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A platform for research: civil engineering, architecture and urbanism
Micropolar nanoliquid flow via mixed convective over an orthogonal cylinder
The intent of the current investigation is to explore the axisymmetric flow of the micropolar nanoliquid past an orthogonal cylinder in the existence of mixed convection impact. Suitable similitude changes produce joined nonlinear differential schemes, which were explicated via fourth‐order finite difference style. The authenticity of the results was emphasized by contrasting them with previous results with some limited presumptions and uncovered to be in excellent agreement. Performance of numerous physical parameters on velocity components and temperature distributions alongside the physical quantities of interests were revealed graphically and in tabular forms. It was shown that the skin friction and heat transport rate boost with rising in the volume fraction nanoparticle and the buoyancy, while they decline with the increase of micropolar parameter. This investigation intends to improve on an intuitive understanding of similar patterns by confirming the physical debates and may be applicable in the field of biomechanics, polymer processing, production of aerosol deposition, and thermal treatment.
Micropolar nanoliquid flow via mixed convective over an orthogonal cylinder
The intent of the current investigation is to explore the axisymmetric flow of the micropolar nanoliquid past an orthogonal cylinder in the existence of mixed convection impact. Suitable similitude changes produce joined nonlinear differential schemes, which were explicated via fourth‐order finite difference style. The authenticity of the results was emphasized by contrasting them with previous results with some limited presumptions and uncovered to be in excellent agreement. Performance of numerous physical parameters on velocity components and temperature distributions alongside the physical quantities of interests were revealed graphically and in tabular forms. It was shown that the skin friction and heat transport rate boost with rising in the volume fraction nanoparticle and the buoyancy, while they decline with the increase of micropolar parameter. This investigation intends to improve on an intuitive understanding of similar patterns by confirming the physical debates and may be applicable in the field of biomechanics, polymer processing, production of aerosol deposition, and thermal treatment.
Micropolar nanoliquid flow via mixed convective over an orthogonal cylinder
EL‐Zahar, Essam R. (author) / Mansour, Mohamed. A. (author) / Rashad, A. M. (author) / EL‐Mky, Hamed A. (author) / EL‐Hakiem, Amal. M. A. (author)
Heat Transfer ; 50 ; 6425-6443
2021-11-01
19 pages
Article (Journal)
Electronic Resource
English