View in EDS

Mixed convection flow of an electrically conducting viscoelastic fluid between vertical parallel plates: Insights on thermal radiation, heat source/sink, and dissipation effects

Saved in:
Bibliographic Details
Title: Mixed convection flow of an electrically conducting viscoelastic fluid between vertical parallel plates: Insights on thermal radiation, heat source/sink, and dissipation effects
Authors: Abdullahi, Hussaini, Yabo, Sahabi Z., Shehu, Anas
Source: Caliphate Journal of Science and Technology; Vol. 7 No. 1 (2025); 150-161
Publisher Information: African Journals Online (AJOL), 2025.
Publication Year: 2025
Subject Terms: Viscoelastic fluid, Magnetohydrodynamic (MHD), Thermal radiation, Heat source/sink
Description: This study explores the mixed convection boundary layer flow and heat transfer of a viscoelastic fluid across a parallel plate, considering the influence of an applied magnetic field, thermal radiation, and viscous dissipation. The equations governing the flow of the fluid are described as Partial Differential Equations (PDEs) and Finite Difference Method (FDM) is used to obtain numerical solutions. Numerical investigations were conducted to examine the effect of parameters in the flow of the fluid i.e. on the velocity, temperature and concentration with the aid of graphs. Efficient heat transfer is critical in designing heat management systems for various industrial applications, where the heat transfer rate may need to be increased or decreased to optimize heating or cooling processes. Additionally, the findings are significant because the wall material's thermal properties depend on the cooling or heating rates during the production of metal or polymer sheets. Radiative effects and viscous dissipation contribute to higher temperature distributions and the expansion of the thermal boundary layer. Radiation particularly enhances heat generation in fluids, increasing their temperature, especially at elevated temperatures where it directly impacts heat transfer and temperature distribution. In the boundary layer, where transport phenomena oppose each other, the magnetic field becomes the dominant factor. The study further demonstrates that an applied magnetic field increases the fluid temperature profile while reducing the rate of heat transfer through the walls.
Document Type: Article
File Description: application/pdf
ISSN: 2705-3121
2705-313X
DOI: 10.4314/cajost.v7i1.15
Access URL: https://www.ajol.info/index.php/cajost/article/view/296299
Rights: CC BY NC
Accession Number: edsair.doi.dedup.....5cceb97a1f9da2e214c079f619f337d1
Database: OpenAIRE
Description
Abstract:This study explores the mixed convection boundary layer flow and heat transfer of a viscoelastic fluid across a parallel plate, considering the influence of an applied magnetic field, thermal radiation, and viscous dissipation. The equations governing the flow of the fluid are described as Partial Differential Equations (PDEs) and Finite Difference Method (FDM) is used to obtain numerical solutions. Numerical investigations were conducted to examine the effect of parameters in the flow of the fluid i.e. on the velocity, temperature and concentration with the aid of graphs. Efficient heat transfer is critical in designing heat management systems for various industrial applications, where the heat transfer rate may need to be increased or decreased to optimize heating or cooling processes. Additionally, the findings are significant because the wall material's thermal properties depend on the cooling or heating rates during the production of metal or polymer sheets. Radiative effects and viscous dissipation contribute to higher temperature distributions and the expansion of the thermal boundary layer. Radiation particularly enhances heat generation in fluids, increasing their temperature, especially at elevated temperatures where it directly impacts heat transfer and temperature distribution. In the boundary layer, where transport phenomena oppose each other, the magnetic field becomes the dominant factor. The study further demonstrates that an applied magnetic field increases the fluid temperature profile while reducing the rate of heat transfer through the walls.
ISSN:27053121
2705313X
DOI:10.4314/cajost.v7i1.15