• حسین سلطانی پور

  • دانشیار
  • گروه مهندسی مکانیک
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Hajialiloo, H. and Soltanipour, H., 2024. Numerical assessment of thermomagnetic convection of ferrofluid in a porous cavity employing a local thermal nonequilibrium model. Thermal Science and Engineering Progress, 53, p.102693.
Jalayeri, A., Soltanipour, H. and Rezazadeh, S., 2024. Simultaneous Effects of a Vortex Generator and Magnetic Field on Ferrofluid Convective Heat Transfer in a 3D Channel: First and Second Law Analyses. AUT Journal of Mechanical Engineering, 8(2), pp.1-1.
Abdi, H., Yekani Motlagh, S. and Soltanipour, H., 2023. Large Eddy Simulation and Proper Orthogonal Decomposition Analysis of Two-phase Turbulent Thermomagnetic Convection of a Ferrofluid in a Cubic Cavity. AUT Journal of Mechanical Engineering, 7(2), pp.155-174.

 Goudarzi, S., Yekani Motlagh, S. and Soltanipour, H., 2022. Two-phase simulation of MHD and FHD impacts on the natural convection of a magnetic nanofluid within a porous cavity. Mechanical engineering, 6(1), pp.9-9.

 Jalayeri Gharahghonlou, A., Soltanipour, H. and Rezazadeh, S., 2021. Numerical investigation of turbulent nanofluid flow and nanoparticle diameter on heat transfer in a wavy form channel. نشریه پژوهشی مهندسی مکانیک ایران.&lrm

Soltanipour, H., 2021. Numerical analysis of two-phase ferrofluid forced convection in an annulus subjected to magnetic sources. Applied Thermal Engineering, 196, p.117278.

Abdi, H., Motlagh, S.Y. and Soltanipour, H., 2021. Numerical study of two-phase flow in a square cavity under magnetic field of parallel wires. Meccanica, 56(8), pp.2005-2020.

Soltanipour, H. and Pourfattah, F., 2021. Simultaneous use of non-uniform magnetic field and porous medium for the intensification of convection heat transfer of a magnetic nanofluid inside a tube. Journal of the Brazilian Society of Mechanical Sciences and Engineering, 43(10), pp.1-19.

 Mehdizadeh Youshanlouei, M., Yekani Motlagh, S. and Soltanipour, H., 2021. The effect of magnetic field on the performance improvement of a conventional solar still: a numerical study. Environmental Science and Pollution Research, 28(24), pp.31778-31791.

Soltanipour, H., 2020. Two-phase simulation of magnetic field effect on the ferrofluid forced convection in a pipe considering Brownian diffusion, thermophoresis, and magnetophoresis. The European Physical Journal Plus, 135(9), pp.1-23.

Abdi, H., Motlagh, S.Y. and Soltanipour, H., 2020. Study of magnetic nanofluid flow in a square cavity under the magnetic field of a wire carrying the electric current in turbulence regime. Results in Physics, 18, p.103224.

Soltanipour, H., Gharegöz, A. and Oskooee, M.B., 2020. Numerical study of magnetic field effect on the ferrofluid forced convection and entropy generation in a curved pipe. Journal of the Brazilian Society of Mechanical Sciences and Engineering, 42(3), pp.1-15.

Habibinia, D., Rostami, N., Feyzi, M.R., Soltanipour, H. and Pyrhönen, J., 2019. New finite element based method for thermal analysis of axial flux interior rotor permanent magnet synchronous machine. IET Electric Power Applications, 14(3), pp.464-470.

Motlagh, S.Y., Taghizadeh, S. and Soltanipour, H., 2016. Natural convection heat transfer in an inclined square enclosure filled with a porous medium saturated by nanofluid using Buongiorno&rsquos mathematical model. Advanced Powder Technology, 27(6), pp.2526-2540.

Motlagh, S.Y. and Soltanipour, H., 2017. Natural convection of Al2O3-water nanofluid in an inclined cavity using Buongiorno's two-phase model. International Journal of Thermal Sciences, 111, pp.310-320.

Soltanipour, H., Khalilarya, S., Yekani Motlagh, S. and Mirzaee, I., 2017. The effect of position-dependent magnetic field on nanofluid forced convective heat transfer and entropy generation in a microchannel. Journal of the Brazilian Society of Mechanical Sciences and Engineering, 39, pp.345-355.

Razeghi, A., Mirzaee, I., Abbasalizadeh, M. and Soltanipour, H., 2017. Al 2 O 3/water nano-fluid forced convective flow in a rectangular curved micro-channel: first and second law analysis, single-phase and multi-phase approach. Journal of the Brazilian Society of Mechanical Sciences and Engineering, 39, pp.2307-2318.

Soltanipour, H., Pourmahmoud, N. and Mirzaee, I., 2015. The effects of longitudinal fins on thermal performance of a curved microchannel: a numerical study. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 229(5), pp.906-915.

Pourmahmoud, N., Soltanipour, H. and Mirzaee, I., 2016. The effects of longitudinal ribs on entropy generation for laminar forced convection in a microchannel. Thermal Science, 20(6), pp.1963-1972.

Razavi, E.S., Soltanipour, H. and Choupani, P., 2015. Second law analysis of laminar forced convection in a rotating curved duct. Thermal Science, 19(1), pp.95-107.

Soltanipour, H., Choupani, P. and Mirzaee, I., 2012. Numerical analysis of heat transfer enhancement with the use of &gamma-Al2O3/water nanofluid and longitudinal ribs in a curved duct. Thermal science, 16(2), pp.469-480.

 




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