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Numerical Heat Transfer, Part A: Applications
An International Journal of Computation and Methodology
Volume 43, 2003 - Issue 6
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Original Articles

COMPUTATION OF TURBULENT FLOW IN POROUS MEDIA USING A LOW-REYNOLDS K -ε MODELAND AN INFINITE ARRAY OF TRANSVERSALLY DISPLACED ELLIPTIC RODS

Marcos H. J. Pedras Instituto de Pesquisa e Desenvolvimento IP&D, UNIVAP, São Paulo, Brazil
&
Marcelo J. S. de Lemos Departamento de Energia--IEME, Instituto Tecnológico de Aeronáutica--ITA, São Paulo, Brazil
Pages 585-602 | Published online: 30 Nov 2010

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Latifa Begum & Mainul Hasan. (2015) A Numerical Study of 3D Turbulent Melt Flow and Solidification in a Direct Chill Slab Caster with a Porous Combo Bag Melt Distributor. Numerical Heat Transfer, Part A: Applications 67:7, pages 746-770.
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Tien-Mo Shih, Chandrasekhar Thamire, Chao-Ho Sung & An-Lu Ren. (2010) Literature Survey of Numerical Heat Transfer (2000–2009): Part I. Numerical Heat Transfer, Part A: Applications 57:3-4, pages 159-296.
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MarceloJ. S. de Lemos & Cleges Fischer. (2008) Thermal Analysis of an Impinging Jet on a Plate With and Without a Porous Layer. Numerical Heat Transfer, Part A: Applications 54:11, pages 1022-1041.
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DanielR. Graminho & MarceloJ. S. de Lemos. (2008) Laminar Confined Impinging Jet into a Porous Layer. Numerical Heat Transfer, Part A: Applications 54:2, pages 151-177.
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NicolauB. Santos & MarceloJ. S. de Lemos. (2006) Flow and Heat Transfer in a Parallel-Plate Channel with Porous and Solid Baffles. Numerical Heat Transfer, Part A: Applications 49:5, pages 471-494.
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Articles from other publishers (60)

Vishal Srikanth, Dylan Peverall & Andrey V. Kuznetsov. (2023) Flow Regimes and Types of Solid Obstacle Surface Roughness in Turbulent Heat Transfer Inside Periodic Porous Media. Transport in Porous Media 149:3, pages 687-708.
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Ching-Wei Huang, Vishal Srikanth & Andrey V. Kuznetsov. (2022) The evolution of turbulent micro-vortices and their effect on convection heat transfer in porous media. Journal of Fluid Mechanics 942.
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Rodrigo Y.I. Tobisawa & Marcelo J.S. de Lemos. (2022) Filtration efficiency of particle-laden flows for thermal plug and abandonment of oil wells using turbulence modeling in porous media. International Communications in Heat and Mass Transfer 135, pages 106108.
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Maksim N. Vlasov & Igor G. Merinov. (2022) Application of an Integral Turbulence Model to Close the Model of an Anisotropic Porous Body as Applied to Rod Structures. Fluids 7:2, pages 77.
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Vishal Srikanth, Ching-Wei Huang, Timothy S. Su & Andrey V. Kuznetsov. (2021) Symmetry breaking of turbulent flow in porous media composed of periodically arranged solid obstacles. Journal of Fluid Mechanics 929.
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Liliana de Luca Xavier Augusto, Paolo Tronville, José A. S. Gonçalves & Gabriela C. Lopes. (2021) A simple numerical method to simulate the flow through filter media: Investigation of different fibre allocation algorithms. The Canadian Journal of Chemical Engineering 99:12, pages 2760-2770.
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Takehito Suzuki. (2021) Characteristic Sensitivity of Turbulent Flow within a Porous Medium under Initial Conditions. Journal of the Physical Society of Japan 90:2, pages 024401.
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Fernando A. Rodrigues & Marcelo J.S. de Lemos. (2020) Transient performance of a thermocline energy storage system using the two-energy equation model. International Journal of Heat and Mass Transfer 150, pages 119323.
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Djamal DARFİLAL. (2020) SOLAR HYDROGEN PRODUCTION BY THERMOCHEMICAL REACTION: DEVELOPMENT OF A PACKED-BED REACTOR. Journal of Thermal Engineering 6:2, pages 152-169.
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Brian D. WoodXiaoliang He & Sourabh V. Apte. (2020) Modeling Turbulent Flows in Porous Media. Annual Review of Fluid Mechanics 52:1, pages 171-203.
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Jaime Daniel Bustos-Vanegas, Sabrina Hempel, David Janke, Moustapha Doumbia, Judith Streng & Thomas Amon. (2019) Numerical simulation of airflow in animal occupied zones in a dairy cattle building. Biosystems Engineering 186, pages 100-105.
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Mehrdad Torabi, Mohsen Torabi, Mohammad Eftekhari Yazdi & G.P. Peterson. (2019) Fluid flow, heat transfer and entropy generation analyses of turbulent forced convection through isotropic porous media using RANS models. International Journal of Heat and Mass Transfer 132, pages 443-461.
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Marcus Vinicius de Assis Silva, Márcio Aredes Martins, Leda Rita D'Antonino Faroni, Jaime Daniel Bustos Vanegas & Adalberto Hipólito de Sousa. (2019) CFD modelling of diffusive-reactive transport of ozone gas in rice grains. Biosystems Engineering 179, pages 49-58.
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Jaime Daniel Bustos-Vanegas, Marcio Arêdes Martins, Angélica de Cassia Oliveira Carneiro, Arthur Gomes Freitas & Ruben Christian Barbosa. (2018) Thermal inertia effects of the structural elements in heat losses during the charcoal production in brick kilns. Fuel 226, pages 508-515.
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Y. Jin & A. V. Kuznetsov. (2017) Turbulence modeling for flows in wall bounded porous media: An analysis based on direct numerical simulations. Physics of Fluids 29:4.
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Donald A. Nield & Adrian BejanDonald A. Nield & Adrian Bejan. 2017. Convection in Porous Media. Convection in Porous Media 1 35 .
Latifa Begum & Mainul Hasan. (2016) 3-D prediction of alloy solidification in the presence of turbulent fow in a vertical direct chill caster with a porous filter near the top. Applied Mathematical Modelling 40:21-22, pages 9029-9051.
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E. V. Usov, M. E. Kuznetsova, N. A. Pribaturin, R. V. Chalyi, N. I. Ryzhov & A. E. Kiselev. (2016) Two-Dimensional Thermohydraulic Module of the Integrated Code Sokrat-BN: Mathematical Model and Computational Results. Atomic Energy 120:2, pages 119-126.
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M. N. Vlasov, A. S. Korsun, Yu. A. Maslov, I. G. Merinov, V. I. Rachkov & V. S. Kharitonov. (2016) Determination of integral turbulence model parameters as applied to calculation of rod-bundle flows in porous-body approximation. Thermophysics and Aeromechanics 23:2, pages 201-209.
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Marcelo J.S. de LemosMarcelo J. S. de Lemos. 2016. Thermal Non-Equilibrium in Heterogeneous Media. Thermal Non-Equilibrium in Heterogeneous Media 69 88 .
Marcelo J.S. de LemosMarcelo J. S. de Lemos. 2016. Thermal Non-Equilibrium in Heterogeneous Media. Thermal Non-Equilibrium in Heterogeneous Media 9 41 .
Mainul Hasan & Latifa Begum. (2015) Semi-continuous casting of magnesium alloy AZ91 using a filtered melt delivery system. Journal of Magnesium and Alloys 3:4, pages 283-301.
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Y. Jin, M.-F. Uth, A. V. Kuznetsov & H. Herwig. (2015) Numerical investigation of the possibility of macroscopic turbulence in porous media: a direct numerical simulation study. Journal of Fluid Mechanics 766, pages 76-103.
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Latifa Begum & Mainul Hasan. (2014) Modeling of 3-D turbulent transport phenomena and solidification of a direct chill caster fitted with a metallic-foam-plated combo bag. International Journal of Thermal Sciences 86, pages 68-87.
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Latifa Begum & Mainul Hasan. (2014) Three-Dimensional Modeling of Direct Chill Caster with Partial Porous Plate. Journal of Thermophysics and Heat Transfer 28:4, pages 735-749.
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Latifa Begum & Mainul Hasan. (2014) 3-D CFD simulation of a vertical direct chill slab caster with a submerged nozzle and a porous filter delivery system. International Journal of Heat and Mass Transfer 73, pages 42-58.
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J. Yang, M. Zhou, S. Y. Li, S. S. Bu & Q. W. Wang. (2014) Three-Dimensional Numerical Analysis of Turbulent Flow in Porous Media Formed by Periodic Arrays of Cubic, Spherical, or Ellipsoidal Particles. Journal of Fluids Engineering 136:1.
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Amir Montakhab, Badronnisa bt.Yusuf, Abdul Halim Ghazali & Thamer Ahmed Mohamed. (2013) Estimation of vegetation porosity in vegetated waterways. Proceedings of the Institution of Civil Engineers - Water Management 166:6, pages 333-340.
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. 2012. Turbulence in Porous Media. Turbulence in Porous Media 353 371 .
Federico E. Teruel & Rizwan-uddin. (2010) Numerical computation of macroscopic turbulence quantities in representative elementary volumes of the porous medium. International Journal of Heat and Mass Transfer 53:23-24, pages 5190-5198.
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Marcelo B. Saito & Marcelo J.S. de Lemos. (2010) A macroscopic two-energy equation model for turbulent flow and heat transfer in highly porous media. International Journal of Heat and Mass Transfer 53:11-12, pages 2424-2433.
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Marcelo J.S. de Lemos & Maximilian S. Mesquita. (2010) Comparison of Four Thermo-Mechanical Models for Simulating Reactive Flow in Porous Materials. Defect and Diffusion Forum 297-301, pages 1493-1501.
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Marcelo J.S. de Lemos. (2010) Analysis of turbulent combustion in inert porous media. International Communications in Heat and Mass Transfer 37:4, pages 331-336.
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Marcelo J. S. de Lemos. 2011. Heat Transfer in Multi-Phase Materials. Heat Transfer in Multi-Phase Materials 443 460 .
Federico E. Teruel & Rizwan-uddin. (2009) Characterization of a porous medium employing numerical tools: Permeability and pressure-drop from Darcy to turbulence. International Journal of Heat and Mass Transfer 52:25-26, pages 5878-5888.
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Marcelo J.S. de Lemos. (2009) Numerical simulation of turbulent combustion in porous materials. International Communications in Heat and Mass Transfer 36:10, pages 996-1001.
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Luzia A. Tofaneli & Marcelo J.S. de Lemos. (2009) Double-diffusive turbulent natural convection in a porous square cavity with opposing temperature and concentration gradients. International Communications in Heat and Mass Transfer 36:10, pages 991-995.
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Marcelo J. S. de Lemos & Marcelo B. Saito. (2009) Heat‐Transfer Coefficient for Cellular Materials Modelled as an Array of Elliptic Rods. Advanced Engineering Materials 11:10, pages 837-842.
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Krithiga Ganesan, Terry Simon & Josh Quinnell. (2009) Flow Through Stirling Engine Regenerators With and Without a Gap Between the Matrix and Container Wall - Part 1: Computation. Flow Through Stirling Engine Regenerators With and Without a Gap Between the Matrix and Container Wall - Part 1: Computation.
Marcelo J. S. De Lemos. (2009) Turbulent Flow Around Fluid–Porous Interfaces Computed with a Diffusion-Jump Model for k and ε Transport Equations. Transport in Porous Media 78:3, pages 331-346.
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Daniel R. Graminho & Marcelo J.S. de Lemos. (2009) Simulation of turbulent impinging jet into a cylindrical chamber with and without a porous layer at the bottom. International Journal of Heat and Mass Transfer 52:3-4, pages 680-693.
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Edimilson J. Braga & Marcelo J.S. de Lemos. (2009) Laminar and turbulent free convection in a composite enclosure. International Journal of Heat and Mass Transfer 52:3-4, pages 588-596.
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Marcos H.J. Pedras & Marcelo J.S. de Lemos. (2008) Thermal dispersion in porous media as a function of the solid–fluid conductivity ratio. International Journal of Heat and Mass Transfer 51:21-22, pages 5359-5367.
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Marcelo J. S. De Lemos. (2008) Analysis of turbulent flows in fixed and moving permeable media. Acta Geophysica 56:3, pages 562-583.
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Marcelo J.S. de Lemos & Marcelo B. Saito. 2008. Cellular and Porous Materials. Cellular and Porous Materials 1 30 .
Brian D. Wood. (2007) Inertial effects in dispersion in porous media. Water Resources Research 43:12.
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H. C. ChanJ. M. LeuC. J. LaiYafei Jia. (2007) Turbulent Flow over a Channel with Fluid-Saturated Porous Bed. Journal of Hydraulic Engineering 133:6, pages 610-617.
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Edimilson J. Braga & Marcelo J.S. de Lemos. (2006) Simulation of turbulent natural convection in a porous cylindrical annulus using a macroscopic two-equation model. International Journal of Heat and Mass Transfer 49:23-24, pages 4340-4351.
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Marcelo B. Saito & Marcelo J. S. de Lemos. (2006) A Correlation for Interfacial Heat Transfer Coefficient for Turbulent Flow Over an Array of Square Rods. Journal of Heat Transfer 128:5, pages 444-452.
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R.J. Goldstein, W.E. Ibele, S.V. Patankar, T.W. Simon, T.H. Kuehn, P.J. Strykowski, K.K. Tamma, J.V.R. Heberlein, J.H. Davidson, J. Bischof, F.A. Kulacki, U. Kortshagen, S. Garrick & V. Srinivasan. (2006) Heat transfer—A review of 2003 literature. International Journal of Heat and Mass Transfer 49:3-4, pages 451-534.
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Marcelo J.S. de Lemos & Renato A. Silva. (2006) Turbulent flow over a layer of a highly permeable medium simulated with a diffusion-jump model for the interface. International Journal of Heat and Mass Transfer 49:3-4, pages 546-556.
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. 2006. Turbulence in Porous Media. Turbulence in Porous Media 313 328 .
Marcelo J. S. de Lemos & Nicolau B. Santos. (2005) Turbulent Heat Transfer in Channels With Solid and Porous Baffles. Turbulent Heat Transfer in Channels With Solid and Porous Baffles.
M. J. S. De Lemos. (2005) Fundamentals of the double - decomposition concept for turbulent transport in permeable media. Materialwissenschaft und Werkstofftechnik 36:10, pages 586-593.
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Marcelo B. Saito & Marcelo J.S. de Lemos. (2005) Interfacial heat transfer coefficient for non-equilibrium convective transport in porous media. International Communications in Heat and Mass Transfer 32:5, pages 666-676.
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Marcelo de Lemos. 2005. Handbook of Porous Media, Second Edition. Handbook of Porous Media, Second Edition 409 454 .
M.J.S. DE LEMOS. 2005. Transport Phenomena in Porous Media III. Transport Phenomena in Porous Media III 1 33 .
Edimilson J. Braga & Marcelo J.S. de Lemos. (2004) Turbulent natural convection in a porous square cavity computed with a macroscopic κ–ε model. International Journal of Heat and Mass Transfer 47:26, pages 5639-5650.
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Marcelo J.S. de Lemos & Luzia A. Tofaneli. (2004) Modeling of double-diffusive turbulent natural convection in porous media. International Journal of Heat and Mass Transfer 47:19-20, pages 4233-4241.
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Renato A. Silva & Marcelo J.S. de Lemos. (2003) Turbulent flow in a channel occupied by a porous layer considering the stress jump at the interface. International Journal of Heat and Mass Transfer 46:26, pages 5113-5121.
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