The scientist’s investigation covers issues in Thermodynamics, Heat transfer, Nusselt number, Mechanics and Nanofluid. As part of his studies on Thermodynamics, Mousa Farhadi often connects relevant subjects like Composite material. His Heat transfer study incorporates themes from Pressure drop, Heat exchanger and Reynolds number.
His work focuses on many connections between Nusselt number and other disciplines, such as Natural convection, that overlap with his field of interest in Cylinder and Annulus. In his research on the topic of Mechanics, Thermal conduction and Eccentric is strongly related with Phase-change material. Mousa Farhadi has included themes like Volume fraction, Streamlines, streaklines, and pathlines and Lattice Boltzmann methods in his Nanofluid study.
Mousa Farhadi mostly deals with Mechanics, Heat transfer, Thermodynamics, Nusselt number and Lattice Boltzmann methods. While the research belongs to areas of Mechanics, Mousa Farhadi spends his time largely on the problem of Classical mechanics, intersecting his research to questions surrounding Drag. Mousa Farhadi studied Heat transfer and Fin that intersect with Annular fin.
His biological study spans a wide range of topics, including Nanofluid, Prandtl number, Richardson number and Forced convection. His Nanofluid study combines topics in areas such as Volume fraction, Streamlines, streaklines, and pathlines and Viscosity. The study incorporates disciplines such as Porosity, Porous medium, Natural convection, Rayleigh number and Phase-change material in addition to Lattice Boltzmann methods.
His primary scientific interests are in Mechanics, Heat transfer, Nusselt number, Turbulence and Pressure drop. The concepts of his Mechanics study are interwoven with issues in Heat exchanger and Thermal. Mousa Farhadi does research in Heat transfer, focusing on Nanofluid specifically.
His Nusselt number study necessitates a more in-depth grasp of Reynolds number. In his study, Evaporation, Refrigerant and Heat transfer coefficient is inextricably linked to Heat flux, which falls within the broad field of Pressure drop. His Heat transfer enhancement research includes themes of Natural convection, Microchannel, Lattice Boltzmann methods and Compressibility.
Mousa Farhadi focuses on Mechanics, Heat transfer, Nusselt number, Natural convection and Reynolds number. His Mechanics study focuses mostly on Subcooling and Lattice Boltzmann methods. His study in Heat transfer is interdisciplinary in nature, drawing from both Fin and Heat sink.
His Natural convection research is multidisciplinary, relying on both Radiation, Thermal and Heat transfer enhancement. The various areas that Mousa Farhadi examines in his Heat transfer enhancement study include Porosity, Thermal conductivity, Magnetohydrodynamics, Flow and Ferrofluid. Mousa Farhadi interconnects Nanofluid and Pressure drop in the investigation of issues within Reynolds number.
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Melting and solidification of PCM enhanced by radial conductive fins and nanoparticles in cylindrical annulus
A. Ali Rabienataj Darzi;Mahmoud Jourabian;Mousa Farhadi.
Energy Conversion and Management (2016)
Experimental analysis of heat transfer enhancement in shell and helical tube heat exchangers
N. Jamshidi;M. Farhadi;D.D. Ganji;K. Sedighi.
Applied Thermal Engineering (2013)
Numerical study of melting inside concentric and eccentric horizontal annulus
AhmadAli Rabienataj Darzi;Mousa Farhadi;Kurosh Sedighi.
Applied Mathematical Modelling (2012)
Lattice Boltzmann simulation of nanofluid in lid-driven cavity
H. Nemati;M. Farhadi;K. Sedighi;E. Fattahi.
International Communications in Heat and Mass Transfer (2010)
A comprehensive review on double pipe heat exchangers
Mohamad Omidi;Mousa Farhadi;Mohamad Jafari.
Applied Thermal Engineering (2017)
A review study on twisted tape inserts on turbulent flow heat exchangers: The overall enhancement ratio criteria
A. Hasanpour;M. Farhadi;K. Sedighi.
International Communications in Heat and Mass Transfer (2014)
Mixed convection heat transfer in a ventilated cavity with hot obstacle: Effect of nanofluid and outlet port location
A. Abouei Mehrizi;M. Farhadi;H. Hassanzade Afroozi;K. Sedighi.
International Communications in Heat and Mass Transfer (2012)
Lattice Boltzmann simulation of natural convection heat transfer in nanofluids
Ehsan Fattahi;Mousa Farhadi;Kurosh Sedighi;Hasan Nemati.
International Journal of Thermal Sciences (2012)
Heat transfer and flow characteristics of AL2O3–water nanofluid in a double tube heat exchanger
A.A. Rabienataj Darzi;Mousa Farhadi;Kurosh Sedighi.
International Communications in Heat and Mass Transfer (2013)
Magnetic field effects on natural convection flow of nanofluid in a rectangular cavity using the Lattice Boltzmann model
H. Nemati;M. Farhadi;K. Sedighi;H.R. Ashorynejad.
Scientia Iranica (2012)
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