Numerical and experimental investigation of flow structure and behavior of nanofluids flow impingement on horizontal flat plate

Numerical and experimental investigation of flow structure and behavior of nanofluids flow impingement on horizontal flat plate

•Jet impingement heat transfer is more superior by using nanofluids.•The heat transfer is very high in impingement zone and decrease rapidly outside it.•Re has a significant effect on the jet impingement heat transfer mechanism.•Heat transfer is high at low water film thickness. Numerical and experi...

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Published in:Experimental thermal and fluid science Vol. 74; pp. 235 - 246
Main Authors: Teamah, Mohamed A., Khairat Dawood, Mohamed M., Shehata, Ali
Format: Journal Article
Language:English
Published: Elsevier Inc 01-06-2016
Subjects:
Average Nusselt number
Computational fluid dynamics
COPPER OXIDE
CUPRIC OXIDE
Film thickness
Flat plates
FLUID FLOW
FLUIDITY
Free jet
HEAT TRANSFER
Horizontal
Impinging
Local Nusselt number
MATHEMATICAL ANALYSIS
Mathematical models
Nanofluid
Nanofluids
PLATE
Average Nusselt number
Local Nusselt number
Free jet
Impinging
Nanofluid
Heat transfer
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Summary:•Jet impingement heat transfer is more superior by using nanofluids.•The heat transfer is very high in impingement zone and decrease rapidly outside it.•Re has a significant effect on the jet impingement heat transfer mechanism.•Heat transfer is high at low water film thickness. Numerical and experimental studies have been conducted to investigate flow structure and heat transfer of nanofluid jet normally impinging on a flat plate. Al2O3–water is used as working fluid. The governing equations are numerically solved using finite volume approach together with SIMPLER algorithm. A wide spectrum of experimental and numerical simulations has been done. The results covered wide ranges of Reynolds number, Re, from 3000 to 32,000, nanofluid volume fraction, ϕ, from 0 to 10%. The dimensionless distance from jet nozzle to the horizontal plate was kept constant at 3. An experimental apparatus was constructed to measure the film thickness distribution, wall temperature and temperature of flowing fluid. The effects of Re and ϕ are investigated on the film thickness distribution, isothermal contours, and both local and average Nusselt numbers. A good agreement was found between the numerical and experimental results as well as the previous cited results. The results showed that the increasing of nanoparticle percent increases the convective heat transfer coefficient compared with the pure water. At ϕ=10.0% and Re=24,000 the heat transfer coefficient increases by 62% compared with the pure water. The effect of nanofluid type (Al2O3–TiO2–CuO) is studied numerically. It has been observed that the CuO nanofluid increases the heat transfer by 8.9% and 12% compared to aluminum and titanium nanofluid respectively.
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ISSN:0894-1777
1879-2286
DOI:10.1016/j.expthermflusci.2015.12.012