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https://doi.org/10.15255/CABEQ.2020.1849

Homotopy Simulation of Dissipative Micropolar Flow and Heat Transfer from a Two-Dimensional Body with Heat Sink Effect: Applications in Polymer Coating

O. A. Bég ; Multi-Physical Engineering Sciences Group, Aeronautical/Mechanical Engineering, SEE, Salford University, M54WT, UK
B. Vasu ; Department of Mathematics, Motilal Nehru National Institute of Technology, Allahabad, Prayagraj-211004, India
A. K. Ray ; Centre of Applied Mathematics and Computing, ITER, Siksha ‘O’ Anusandhan, Bhubaneswar-751030, Odisha, India
T. A. Bég ; Engineering Mechanics Research, Israfil House, Dickenson Rd., Manchester, M13, UK
A. Kadir ; Multi-Physical Engineering Sciences Group, Aeronautical/Mechanical Engineering, SEE, Salford University, M54WT, UK
H. J. Leonard ; Multi-Physical Engineering Sciences Group, Aeronautical/Mechanical Engineering, SEE, Salford University, M54WT, UK
R. S. R. Gorla ; Department of Aeronautics and Astronautics, Air Force Institute of Technology, Wright Patterson Air Force Base, Dayton, Ohio 45433, USA

Sažetak

Non-Newtonian flow from a wedge constitutes a fundamental problem in chemical engineering systems and is relevant to processing of polymers, coating systems, etc. Motivated by such applications, the homotopy analysis method (HAM) was employed to obtain semi-analytical solutions for thermal convection boundary layer flow of incompressible micropolar fluid from a two-dimensional body (wedge). Viscous dissipation and heat sink effects were included. The non-dimensional boundary value problem emerges as a system of nonlinear coupled ordinary differential equations, by virtue of suitable coordinate transformations. The so-called Falkner-Skan flow cases are elaborated. Validation of the HAM solutions was achieved with earlier simpler models, as well as with a Nakamura finite difference method for the general model. The micropolar model employed simulates certain polymeric solutions quite accurately, and features rotary motions of micro-elements. Primary and secondary shear stress, wall couple stress, Nusselt number, microrotation velocity, and temperature were computed for the effect of vortex viscosity parameter (micropolar rheological), Eckert number (viscous dissipation), Falkner-Skan (pressure gradient) parameter, micro-inertia density, and heat sink parameter. The special cases of Blasius and stagnation flow were also addressed. It was observed from the study that the temperature and thermal boundary layer thickness are both suppressed with increasing wedge parameter and wall heat sink effect, which is beneficial to temperature regulation in polymer coating dynamics. Further, strong reverse spin was generated in the microrotation with increasing vortex viscosity, which resulted in increase in angular momentum boundary layer thickness. Also, both primary and secondary skin friction components were reduced with increasing wedge parameter. Nusselt number was also enhanced substantially with greater wedge parameter.







This work is licensed under a Creative Commons Attribution 4.0 International License.

Ključne riječi

micropolar fluid; wedge flow; homotopy analysis method; Nakamura difference scheme; pressure gradient; polymer flow processing

Hrčak ID:

251483

URI

https://hrcak.srce.hr/251483

Datum izdavanja:

3.2.2021.

Posjeta: 667 *