Solar Radiation Energy Issues on
Nanoparticle Shapes in the Potentiality of
Water Based Cu, Al2O3 and SWCNTs
Volume 1 - Issue 2
R Kandasamy*, Mohammed Mahdi Fayyadh and Radiah Mohammad
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- Research Centre for Computational Fluid Dynamics, FSTPI, Universiti Tun Hussein Onn Malaysia, Malaysia
*Corresponding author:
R Kandasamy, Research Centre for Computational Fluid Dynamics, FSTPI, Universiti Tun Hussein Onn
Malaysia, Malaysia
Received: May 13, 2018; Published: May 24, 2018
DOI: 10.32474/ANOAJ.2018.01.000110
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Abstract
Energy is an extensive view for industrial advancement. Solar thermal energy is designed by light and heat which is radiated
by the sun, in the form of electromagnetic radiation. Solar energy is the highest promptly and sufficiently applicable authority of
green energy. Impact of nanoparticle shapes on the Hiemenz nano fluid (water based Cu, Al2O3 and SWCNTs) flow over a porous
wedge surface in view of solar radiation energy has been analyzed. The three classical form of nanoparticle shapes are registered
into report, i.e. sphere , cylinder and laminar . Nanoparticles in the water based Cu, Al2O3 and SWCNTs have been advanced as a
means to boost solar collector energy through explicit absorption of the entering solar energy. The controlling partial differential
equations (PDEs) are remodeled into ordinary differential equations (ODEs) by applying dependable accordance alteration and it is
determined numerically by executing Runge Kutta Fehlberg method with shooting technique. It is anticipated that the lamina shape
SWCNTs have dynamic heat transfer attainments in the flow improvement over a porous wedge surface as compared with the other
nanoparticle shapes in different nano fluid flow regime.
Keywords: Nano Particle Shapes; Unsteady Hiemenz Flow; Water Based Cu; Al2O3 and Swcnts; Solar Energy Radiation; Nano
Fluids; Solar Thermal Energy; Progressive Technology; Volumetric Receivers; Thermal Attitude
Abstract|
Introduction|
Mathematical Analysis|
Results and Discussion|
Nanoparticle Shapes|
Conclusion|
Acknowledgement|
Nomenclature|
References|