Ashkan Hosseini scite author profile

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Comparative Numerical Study of Single-Phase and Two-Phase Models for Bio-Nanofluid Transport Phenomena

Bég¹,

Rashidi

Akbari

et al. 2014

J. Mech. Med. Biol.

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A computational fluid dynamics (CFD) simulation of laminar convection of Al 2 O 3–water bio-nanofluids in a circular tube under constant wall temperature conditions was conducted, employing a single-phase model and three different two-phase models (volume of fluid (VOF), mixture and Eulerian). The steady-state, three-dimensional flow conservation equations were discretised using the finite volume method (FVM). Several parameters such as temperature, flow field, skin friction and heat transfer coefficient were computed. The computations showed that CFD predictions with the three different two-phase models are essentially the same. The CFD simulations also demonstrated that single-phase and two-phase models yield the same results for fluid flow but different results for thermal fields. The two-phase models, however, achieved better correlation with experimental measurements. The simulations further showed that heat transfer coefficient distinctly increases with increasing nanofluid particle concentration. The physical properties of the base fluid were considered to be temperature-dependent, while those of the solid particles were constant. Grid independence tests were also included. The simulations have applications in novel biomedical flow processing systems.

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Representing solute solubility in supercritical carbon dioxide: A novel empirical model

Khansary

Amiri

Hosseini

et al. 2015

Chemical Engineering Research and Design

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Ashkan Hosseini

Homotopy simulation of nanofluid dynamics from a non-linearly stretching isothermal permeable sheet with transpiration

Comparative numerical study of single and two-phase models of nanofluid heat transfer in wavy channel

Wood Pellet as a Renewable Source of Energy

Comparative Numerical Study of Single-Phase and Two-Phase Models for Bio-Nanofluid Transport Phenomena

Representing solute solubility in supercritical carbon dioxide: A novel empirical model

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