O. Zeitoun scite author profile

O. Zeitoun

5Publications

158Citation Statements Received

88Citation Statements Given

How they've been cited

528

155

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Affiliations

King Saud University, McMaster University, Alexandria University

Publications

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Natural convection in a horizontal cylindrical annulus using porous fins

Kiwan

Zeitoun

2008

103

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PurposeThe aim is to study the effects of fin conductivity ratio, Darcy number, and Rayleigh number on the average Nusselt number for fins made of porous material when attached to the inner cylinder of the annulus between two concentric cylinders. The paper also aims to compare the results with those obtained using solid fins over a range of Rayleigh numbers.Design/methodology/approachThe Darcy‐Brinkman equations were used to model the fluid flow inside the porous media and the Boussinesq approximation was used to model the buoyancy effect. The energy equation is also solved to find the temperature distribution in the domain of interest. The model equations are solved numerically using a finite volume code.FindingsPorous fins provided higher heat transfer rates than solid fins for similar configurations. This enhancement in heat transfer reached 75 per cent at Ra=5 × 104 and Da=2.5 × 10−2. It is also found that unlike solid fins the rate of heat transfer from the cylinder equipped with porous fins decreases with increasing the fin inclination angle.Research limitations/implicationsThe range of the Rayleigh number considered in this research covers only the laminar regime. The research does not cover turbulent flows. In addition to that, the local thermal equilibrium assumption is used.Practical implicationsThis work can help designers in selecting the proper material properties and operating conditions in designing porous fins to enhance the heat transfer in the annulus between two horizontal concentric cylinders under natural convection condition.Originality/valueThis work has not been done before and it can initiate additional research projects as looking at the performance of porous fins under other conditions and configurations (e.g. turbulent conditions).

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Bubble Behavior and Mean Diameter in Subcooled Flow Boiling

Zeitoun

Shoukri

1996

174

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Bubble behavior and mean bubble diameter in subcooled upward flow boiling in a vertical annular channel were investigated under low pressure and mass flux conditions. A high-speed video system was used to visualize the subcooled flow boiling phenomenon. The high-speed photographic results indicated that, contrary to the common understanding, bubbles tend to detach from the heating surface upstream of the net vapor generation point. Digital image processing technique was used to measure the mean bubble diameter along the subcooled flow boiling region. Data on the axial area-averaged void fraction distributions were also obtained using a single-beam gamma densitometer. Effects of the liquid subcooling, applied heat flux, and mass flux on the mean bubble size were investigated. A correlation for the mean bubble diameter as a function of the local subcooling, heat flux, and mass flux was obtained.

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Axial void fraction profile in low pressure subcooled flow boiling

Zeitoun

Shoukri

1997

International Journal of Heat and Mass Transfer

135

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Measurement of interfacial area concentration in subcooled liquid-vapour flow

Zeitoun

Shoukri

Chatoorgoon

1994

Nuclear Engineering and Design

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Nanofluid impingement jet heat transfer

Zeitoun

Ali

2012

Nanoscale Res Lett

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Experimental investigation to study the heat transfer between a vertical round alumina-water nanofluid jet and a horizontal circular round surface is carried out. Different jet flow rates, jet nozzle diameters, various circular disk diameters and three nanoparticles concentrations (0, 6.6 and 10%, respectively) are used. The experimental results indicate that using nanofluid as a heat transfer carrier can enhance the heat transfer process. For the same Reynolds number, the experimental data show an increase in the Nusselt numbers as the nanoparticle concentration increases. Size of heating disk diameters shows reverse effect on heat transfer. It is also found that presenting the data in terms of Reynolds number at impingement jet diameter can take into account on both effects of jet heights and nozzle diameter. Presenting the data in terms of Peclet numbers, at fixed impingement nozzle diameter, makes the data less sensitive to the percentage change of the nanoparticle concentrations. Finally, general heat transfer correlation is obtained verses Peclet numbers using nanoparticle concentrations and the nozzle diameter ratio as parameters.

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O. Zeitoun

Natural convection in a horizontal cylindrical annulus using porous fins

Bubble Behavior and Mean Diameter in Subcooled Flow Boiling

Axial void fraction profile in low pressure subcooled flow boiling

Measurement of interfacial area concentration in subcooled liquid-vapour flow

Nanofluid impingement jet heat transfer

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