Thermal Performance of Hybrid Nanofluid in a Rotating Vertical Channel between Two Plates.

Abstract

The main purpose of this thesis is construct the mathematical model of the fluid flow in a rotating system between two infinitely flat surfaces. In this model one plate is stretchable while other is penetrable. By using basic fundamental law, equation of momentum and energy are formulated. Then, these energy and momentum equations are converted in to non-linear ordinary differential equation by using similarity variables. Theses ordinary differential equation are further solve by using Adomian decomposition method (ADM). The impact of various parameters on temperature and velocity profiles are investigate. The obtained result shows the variation of Nusselt number by increasing the radiation and injection parameter. This thesis is split in to five chapter. In chapter 1 comprehensive review analysis is done to determine gape exist, where we can fill up by developing the modification in fundamental laws and methodology. Chapter 2 is related to basic concept of fluid and its properties of fluid. Chapter 3 is review work done by Ali J Chamkha et al [35] that deals flow of hybrid nanofluid between two parallel plates. Chapter 4 is the extension of chapter 3 in which we have developed the channel flow with various effects that improve the thermal conductivity and flow behavior between the channels. In the very last chapter, conclusion of entire analysis is presented.