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Numerical Heat Transfer, Part A: Applications
An International Journal of Computation and Methodology
Volume 37, 2000 - Issue 7
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Original Articles

MIXED CONVECTION IN CAVITIES WITH A LOCALLY HEATED LOWER WALL AND MOVING SIDEWALLS

Orhan Aydin, Wen-Jei Yang
Pages 695-710 | Published online: 29 Oct 2010

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Lei Wang, Wei-Wei Wang, Yang Cai, Di Liu & Fu-Yun Zhao. (2020) Mixed convection and heat flow characteristics in a lid-driven enclosure with porous fins: Full numerical modeling and parametric investigations. Numerical Heat Transfer, Part A: Applications 77:4, pages 361-390.
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S. Sivasankaran, V. Sivakumar, Ahmed Kadhim Hussein & P. Prakash. (2014) Mixed Convection in a Lid-Driven Two-Dimensional Square Cavity with Corner Heating and Internal Heat Generation. Numerical Heat Transfer, Part A: Applications 65:3, pages 269-286.
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Dipankar Chatterjee, Pabitra Halder, Sinchan Mondal & Supratim Bhattacharjee. (2013) Magnetoconvective Transport in a Vertical Lid-Driven Cavity Including a Heat Conducting Square Cylinder with Joule Heating. Numerical Heat Transfer, Part A: Applications 64:12, pages 1050-1071.
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Dipankar Chatterjee. (2013) MHD Mixed Convection in a Lid-Driven Cavity Including a Heated Source. Numerical Heat Transfer, Part A: Applications 64:3, pages 235-254.
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M.M. Rahman, N.A. Rahim, S. Saha, M.M. Billah, R. Saidur & A. Ahsan. (2011) Optimization of Mixed Convection in a Lid-Driven Enclosure with a Heat Generating Circular Body. Numerical Heat Transfer, Part A: Applications 60:7, pages 629-650.
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Md. Mustafizur Rahman, Mohammad Arif Hasan Mamun & Rahman Saidur. (2011) Analysis of magnetohydrodynamic mixed convection and joule heating in lid-driven cavity having a square block. Journal of the Chinese Institute of Engineers 34:5, pages 585-599.
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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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B. Ghasemi & S. M. Aminossadati. (2008) Comparison of Mixed Convection in a Square Cavity with an Oscillating versus a Constant Velocity Wall. Numerical Heat Transfer, Part A: Applications 54:7, pages 726-743.
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Tzer-Ming Jeng & Sheng-Chung Tzeng. (2008) Heat Transfer in a Lid-Driven Enclosure Filled with Water-Saturated Aluminum Foams. Numerical Heat Transfer, Part A: Applications 54:2, pages 178-196.
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Semiha Öztuna. (2007) A Differential Quadrature Solution of Natural Convection in an Enclosure with a Partial Partition. Numerical Heat Transfer, Part A: Applications 52:11, pages 1009-1026.
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Kamil Kahveci. (2007) A Differential Quadrature Solution of Natural Convection in an Enclosure with a Finite-Thickness Partition. Numerical Heat Transfer, Part A: Applications 51:10, pages 979-1002.
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Yanjun Chen, Chenhao Du, Zhoumiao Wang & Deqiang He. (2024) Mixed Convective Heat Transfer Characteristics of Graphene Nanofluid Strengthened by Periodically Direction-Switching Electric Field. Journal of Thermal Science and Engineering Applications 16:1.
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A. Satheesh, Shivananda Moolya, Salim Al Jadidi, P. Rajesh Kanna, Dawid Taler, Tomasz Sobota & Jan Taler. (2023) Optimization of the effect of sinusoidal phase shift heating on mixed convective in an enclosure: LBM approach. Case Studies in Thermal Engineering, pages 103625.
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Rowsanara Akhter, Mohammad Mokaddes Ali & Md Abdul Alim. (2023) Magnetic field impact on double diffusive mixed convective hybrid-nanofluid flow and irreversibility in porous cavity with vertical wavy walls and rotating solid cylinder. Results in Engineering 19, pages 101292.
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Md. Yousuf Ali, M. A. Alim & Md. Mashud Karim. (2023) Mixed Convective Heat Transfer Analysis by Heatlines on a Lid-Driven Cavity Having Heated Wavy Wall Containing Tilted Square Obstacle. Mathematical Problems in Engineering 2023, pages 1-17.
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Zakir Hussain, Metib Alghamdi, Fozia, Shahbaz Ali, Mohamed R. Ali & Muhammad Aslam. (2023) Significance of mixed convective heat transfer model in an equilateral triangular enclosure subjected to cylindrical heated objects inside. Case Studies in Thermal Engineering 47, pages 103027.
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Bishnu Ram Das, Paramananda Deka & Shiva Rao. (2023) Numerical Analysis on MHD mixed convection flow of Al_2O_3/H_2O (Aluminum-Water) Nanofluids in a Vertical Square Duct. East European Journal of Physics:2, pages 51-62.
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Basanta Kumar Rana. (2023) Mixed Convection Heat Transfer From Swirling Open Spherical Cavity. ASME Journal of Heat and Mass Transfer 145:6.
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Periklis Mountrichas, Wendi Zhao, Mehtab Singh Randeva & Prodip K. Das. (2023) Entropy Generation of CuO-Water Nanofluid in a Cavity with an Intruded Rectangular Fin. Energies 16:2, pages 912.
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Md. Shahneoug Shuvo, Mahmudul Hasan Hasib & Sumon Saha. (2022) Entropy generation and characteristics of mixed convection in lid-driven trapezoidal tilted enclosure filled with nanofluid. Heliyon 8:12, pages e12079.
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Z. H. Khan, W. A. Khan, M. Qasim, S. O. Alharbi, M. Hamid & M. Du. (2022) Hybrid nanofluid flow around a triangular-shaped obstacle inside a split lid-driven trapezoidal cavity. The European Physical Journal Special Topics 231:13-14, pages 2749-2759.
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Swapan K. Pandit & Samrat Hansda. (2022) On the Analysis of Thermosolutal Mixed Convection with Soret and Dufour Effects in a Two-Sided Lid-Driven Deep Cavity. International Journal of Applied and Computational Mathematics 8:1.
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Sofiane Boulkroune, Omar Kholai & Brahim Mahfoud. (2021) Effects of Important Parameters on the Transition from Forced to Mixed Convection Flow in a Square Cavity. Defect and Diffusion Forum 406, pages 36-52.
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Ece Aylı. (2020) Modeling of mixed convection in an enclosure using multiple regression, artificial neural network, and adaptive neuro-fuzzy interface system models. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science 234:15, pages 3078-3093.
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Lei Wang, Wei-Wei Wang, Yang Cai, Di Liu & Fu-Yun Zhao. (2020) Effects of Porous Fins on Mixed Convection and Heat Transfer Mechanics in Lid-Driven Cavities: Full Numerical Modeling and Parametric Simulations. Transport in Porous Media 132:3, pages 495-534.
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Sicelo P. Goqo, Hiranmoy Mondal, Precious Sibanda & Sandile S. Motsa. (2019) A multivariate spectral quasilinearisation method for entropy generation in a square cavity filled with porous medium saturated by nanofluid. Case Studies in Thermal Engineering 14, pages 100415.
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Hari Ponnamma Rani, Vekamulla Narayana & Yadagiri Rameshwar. (2019) Mixed convective flow in a bottom heated lid-driven cubical cavity: Energy streamlines and field synergy. Heat Transfer-Asian Research 48:6, pages 2067-2081.
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A. Evgrafova & A. Sukhanovskii. (2019) Specifics of heat flux from localized heater in a cylindrical layer. International Journal of Heat and Mass Transfer 135, pages 761-768.
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Mehmet Saglam, Bugra Sarper & Orhan Aydin. (2019) Natural Convection in an Enclosure with a Pair of Discrete Heat Sources. Journal of Thermophysics and Heat Transfer 33:1, pages 234-245.
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H. P. Rani, V. Narayana & Y. Rameshwar. 2019. Numerical Heat Transfer and Fluid Flow. Numerical Heat Transfer and Fluid Flow 597 602 .
Ali Khaleel Kareem & Shian Gao. (2017) Computational study of unsteady mixed convection heat transfer of nanofluids in a 3D closed lid-driven cavity. International Communications in Heat and Mass Transfer 82, pages 125-138.
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Nirmalendu Biswas & Nirmal K Manna. (2017) Transport phenomena in a sidewall-moving bottom-heated cavity using heatlines. Sādhanā 42:2, pages 193-211.
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N. A. Bakar, A. Karimipour & R. Roslan. Numerical study of mixed convection in a lid-driven cavity in the presence of internal heat generation/absorption. Numerical study of mixed convection in a lid-driven cavity in the presence of internal heat generation/absorption.
Ali Khaleel Kareem, H.A. Mohammed, Ahmed Kadhim Hussein & Shian Gao. (2016) Numerical investigation of mixed convection heat transfer of nanofluids in a lid-driven trapezoidal cavity. International Communications in Heat and Mass Transfer 77, pages 195-205.
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Przemysław Błasiak & Piotr Kolasiński. (2015) Modelling of the mixed convection in a lid-driven cavity with a constant heat flux boundary condition. Heat and Mass Transfer 52:3, pages 595-609.
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Satyajit Mojumder, Sourav Saha, Sumon Saha & M. A. H. Mamun. (2015) Combined effect of Reynolds and Grashof numbers on mixed convection in a lid-driven T-shaped cavity filled with water-Al2O3 nanofluid. Journal of Hydrodynamics 27:5, pages 782-794.
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Monisha Roy, S. Roy & Tanmay Basak. (2015) Role of various moving walls on energy transfer rates via heat flow visualization during mixed convection in square cavities. Energy 82, pages 1-22.
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Madhuchhanda Bhattacharya, Tanmay Basak, Hakan F. Oztop & Yasin Varol. (2013) Mixed convection and role of multiple solutions in lid-driven trapezoidal enclosures. International Journal of Heat and Mass Transfer 63, pages 366-388.
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Ali J. Chamkha & Eiyad Abu-Nada. (2012) Mixed convection flow in single- and double-lid driven square cavities filled with water–Al2O3 nanofluid: Effect of viscosity models. European Journal of Mechanics - B/Fluids 36, pages 82-96.
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M.M. Billah, M.M. Rahman, Uddin M. Sharif, N.A. Rahim, R. Saidur & M. Hasanuzzaman. (2011) Numerical analysis of fluid flow due to mixed convection in a lid-driven cavity having a heated circular hollow cylinder. International Communications in Heat and Mass Transfer 38:8, pages 1093-1103.
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Sumon Saha, Goutam Saha, Md. Quamrul Islam & M. C. Raju. (2010) Mixed Convection Inside a Lid-Driven Parallelogram Enclosure with ISOflux Heating from Below. i-manager's Journal on Future Engineering and Technology 6:1, pages 14-22.
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M.M. Rahman, M.A. Alim & M.M.A. Sarker. (2010) Numerical study on the conjugate effect of joule heating and magnato-hydrodynamics mixed convection in an obstructed lid-driven square cavity. International Communications in Heat and Mass Transfer 37:5, pages 524-534.
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Ghanbar Ali Sheikhzadeh, S.H. Musavi & N. Sadoughi. (2010) Effect of a Shield on Mixed Convection in a Rectangular Enclosure with Moving Cold Sidewalls and a Heat Source on the Bottom Wall. Defect and Diffusion Forum 297-301, pages 584-589.
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E.M. Wahba & M.A. Gadalla. (2009) Heat and fluid flow characteristics inside differentially heated square enclosures with single and multiple sliding walls. Heat Transfer—Asian Research 38:7, pages 422-434.
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M.A. Waheed. (2009) Mixed convective heat transfer in rectangular enclosures driven by a continuously moving horizontal plate. International Journal of Heat and Mass Transfer 52:21-22, pages 5055-5063.
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Nasreddine Ouertatani, Nader Ben Cheikh, Brahim Ben Beya, Taieb Lili & Antonio Campo. (2009) Mixed convection in a double lid-driven cubic cavity. International Journal of Thermal Sciences 48:7, pages 1265-1272.
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M.R.H. Nobari & A. Beshkani. (2007) A numerical study of mixed convection in a vertical channel flow impinging on a horizontal surface. International Journal of Thermal Sciences 46:10, pages 989-997.
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Abdalla M. Al-Amiri, Khalil M. Khanafer & Ioan Pop. (2007) Numerical simulation of combined thermal and mass transport in a square lid-driven cavity. International Journal of Thermal Sciences 46:7, pages 662-671.
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Guanghong Guo & Muhammad A.R. Sharif. (2004) Mixed convection in rectangular cavities at various aspect ratios with moving isothermal sidewalls and constant flux heat source on the bottom wall. International Journal of Thermal Sciences 43:5, pages 465-475.
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R.J. Goldstein, E.R.G. Eckert, W.E. Ibele, S.V. Patankar, 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.A. Kulacki, U. Kortshagen & S. Garrick. (2002) Heat transfer – a review of 2000 literature. International Journal of Heat and Mass Transfer 45:14, pages 2853-2957.
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