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Numerical Heat Transfer, Part A: Applications
An International Journal of Computation and Methodology
Volume 29, 1996 - Issue 2
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Original Articles

HIGHER ORDER PENALTY-GALERKIN FINITE ELEMENT APPROACH TO LAMINAR NATURAL CONVECTION IN A SQUARE CAVITY

Seppo Syrjälä Energy and Process Engineering, Tampere University of Technology, Tampere, 33101, Finland
Pages 197-210 | Received 12 Jun 1995, Accepted 26 Sep 1995, Published online: 23 Oct 2007

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M. Adekojo Waheed. (2009) Heatfunction Formulation of Thermal Convection in Rectangular Enclosures Filled with Porous Media. Numerical Heat Transfer, Part A: Applications 55:2, pages 185-204.
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Farhad Shahraki. (2002) MODELING OF BUOYANCY-DRIVEN FLOW AND HEAT TRANSFER FOR AIR IN A HORIZONTAL ANNULUS: EFFECTS OF VERTICAL ECCENTRICITY AND TEMPERATURE-DEPENDENT PROPERTIES. Numerical Heat Transfer, Part A: Applications 42:6, pages 603-621.
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Gang Wang. (2002) An Efficient Equal-Order Finite-Element Method for Natural Convection in Complex Enclosures. Numerical Heat Transfer, Part B: Fundamentals 42:4, pages 307-324.
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Paulo J. Oliveira, Raad I. Issa. (2001) AN IMPROVED PISO ALGORITHM FOR THE COMPUTATION OF BUOYANCY-DRIVEN FLOWS. Numerical Heat Transfer, Part B: Fundamentals 40:6, pages 473-493.
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C. Nonino & G. Croce. (1997) AN EQUAL-ORDER VELOCITY-PRESSURE ALGORITHM FOR INCOMPRESSIBLE THERMAL FLOWS, PART 2: VALIDATION. Numerical Heat Transfer, Part B: Fundamentals 32:1, pages 17-35.
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Articles from other publishers (14)

Banghua Zhao, Yuanye Zhou, Chen Ding & Sujun Dong. (2023) A fast natural convection algorithm based on dividing fluid development stages. Physics of Fluids 35:11.
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Nagesh Babu Balam, Tabish Alam, Akhilesh Gupta & Paolo Blecich. (2021) Higher Order Accurate Transient Numerical Model to Evaluate the Natural Convection Heat Transfer in Flat Plate Solar Collector. Processes 9:9, pages 1508.
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Aditya Dewanto Hartono, Kyuro Sasaki, Yuichi Sugai & Ronald Nguele. (2021) Computational Performance of Disparate Lattice Boltzmann Scenarios under Unsteady Thermal Convection Flow and Heat Transfer Simulation. Computation 9:6, pages 65.
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Nagesh Babu Balam & Akhilesh Gupta. (2019) A fourth-order accurate finite difference method to evaluate the true transient behaviour of natural convection flow in enclosures. International Journal of Numerical Methods for Heat & Fluid Flow 30:3, pages 1233-1290.
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Bingxin Zhao & Zhenfu Tian. (2016) High-resolution high-order upwind compact scheme-based numerical computation of natural convection flows in a square cavity. International Journal of Heat and Mass Transfer 98, pages 313-328.
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Kerim Yapici & Salih Obut. (2015) Benchmark results for natural and mixed convection heat transfer in a cavity. International Journal of Numerical Methods for Heat & Fluid Flow 25:5, pages 998-1029.
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Pei Xiang Yu & Zhen F. Tian. (2012) Compact computations based on a stream-function–velocity formulation of two-dimensional steady laminar natural convection in a square cavity. Physical Review E 85:3.
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A. Barletta & D.A. Nield. (2009) Mixed convection with viscous dissipation and pressure work in a lid-driven square enclosure. International Journal of Heat and Mass Transfer 52:19-20, pages 4244-4253.
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Yue-Tzu Yang & Cheng-Hua Chen. (2008) Numerical simulation of turbulent fluid flow and heat transfer characteristics of heated blocks in the channel with an oscillating cylinder. International Journal of Heat and Mass Transfer 51:7-8, pages 1603-1612.
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Zhenfu Tian & Yongbin Ge. (2003) A fourth‐order compact finite difference scheme for the steady stream function–vorticity formulation of the Navier–Stokes/Boussinesq equations. International Journal for Numerical Methods in Fluids 41:5, pages 495-518.
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E.R.G. Eckert, R.J. Goldstein, W.E. Ibele, T.W. Simon, T.H. Kuehn, P.J. Strykowski, K.K. Tamma, A. Bar-Cohen, J.V.R. Heberlein, J.H. Davidson, J. Bischof, F. Kulacki & U. Kortshagen. (2000) Heat transfer — a review of 1996 literature. International Journal of Heat and Mass Transfer 43:8, pages 1273-1371.
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Seppo Syrjälä. (1998) Laminar flow of viscoelastic fluids in rectangular ducts with heat transfer: A finite element analysis. International Communications in Heat and Mass Transfer 25:2, pages 191-204.
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Seppo Syrjälä. (1997) Numerical study of fully developed non-newtonian fluid flow and heat transfer in a rectangular channel with a moving wall. International Communications in Heat and Mass Transfer 24:1, pages 11-25.
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Seppo Syrjälä. (1996) Further finite element analyses of fully developed laminar flow of power-law non-Newtonian fluid in rectangular ducts: Heat transfer predictions. International Communications in Heat and Mass Transfer 23:6, pages 799-807.
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