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Numerical Heat Transfer, Part A: Applications
An International Journal of Computation and Methodology
Volume 56, 2009 - Issue 6
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Original Articles

Effect of Surface Roughness in Parallel-Plate Microchannels on Heat Transfer

M. B. Turgay Department of Mechanical Engineering, Middle East Technical University, Ankara, Turkey
&
A. G. Yazicioglu Department of Mechanical Engineering, Middle East Technical University, Ankara, TurkeyCorrespondence[email protected]
Pages 497-514 | Received 01 Apr 2009, Accepted 10 Aug 2009, Published online: 25 Sep 2009

Citations (17)

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Read on this site (3)

Anil Singh Yadav & J.L. Bhagoria. (2014) A Numerical Investigation of Turbulent Flows through an Artificially Roughened Solar Air Heater. Numerical Heat Transfer, Part A: Applications 65:7, pages 679-698.
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Chungpyo Hong, Yutaka Asako, Koichi Suzuki & Mohammad Faghri. (2012) Friction Factor Correlations for Compressible Gaseous Flow in a Concentric Micro Annular Tube. Numerical Heat Transfer, Part A: Applications 61:3, pages 163-179.
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Tien-Mo Shih, Martinus Arie & Derrick Ko. (2011) Literature Survey of Numerical Heat Transfer (2000–2009): Part II. Numerical Heat Transfer, Part A: Applications 60:11-12, pages 883-1096.
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Articles from other publishers (14)

Shuyu Ding, Kai Huang, Yifan Han & Damir Valiev. (2021) Numerical study of the influence of wall roughness on laminar boundary layer flashback. Physical Review Fluids 6:2.
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Turgay Coskun & Erdal Cetkin. (2020) A review of heat and fluid flow characteristics in microchannel heat sinks. Heat Transfer 49:8, pages 4109-4133.
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Nehir Tokgoz, Tural Tunay & Besir Sahin. (2018) Effect of corrugated channel phase shifts on flow structures and heat transfer rate. Experimental Thermal and Fluid Science 99, pages 374-391.
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Raheem K. Ajeel, W.S-I. W. Salim & Khalid Hasnan. (2018) Thermal and hydraulic characteristics of turbulent nanofluids flow in trapezoidal-corrugated channel: Symmetry and zigzag shaped. Case Studies in Thermal Engineering 12, pages 620-635.
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Almıla G. Yazıcıoğlu, Selin Aradağ, Ece Aylı, Gizem Gülben & Sadık Kakaç. 2018. Comprehensive Energy Systems. Comprehensive Energy Systems 40 69 .
Elaheh Dorari, Majid Saffar-Avval & Zohreh Mansoori. (2015) Numerical simulation of gas flow and heat transfer in a rough microchannel using the lattice Boltzmann method. Physical Review E 92:6.
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Yangpeng Liu, Guoqiang Xu, Jining Sun & Haiwang Li. (2015) Investigation of the roughness effect on flow behavior and heat transfer characteristics in microchannels. International Journal of Heat and Mass Transfer 83, pages 11-20.
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Ali Ijam, R. Saidur & P. Ganesan. (2012) Cooling of minichannel heat sink using nanofluids. International Communications in Heat and Mass Transfer 39:8, pages 1188-1194.
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H.M. Park & H.D. Lee. (2012) Effects of wall roughness and velocity slip on streaming potential of microchannels. International Journal of Heat and Mass Transfer 55:11-12, pages 3295-3306.
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M.A. Ahmed, N.H. Shuaib, M.Z. Yusoff & A.H. Al-Falahi. (2011) Numerical investigations of flow and heat transfer enhancement in a corrugated channel using nanofluid. International Communications in Heat and Mass Transfer 38:10, pages 1368-1375.
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H.M. Park & H.S. Sohn. (2011) Measurement of zeta potential of macroscopic surfaces with Navier velocity slip exploiting electrokinetic flows in a microchannel. International Journal of Heat and Mass Transfer 54:15-16, pages 3466-3475.
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Dorin Lelea & Adrian Eugen Cioabla. (2010) The viscous dissipation effect on heat transfer and fluid flow in micro-tubes. International Communications in Heat and Mass Transfer 37:9, pages 1208-1214.
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Ming-I Char & Bo-Chen Tai. (2010) Effects of viscous dissipation on slip-flow heat transfer in a micro annulus. International Journal of Heat and Mass Transfer 53:7-8, pages 1402-1408.
Crossref
A. Guvenc Yazicioglu & S. Kakaç. 2010. Microfluidics Based Microsystems. Microfluidics Based Microsystems 15 38 .

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