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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

NUMERICAL ANALYSIS OF THE STRESS JUMP INTERFACE CONDITION FOR LAMINAR FLOW OVER A POROUS LAYER

Renato A. Silva Departamento de Energia--IEME, Instituto Tecnológico de Aeronáutica--ITA, São Paulo, Brazil.
&
Marcelo J. S. de Lemos Departamento de Energia--IEME, Instituto Tecnológico de Aeronáutica--ITA, São Paulo, Brazil.
Pages 603-617 | Published online: 30 Nov 2010

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Lei Fu & Yee-chung Jin. (2018) Macroscopic particle method for channel flow over porous bed. Engineering Applications of Computational Fluid Mechanics 12:1, pages 13-27.
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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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V. A. F. Costa, L. A. Oliveira & B. R. Baliga. (2008) Implementation of the Stress Jump Condition in a Control-Volume Finite-Element Method for the Simulation of Laminar Coupled Flows in Adjacent Open and Porous Domains. Numerical Heat Transfer, Part B: Fundamentals 53:5, pages 383-411.
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X. B. Chen, P. Yu, S. H. Winoto & H. T. Low. (2008) Forced Convection Over a Backward-Facing Step with a Porous Floor Segment. Numerical Heat Transfer, Part A: Applications 53:11, pages 1211-1230.
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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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E. Holzbecher. (2004) FREE CONVECTION IN OPEN-TOP ENCLOSURES FILLED WITH A POROUS MEDIUM HEATED FROM BELOW. Numerical Heat Transfer, Part A: Applications 46:3, pages 241-254.
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Articles from other publishers (46)

Somayeh Davoodabadi Farahani, Mahdi Alibeigi, Amir Zakinia & Marjan Goodarzi. (2021) The effect of microchannel-porous media and nanofluid on temperature and performance of CPV system. Journal of Thermal Analysis and Calorimetry 147:14, pages 7945-7960.
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Qahtan Al-Aabidy, Timothy J. Craft & Hector Iacovides. (2019) Improved Eddy-Viscosity Modelling of Turbulent Flow around Porous–Fluid Interface Regions. Transport in Porous Media 131:2, pages 569-594.
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Chandra Shekhar Nishad, Timir Karmakar, Anirban Chandra & G.P. Raja Sekhar. (2019) A non-primitive boundary integral formulation for modeling flow through composite porous channel. Engineering Analysis with Boundary Elements 109, pages 94-105.
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C.H. Amanulla, S. Saleem, Abderrahim Wakif & M.M. AlQarni. (2019) MHD Prandtl fluid flow past an isothermal permeable sphere with slip effects. Case Studies in Thermal Engineering 14, pages 100447.
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Mac Panah & François Blanchette. (2018) Simulating flow over and through porous media with application to erosion of particulate deposits. Computers & Fluids 166, pages 9-23.
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R. Aganetti, A. Lamorlette & G.R. Thorpe. (2017) The relationship between external and internal flow in a porous body using the penalisation method. International Journal of Heat and Fluid Flow 66, pages 185-196.
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Xianbo Nian, Hai Liu, Yanwei Li, Yong Liu, Chunsheng Guo & Fangyi Qu. (2017) Numerical Simulation of the Fluid Traverses the Porous Media by Single Domain Method Based on UDF. Procedia Engineering 205, pages 3946-3953.
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Donald A. Nield & Adrian BejanDonald A. Nield & Adrian Bejan. 2017. Convection in Porous Media. Convection in Porous Media 1 35 .
Renato A. Silva, Marcelo Assato & Marcelo J.S. de Lemos. (2016) Mathematical modeling and numerical results of power-law fluid flow over a finite porous medium. International Journal of Thermal Sciences 100, pages 126-137.
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Donald A. Nield & Adrian BejanDonald A. Nield & Adrian Bejan. 2013. Convection in Porous Media. Convection in Porous Media 1 29 .
. 2012. Turbulence in Porous Media. Turbulence in Porous Media 353 371 .
Renato A. Silva & Marcelo J.S. de Lemos. (2011) Turbulent flow in a composite channel. International Communications in Heat and Mass Transfer 38:8, pages 1019-1023.
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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 & 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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P. Yu, Y. Zeng, T.S. Lee & H.T. Low. (2009) A numerical analysis of cell density effect on oxygen transport in a micro-bioreactor with a tissue engineering scaffold. International Communications in Heat and Mass Transfer 36:6, pages 569-573.
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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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D. Jamet, M. Chandesris & B. Goyeau. (2008) On the Equivalence of the Discontinuous One- and Two-Domain Approaches for the Modeling of Transport Phenomena at a Fluid/Porous Interface. Transport in Porous Media 78:3, pages 403-418.
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Tomer Duman & Uri Shavit. (2008) An Apparent Interface Location as a Tool to Solve the Porous Interface Flow Problem. Transport in Porous Media 78:3, pages 509-524.
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Huixing Bai, P. Yu, S. H. Winoto & H. T. Low. (2008) Lattice Boltzmann method for flows in porous and homogenous fluid domains coupled at the interface by stress jump. International Journal for Numerical Methods in Fluids 60:6, pages 691-708.
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P. Yu, T. S. Lee, Y. Zeng, S. A. Meguid & H. T. Low. (2008) A numerical technique for laminar swirling flow at the interface between porous and homogenous fluid domains. International Journal for Numerical Methods in Fluids 60:3, pages 337-353.
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X.B. Chen, P. Yu, S.H. Winoto & H.T. Low. (2009) Numerical analysis for the flow past a porous trapezoidal‐cylinder based on the stress‐jump interfacial‐conditions. International Journal of Numerical Methods for Heat & Fluid Flow 19:2, pages 223-241.
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Peng Yu, Thong See Lee, Yan Zeng & Hong Tong Low. (2009) Fluid dynamics and oxygen transport in a micro-bioreactor with a tissue engineering scaffold. International Journal of Heat and Mass Transfer 52:1-2, pages 316-327.
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Edimilson J. Braga & Marcelo J.S. de Lemos. (2008) Computation of turbulent free convection in left and right tilted porous enclosures using a macroscopic k–ε model. International Journal of Heat and Mass Transfer 51:21-22, pages 5279-5287.
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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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Xiaobing Chen, Peng Yu, S.H. Winoto & Hong‐Tong Low. (2008) Numerical analysis for the flow past a porous square cylinder based on the stress‐jump interfacial‐conditions. International Journal of Numerical Methods for Heat & Fluid Flow 18:5, pages 635-655.
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Xiaobing Chen, Peng Yu, S. H. Winoto & Hong‐Tong Low. (2007) A numerical method for forced convection in porous and homogeneous fluid domains coupled at interface by stress jump. International Journal for Numerical Methods in Fluids 56:9, pages 1705-1729.
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Marcelo J.S. de Lemos & Marcelo B. Saito. 2008. Cellular and Porous Materials. Cellular and Porous Materials 1 30 .
H.C. Chan, W.C. Huang, J.M. Leu & C.J. Lai. (2007) Macroscopic modeling of turbulent flow over a porous medium. International Journal of Heat and Fluid Flow 28:5, pages 1157-1166.
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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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P. Yu, T. S. Lee, Y. Zeng & H. T. Low. (2006) A numerical method for flows in porous and homogenous fluid domains coupled at the interface by stress jump. International Journal for Numerical Methods in Fluids 53:11, pages 1755-1775.
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Edimilson J. Braga & Marcelo J. S. de Lemos. (2006) Turbulent Heat Transfer in an Enclosure With a Horizontal Permeable Plate in the Middle. Journal of Heat Transfer 128:11, pages 1122-1129.
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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.
Edimilson J. Braga & Marcelo J.S. de Lemos. (2005) Heat transfer in enclosures having a fixed amount of solid material simulated with heterogeneous and homogeneous models. International Journal of Heat and Mass Transfer 48:23-24, pages 4748-4765.
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Edimilson J. Braga & Marcelo J.S. de Lemos. (2005) Laminar natural convection in cavities filled with circular and square rods. International Communications in Heat and Mass Transfer 32:10, pages 1289-1297.
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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 de Lemos. 2005. Handbook of Porous Media, Second Edition. Handbook of Porous Media, Second Edition 409 454 .
Marcelo J.S. de Lemos. (2005) Turbulent kinetic energy distribution across the interface between a porous medium and a clear region. International Communications in Heat and Mass Transfer 32:1-2, pages 107-115.
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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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