Heat transfer enhancement of nanofluids in forced convection finite element model / Ivan Garbis Zaven Miskdjian ; Supervised Adel A. Megahed , Amr G. Guaily

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Ivan Garbis Zaven Miskdjian

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TextLanguage: English Publication details: Cairo : Ivan Garbis Zaven Miskdjian , 2017Description: 71 P. : charts , facsimiles ; 30cmOther title:

تحسين انتقال الحرارة خلال موائع النانوفي نموذج العناصر المحدودة للحمل القسري [Added title page title]

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Dissertation note: Thesis (M.Sc.) - Cairo University - Faculty of Engineering - Department of Mathematics and Physics Summary: Nanofluids, in which nano-sized particles of scale less than 100 nm are surged in fluids, have shown to possess enhanced heat transfer characteristics than common fluids. In this work, a numerical study, using Finite Element Streamline Upwind Petrov Galerkin SUPG method, is performed to study the heat transfer characteristics of nanofluids. The heat transfer coefficient and the wall shear stress are analyzed for alumina Al2O3 nanoparticles submerged in water and ethylene glycol as a base fluid under laminar forced convection in a channel. It is also assumed that the nanoparticles distribution in the base fluid is non-homogenous

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Thesis	قاعة الرسائل الجامعية - الدور الاول	المكتبة المركزبة الجديدة - جامعة القاهرة	Cai01.13.10.M.Sc.2017.Iv.H (Browse shelf(Opens below))		Not for loan	01010110075143000
CD - Rom	مخـــزن الرســائل الجـــامعية - البدروم	المكتبة المركزبة الجديدة - جامعة القاهرة	Cai01.13.10.M.Sc.2017.Iv.H (Browse shelf(Opens below))	75143.CD	Not for loan	01020110075143000

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Thesis (M.Sc.) - Cairo University - Faculty of Engineering - Department of Mathematics and Physics

Nanofluids, in which nano-sized particles of scale less than 100 nm are surged in fluids, have shown to possess enhanced heat transfer characteristics than common fluids. In this work, a numerical study, using Finite Element Streamline Upwind Petrov Galerkin SUPG method, is performed to study the heat transfer characteristics of nanofluids. The heat transfer coefficient and the wall shear stress are analyzed for alumina Al2O3 nanoparticles submerged in water and ethylene glycol as a base fluid under laminar forced convection in a channel. It is also assumed that the nanoparticles distribution in the base fluid is non-homogenous

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