Feedback control of oscillatory thermocapillary convection in a half-zone liquid bridge

J. SHIOMI; M. KUDO; I. UENO; H. KAWAMURA; G. AMBERG

doi:10.1017/S0022112003006323

Abstract

Active feedback control was applied to suppress oscillations in thermocapillary convection in a half-zone liquid bridge. The experiment is on a unit-aspect-ratio liquid bridge where the most unstable azimuthal mode has wavenumber 2 when control is absent. Active control was realized by locally modifying the surface temperature using the local temperature measured at different locations fed back through a simple control law. The performance of the control process was quantified by analysing local temperature signals, and the flow structure was simultaneously identified by flow visualization. With optimal placement of sensors and heaters, proportional control can raise the critical Marangoni number by more than 40%. The amplitude of the oscillation can be suppressed to less than 30% of the initial value for a wide range of Marangoni number, up to 90% of the critical value. The proportional control was tested for a period-doubling state and it stabilized the oscillation to a periodic state. Weakly nonlinear control was applied by adding a cubic term to the control law to improve the performance of the control and alter the bifurcation characteristics.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

2004. Fluids, Materials and Microgravity. p. 485.

Kudo, M. Shiomi, J. Ueno, I. Amberg, G. and Kawamura, H. 2005. Experiment on multimode feedback control of non-linear thermocapillary convection in a half-zone liquid bridge. Advances in Space Research, Vol. 36, Issue. 1, p. 57.

Uemura, Suguru Kudo, Masaki Ueno, Ichiro and Kawamura, Hiroshi 2005. Azimuthal wave number control of oscillatory thermocapillary convection in a liquid bridge. Heat Transfer—Asian Research, Vol. 34, Issue. 7, p. 460.

Shiomi, Junichiro and Amberg, Gustav 2005. Numerical investigation of feedback control of thermocapillary instability. Physics of Fluids, Vol. 17, Issue. 5,

Shiomi, J. and Amberg, G. 2005. Proportional control of oscillatory thermocapillary convection in a toy model. European Journal of Mechanics - B/Fluids, Vol. 24, Issue. 3, p. 296.

Brunet, P. Amberg, G. and Alfredsson, P. H. 2005. Control of thermocapillary instabilities far from threshold. Physics of Fluids, Vol. 17, Issue. 10,

Bárcena, L.T. Shiomi, J. and Amberg, G. 2006. Control of oscillatory thermocapillary convection with local heating. Journal of Crystal Growth, Vol. 286, Issue. 2, p. 502.

Schwabe, D. Mizev, A. I. Udhayasankar, M. and Tanaka, S. 2007. Formation of dynamic particle accumulation structures in oscillatory thermocapillary flow in liquid bridges. Physics of Fluids, Vol. 19, Issue. 7,

van Elsen, Maarten Al‐Bender, Farid and Kruth, Jean‐Pierre 2008. Application of dimensional analysis to selective laser melting. Rapid Prototyping Journal, Vol. 14, Issue. 1, p. 15.

Muldoon, Frank 2013. Control of hydrothermal waves in a thermocapillary flow using a gradient‐based control strategy. International Journal for Numerical Methods in Fluids, Vol. 72, Issue. 1, p. 90.

Muldoon, Frank H. and Kuhlmann, Hendrik C. 2015. Objective function choice for control of a thermocapillary flow using an adjoint-based control strategy. International Journal of Heat and Fluid Flow, Vol. 56, Issue. , p. 28.

Muldoon, F. H. 2018. Numerical Study of Hydrothermal Wave Suppression in Thermocapillary Flow Using a Predictive Control Method. Computational Mathematics and Mathematical Physics, Vol. 58, Issue. 4, p. 493.

Samoilova, Anna E. and Nepomnyashchy, Alexander 2020. Nonlinear feedback control of Marangoni wave patterns in a thin film heated from below. Physica D: Nonlinear Phenomena, Vol. 412, Issue. , p. 132627.

Fukuda, Yuya Ogasawara, Toru Fujimoto, Sorachi Eguchi, Toshikazu Motegi, Kosuke and Ueno, Ichiro 2021. Thermal-flow patterns of m=1 in thermocapillary liquid bridges of high aspect ratio with free-surface heat transfer. International Journal of Heat and Mass Transfer, Vol. 173, Issue. , p. 121196.

Le, Chengcheng Liu, Lijun and Li, Zaoyang 2021. Thermocapillary instabilities in half zone liquid bridges of low Prandtl fluid with non-equal disks under microgravity. Journal of Crystal Growth, Vol. 560-561, Issue. , p. 126063.

Porter, J. Salgado Sánchez, P. Shevtsova, V. Yasnou, V. Samoilova, Anna and Nepomnyashchy, Alexander 2021. A review of fluid instabilities and control strategies with applications in microgravity. Mathematical Modelling of Natural Phenomena, Vol. 16, Issue. , p. 24.

Ueno, Ichiro 2021. Experimental Study on Coherent Structures by Particles Suspended in Half-Zone Thermocapillary Liquid Bridges: Review. Fluids, Vol. 6, Issue. 3, p. 105.

Sakata, Tomoki Terasaki, Sayo Saito, Hiroki Fujimoto, Sorachi Ueno, Ichiro Yano, Taishi Nishino, Koichi Kamotani, Yasuhiro and Matsumoto, Satoshi 2022. Coherent structures of m=1 by low-Stokes-number particles suspended in a half-zone liquid bridge of high aspect ratio: Microgravity and terrestrial experiments. Physical Review Fluids, Vol. 7, Issue. 1,

Terasaki, Sayo Sensui, Shogo and Ueno, Ichiro 2023. Thermocapillary-driven coherent structures by low-Stokes-number particles and their morphology in high-aspect-ratio liquid bridges. International Journal of Heat and Mass Transfer, Vol. 203, Issue. , p. 123772.

DUAN, Wenhao ZHOU, Xiaoming and CHEN, Qisheng 2024. Study on the Active Regulation Mechanism of Laser Photothermal Effect on Thermocapillary Convection of Double-layer Fluid. Chinese Journal of Space Science, Vol. 44, Issue. 2, p. 335.

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Feedback control of oscillatory thermocapillary convection in a half-zone liquid bridge

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Feedback control of oscillatory thermocapillary convection in a half-zone liquid bridge

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