Heat transfer enhancement of turbulent nanofluid flow over various types of internally corrugated channels
Ethylene; Ethylene glycol; Finite volume method; Geometry; Glycerol; Heat flux; Heat transfer; Nanoparticles; Nusselt number; Reynolds number; Turbulent flow; Volume fraction; Changing parameter; Corrugated channel; Grooved channel; Heat Transfer enhancement; Nanofluids; Nanoparticle diameter; Skin-...
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my.uniten.dspace-222112023-05-29T13:59:38Z Heat transfer enhancement of turbulent nanofluid flow over various types of internally corrugated channels Navaei A.S. Mohammed H.A. Munisamy K.M. Yarmand H. Gharehkhani S. 57202235458 15837504600 15035918600 56096104400 56066992400 Ethylene; Ethylene glycol; Finite volume method; Geometry; Glycerol; Heat flux; Heat transfer; Nanoparticles; Nusselt number; Reynolds number; Turbulent flow; Volume fraction; Changing parameter; Corrugated channel; Grooved channel; Heat Transfer enhancement; Nanofluids; Nanoparticle diameter; Skin-friction factors; Thermal Performance; Nanofluidics; aluminum oxide nanoparticle; copper oxide nanoparticle; ethylene glycol; glycerol; nanoparticle; silica nanoparticle; unclassified drug; water; zinc oxide nanoparticle; Article; comparative study; dispersion; flow rate; fluid flow; fractionation; geometry; heat transfer; height; process optimization; simulation; thermal analysis; turbulent flow; turbulent nanofluid flow; validation process A numerical study is carried out to investigate the effects of different geometrical parameters and various nanofluids on the thermal performance of rib-grooved channels under uniform heat flux. The continuity, momentum and energy equations are solved by using the finite volume method (FVM). Three different rib-groove shapes are studied (rectangular, semi-circular and trapezoidal). Four different types of nanoparticles, Al2O3, CuO, SiO2 and ZnO with different volume fractions in the range of 1% to 4% and different nanoparticle diameters in the range of 20nm to 60nm, are dispersed in the base fluids such as water, glycerin and ethylene glycol. The Reynolds number varies from 5000 to 25,000. To optimize the shape of rib-groove channels different rib-groove heights from 0.1Dh (4mm) to 0.2Dh (8mm) and rib-groove pitch from 5e (20mm) to 7e (56mm) are examined. Simulation results reveal that the semi-circular rib-groove with height of 0.2Dh (8mm) and pitch equals to 6e (48mm) has the highest Nusselt number. The nanofluid containing SiO2 has the highest Nusselt number compared with other types. The Nusselt number rises as volume fraction increases, and it declines as the nanoparticle diameter increases. The glycerin-SiO2 nanofluid has the best heat transfer compared to other base fluids. It is also observed that in the case of using nanofluid by changing parameters such as nanoparticle diameter, volume fraction and base fluids the skin friction factor has no significant changes. � 2015 Elsevier B.V. Final 2023-05-29T05:59:38Z 2023-05-29T05:59:38Z 2015 Article 10.1016/j.powtec.2015.06.009 2-s2.0-84940385125 https://www.scopus.com/inward/record.uri?eid=2-s2.0-84940385125&doi=10.1016%2fj.powtec.2015.06.009&partnerID=40&md5=f57eba6ef70e052bd3564fad6b36d5af https://irepository.uniten.edu.my/handle/123456789/22211 286 332 341 Elsevier Scopus |
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Ethylene; Ethylene glycol; Finite volume method; Geometry; Glycerol; Heat flux; Heat transfer; Nanoparticles; Nusselt number; Reynolds number; Turbulent flow; Volume fraction; Changing parameter; Corrugated channel; Grooved channel; Heat Transfer enhancement; Nanofluids; Nanoparticle diameter; Skin-friction factors; Thermal Performance; Nanofluidics; aluminum oxide nanoparticle; copper oxide nanoparticle; ethylene glycol; glycerol; nanoparticle; silica nanoparticle; unclassified drug; water; zinc oxide nanoparticle; Article; comparative study; dispersion; flow rate; fluid flow; fractionation; geometry; heat transfer; height; process optimization; simulation; thermal analysis; turbulent flow; turbulent nanofluid flow; validation process |
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57202235458 Navaei A.S. Mohammed H.A. Munisamy K.M. Yarmand H. Gharehkhani S. |
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Navaei A.S. Mohammed H.A. Munisamy K.M. Yarmand H. Gharehkhani S. |
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Navaei A.S. Mohammed H.A. Munisamy K.M. Yarmand H. Gharehkhani S. Heat transfer enhancement of turbulent nanofluid flow over various types of internally corrugated channels |
author_sort |
Navaei A.S. |
title |
Heat transfer enhancement of turbulent nanofluid flow over various types of internally corrugated channels |
title_short |
Heat transfer enhancement of turbulent nanofluid flow over various types of internally corrugated channels |
title_full |
Heat transfer enhancement of turbulent nanofluid flow over various types of internally corrugated channels |
title_fullStr |
Heat transfer enhancement of turbulent nanofluid flow over various types of internally corrugated channels |
title_full_unstemmed |
Heat transfer enhancement of turbulent nanofluid flow over various types of internally corrugated channels |
title_sort |
heat transfer enhancement of turbulent nanofluid flow over various types of internally corrugated channels |
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Elsevier |
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2023 |
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1806426244326096896 |
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13.222552 |