Effects of Convective Heating and Suction/Injection on Mixed Convective Flow of a Nanofluid over Rotating Truncated Cone

Abstract

This paper investigates the mixed convective pour of a nanofluid through warmth as well as accumulation transport induced by the vertical rotation of a permeable truncated cone. The study considers convective-type thermal boundary conditions and zero nanoparticle mass flux conditions. The effects of thermophoresis and Brownian motion have been integrated into the present nanofluid model. To transform the coupled non-linear border line sheet equations into dimensionless partial differential equations, a set of non-similarity transformations is introduced. The ensuing PDEs are then numerically figured out using a Spectral collocation method in conjunction with the local linearization technique. To authenticate the numerical technique, the obtained outcomes are in contrast to with established findings in a specific case. The manipulate of a variety of corporeal constraints inactive on the tangential and swirl velocities of the nanofluid, as well as warmth, hard volume fraction, as well as exterior drag, warmth, as well as accumulation transport characteristics, are discussed.