During thermal radiation treatments, heat therapies,
and examination
procedures like scans and X-rays, the cylindrical blood vessels may
get stretched; meanwhile, the blood flow through those blood vessels
may get affected due to temperature variations around them. To overcome
this issue, this work was framed to explore the impact of heat transmission
in a Carreau fluid flow (CFF) through a stretching cylinder in terms
of the nonlinear stretching rate and irregular heat source/sink. Temperature-dependent
thermal conductivity and thermal radiation are taken into consideration
in this study. To tranform complicated partial differential equations
into ordinary differential equations, appropriate similarity variables
are used. For a limited set of instances, the derived series solutions
are compared to previously published results. For linear and nonlinear
stretching rates, graphs and tables are used to examine the influence
of an irregular heat source/sink on fluid movement and heat transfer.
The research outcomes demonstrate that the heat source and nonlinear
stretching rate cause a disruption in the temperature distribution
in the fluid region, which can alter the blood flow through the vessels.
In all conditions except for the heat in an internal heat sink, the
nonlinear stretching situation improves the velocity and heat profile.
Furthermore, with the increase in the values of the Weissenberg number,
the temperature profile shows opposing features in a shear-thickening
fluid and shear-thinning fluid. For the former
n
>
1, the blood fluidity gets affected, restricting the free movement
of blood. For the latter,
n
< 1, the phenomenon
is reversed. Other industrial applications of this work are wire coating,
plastic coverings, paper fabrication, fiber whirling, etc. In all
of those processes, the fluid flow is manipulated by thermal conditions.
In solar heating, ventilation, and air conditioning (HVAC), communications are designed to create new 3D mathematical models that address the flow of rotating Sutterby hybrid nanofluids exposed to slippery and expandable seats. The heat transmission investigation included effects such as copper and graphene oxide nanoparticles, as well as thermal radiative fluxing. The activation energy effect was used to investigate mass transfer with fluid concentration. The boundary constraints utilized were Maxwell speed and Smoluchowksi temperature slippage. With the utilization of fitting changes, partial differential equations (PDEs) for impetus, energy, and concentricity can be decreased to ordinary differential equations (ODEs). To address dimensionless ODEs, MATLAB’s Keller box numerical technique was employed. Graphene oxide Copper/engine oil (GO-Cu/EO) is taken into consideration to address the performance analysis of the current study. Physical attributes, for example, surface drag coefficient, heat move, and mass exchange are mathematically processed and shown as tables and figures when numerous diverse factors are varied. The temperature field is enhanced by an increase in the volume fraction of copper and graphene oxide nanoparticles, while the mass fraction field is enhanced by an increase in activation energy.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.