, Government of India (Award No. CRG/2018/004521) for the financial support.

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Copyright information

© Springer Nature Singapore Pte Ltd. 2020

Authors and Affiliations

  1. 1.Department of MathematicsSRM Institute of Science and TechnologyKattankulathurIndia
  2. 2.Department of MathematicsIndian Institute of TechnologyJodhpurIndia

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