Citations (22)
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MD Mumtaz A. Ansari, Kunja B. Sahu, Sumanta Chaudhuri, Jujjuvarapu Srikanth, Debjyoti Sahu & Vijay K. Mishra. (2023) Hybrid genetic algorithm-self organizing map network for decision support system: An application in combined mode conduction-radiation heat transfer in porous medium. Numerical Heat Transfer, Part B: Fundamentals 84:5, pages 642-664.
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Premananda Pradhan, Purna Chandra Mishra & Bibhuti Bhusan Samantaray. (2018) Performance and Emission Analysis of a Novel Porous Radiant Burner for Domestic Cooking Application. Heat Transfer Engineering 39:9, pages 784-793.
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Vijay K. Mishra, Subhash C. Mishra & Dipankar N. Basu. (2017) Simultaneous estimation of four parameters in a combined-mode heat transfer in a 2D porous matrix with heat generation. Numerical Heat Transfer, Part A: Applications 71:6, pages 677-692.
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Vijay K. Mishra, Subhash C. Mishra & Dipankar N. Basu. (2017) Simultaneous estimation of parameters in analyzing porous medium combustion—assessment of seven optimization tools. Numerical Heat Transfer, Part A: Applications 71:6, pages 666-676.
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Subhash C. Mishra, Snehasish Panigrahy & Viswajit J. Ghatage. (2016) Analysis of combined mode heat transfer in a porous medium using the lattice Boltzmann method. Numerical Heat Transfer, Part A: Applications 69:10, pages 1092-1105.
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Dianxin Li, Pingfa Feng, Jianfu Zhang, Zhijun Wu & Dingwen Yu. (2016) Method for modifying convective heat transfer coefficients used in the thermal simulation of a feed drive system based on the response surface methodology. Numerical Heat Transfer, Part A: Applications 69:1, pages 51-66.
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VijayK. Mishra, SubhashC. Mishra & DipankarN. Basu. (2015) Combined Mode Conduction and Radiation Heat Transfer in a Porous Medium and Estimation of the Optical Properties of the Porous Matrix. Numerical Heat Transfer, Part A: Applications 67:10, pages 1119-1135.
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Tien-Mo Shih, Yingbin Zheng, Martinus Arie & Jin-Cheng Zheng. (2013) Literature Survey of Numerical Heat Transfer (2010–2011). Numerical Heat Transfer, Part A: Applications 64:6, pages 435-525.
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Articles from other publishers (14)
Swagatika Acharya, Vijay K. Mishra, Sumanta Chaudhuri, Jitendra Kumar Patel, Prakash Ghose & Vishesh Ranjan Kar. (2023) Decision Support System for Porous Ceramic Matrix-based Burner by Hybrid Genetic Algorithm-Supervised Kohonen Map: A Comparative Assessment of Performance of Neural Network Under Different Minor Attributes. Arabian Journal for Science and Engineering.
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Hakan Ertürk, Kyle Daun, Francis H. R. França, Shima Hajimirza & John R. Howell. (2023) Inverse Methods in Thermal Radiation Analysis and Experiment. ASME Journal of Heat and Mass Transfer 145:5.
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Swagatika Acharya, Vijay Kumar Mishra, Jitendra Kumar Patel, Gaurav Gupta, Sumanta Chaudhuri & Niraj Kumar Mishra. 2023. Recent Advances in Thermofluids and Manufacturing Engineering. Recent Advances in Thermofluids and Manufacturing Engineering
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André C. Contini & Fernando M. Pereira. (2022) Numerical study of flame stability within inert porous media with variable void area. Combustion and Flame 246, pages 112475.
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Kshitij Anand, Abhishek Bhardwaj, Sumanta Chaudhuri & Vijay K. Mishra. (2022) Self-Organizing Map Network for the Decision Making in Combined Mode Conduction-Radiation Heat Transfer in Porous Medium. Arabian Journal for Science and Engineering 47:12, pages 15175-15194.
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Marta F.C. Fidalgo, Miguel A.A. Mendes & José M.C. Pereira. (2021) An automated method for efficient multi-parametric analysis of porous radiant burner performance. International Journal of Thermal Sciences 163, pages 106851.
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S. Saravanan, Ramesh Kumar Chidambaram & V. Edwin Geo. (2020) An experimental study to analyze influence of porous media combustor on performance and emission characteristics of a DI diesel engine. Fuel 280, pages 118645.
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Seyed Mohammad Vahidhosseini, Javad Abolfazli Esfahani & Kyung Chun Kim. (2020) Cylindrical porous radiant burner with internal combustion regime: Energy saving analysis using response surface method. Energy 207, pages 118231.
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Mykhailo Samoilenko, Patrice Seers, Patrick Terriault & Vladimir Brailovski. (2019) Design, manufacture and testing of porous materials with ordered and random porosity: Application to porous medium burners. Applied Thermal Engineering 158, pages 113724.
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H. B. GaoX. B. FengZ. G. Qu. (2017) Combustion in a Hybrid Porous Burner Packed with Alumina Pellets and Silicon Carbide Foams with a Gap. Journal of Energy Engineering 143:5.
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Bibhuti Bhusan Samantaray, P. Pradhan, Dillip K. Sahoo & P.C. Mishra. (2015) Comparative Thermal Performance and Emission Analysis of Flat, Semi-swirl and Full-swirl Cooking Burners-Experimental Results. Procedia Engineering 127, pages 932-939.
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H.B. Gao, Z.G. Qu, X.B. Feng & W.Q. Tao. (2014) Methane/air premixed combustion in a two-layer porous burner with different foam materials. Fuel 115, pages 154-161.
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Huaibin Gao, Zhiguo Qu, Xiangbo Feng & Wenquan Tao. (2014) Combustion of methane/air mixtures in a two-layer porous burner: A comparison of alumina foams, beads, and honeycombs. Experimental Thermal and Fluid Science 52, pages 215-220.
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Huai-Bin Gao, Zhi-Guo Qu, Wen-Quan Tao & Ya-Ling He. (2013) Experimental investigation of methane/(Ar, N2, CO2)–air mixture combustion in a two-layer packed bed burner. Experimental Thermal and Fluid Science 44, pages 599-606.
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