Moderate-Reynolds-number flow in a wall-bounded porous medium

REGHAN J. HILL; DONALD L. KOCH

doi:10.1017/S002211200100684X

Abstract

The transition to unsteady flow and the dynamics of moderate-Reynolds-number flows in unbounded and wall-bounded periodic arrays of aligned cylinders are examined using lattice-Boltzmann simulations. The simulations are compared to experiments, which necessarily have bounding walls. With bounding walls, the transition to unsteady flow is accompanied by a loss of spatial periodicity, and the temporal fluctuations are chaotic at much smaller Reynolds numbers. The walls, therefore, affect the unsteady flows everywhere in the domain. Consistency between experiments and simulations is established by examining the wake lengths for steady flows and the fundamental frequencies at higher Reynolds numbers, both as a function of the Reynolds number. Simulations are used to examine the velocity fluctuations, flow topologies, and the fluctuating forces on the cylinders.

Crossref Citations

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

Schure, Mark R. Maier, Robert S. Kroll, Daniel M. and Ted Davis, H. 2004. Simulation of ordered packed beds in chromatography. Journal of Chromatography A, Vol. 1031, Issue. 1-2, p. 79.

Pereira, J.C.F. Malico, I. Hayashi, T.C. and Raposo, J. 2005. Experimental and numerical characterization of the transverse dispersion at the exit of a short ceramic foam inside a pipe. International Journal of Heat and Mass Transfer, Vol. 48, Issue. 1, p. 1.

Wu, Q. Weinbaum, S. and Andreopoulos, Y. 2005. Stagnation-point flows in a porous medium. Chemical Engineering Science, Vol. 60, Issue. 1, p. 123.

Cappietti, Lorenzo 2006. Lattice Boltzmann Numerical Simulations of Wave-Current Interaction Within the Boundary Layer. p. 1.

Tanino, Yukie and Nepf, Heidi M. 2009. Laboratory investigation of lateral dispersion within dense arrays of randomly distributed cylinders at transitional Reynolds number. Physics of Fluids, Vol. 21, Issue. 4,

Malico, Isabel and Ferreira de Sousa, Paulo J. S. A. 2012. Numerical Analysis of Heat and Mass Transfer in Porous Media. Vol. 27, Issue. , p. 229.

Huang, K. Wan, J.W. Chen, C.X. He, L.Q. Mei, W.B. and Zhang, M.Y. 2013. Experimental investigation on water flow in cubic arrays of spheres. Journal of Hydrology, Vol. 492, Issue. , p. 61.

Wood, B.D. Apte, S.V. Liburdy, J.A. Ziazi, R.M. He, X. Finn, J.R. and Patil, V.A. 2015. A comparison of measured and modeled velocity fields for a laminar flow in a porous medium. Advances in Water Resources, Vol. 85, Issue. , p. 45.

Malico, I. and Ferreira de Sousa, P.J.S.A. 2015. Modelling the Pore Level Heat Transfer in Porous Media Using the Immersed Boundary Method. Diffusion Foundations, Vol. 3, Issue. , p. 63.

2016. Liquid Acquisition Devices for Advanced In-Space Cryogenic Propulsion Systems. p. 421.

2016. Liquid Acquisition Devices for Advanced In-Space Cryogenic Propulsion Systems. p. 403.

NAKAJO, Sota WATANABE, Yuya and SIGEMATSU, Takaaki 2017. ON THE EFFECTS OF ABSENCE OF A MEMBER OF POROUS MEDIA BASED ON MICROSCOPIC FLOW SIMULATION. Journal of Japan Society of Civil Engineers, Ser. B2 (Coastal Engineering), Vol. 73, Issue. 2, p. I_877.

NAKAJO, Sota KODUKA, Izumi TSUJIMOTO, Gozo and SHIGEMATSU, Takaaki 2018. BASIC STUDY ON THE CHARACTERISTICS OF MICROSCOPIC FLOW NEARBY POROUS MEDIA IN WAVE FIELD. Journal of Japan Society of Civil Engineers, Ser. B2 (Coastal Engineering), Vol. 74, Issue. 2, p. I_991.

Wang, Yibiao Ahmadi, Azita and Lasseux, Didier 2019. On the Inertial Single Phase Flow in 2D Model Porous Media: Role of Microscopic Structural Disorder. Transport in Porous Media, Vol. 128, Issue. 1, p. 201.

Lang, Ji Nathan, Rungun and Wu, Qianhong 2019. Theoretical and experimental study of transient squeezing flow in a highly porous film. Tribology International, Vol. 135, Issue. , p. 259.

NAKAJO, Sota KOZUKA, Izumi and SHIGEMATSU, Takaaki 2020. WAVE PERIOD EFFECTS ON A FLOW AND SHEAR VELOCITY AROUND SUBMERSED POROUS MEDIA. Journal of Japan Society of Civil Engineers, Ser. B2 (Coastal Engineering), Vol. 76, Issue. 2, p. I_745.

Chu, Xu Wu, Yongxiang Rist, Ulrich and Weigand, Bernhard 2020. Instability and transition in an elementary porous medium. Physical Review Fluids, Vol. 5, Issue. 4,

Wood, Brian D. He, Xiaoliang and Apte, Sourabh V. 2020. Modeling Turbulent Flows in Porous Media. Annual Review of Fluid Mechanics, Vol. 52, Issue. 1, p. 171.

Vangeffelen, A. Buckinx, G. Vetrano, M. R. and Baelmans, M. 2021. Friction factor for steady periodically developed flow in micro- and mini-channels with arrays of offset strip fins. Physics of Fluids, Vol. 33, Issue. 10,

Lallemand, Pierre Luo, Li-Shi Krafczyk, Manfred and Yong, Wen-An 2021. The lattice Boltzmann method for nearly incompressible flows. Journal of Computational Physics, Vol. 431, Issue. , p. 109713.

Download full list

Article contents

Moderate-Reynolds-number flow in a wall-bounded porous medium

Abstract

Access options

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

Article contents

Moderate-Reynolds-number flow in a wall-bounded porous medium

Abstract

Access options

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests