This article examines the impact of radiation on the flow over a vertically rotating cone within a saturated non-Darcy Forchheimer porous medium. To facilitate the analysis, we nondimensionalized the governing equations for this specific geometry using prescribed transformations. The resulting equations were then solved using the BVP4C method. Our study involved obtaining solutions of the concentration of fluid profiles, their temperature and velocity while adhering to relevant physical boundary conditions. We explored the impact of velocities and thermal radiation by varying parameters such as the Darcy parameter, thermal Grashof number, and Forchheimer parameters graphically. Our observations indicated a significant influence on flow characteristics and heat transfer rates due to changes in these parameters. This research contributes to a better understanding of the complex interplay between radiation, porous media, and rotating geometries.

错误:搜索内容不能为空,请输入英文关键词
错误:关键词超出字数限制,请精简
高级检索

Natural Buoyancy Forces on Convection Radiative Nanofluid Flow Over a Vertically Rotating Cone in Nonlinear Darcy Medium

  • Nilam VenkataKoteswararao,
  • D. Harish Babu,
  • K. Sripriyan,
  • M. Xavier Suresh

摘要

This article examines the impact of radiation on the flow over a vertically rotating cone within a saturated non-Darcy Forchheimer porous medium. To facilitate the analysis, we nondimensionalized the governing equations for this specific geometry using prescribed transformations. The resulting equations were then solved using the BVP4C method. Our study involved obtaining solutions of the concentration of fluid profiles, their temperature and velocity while adhering to relevant physical boundary conditions. We explored the impact of velocities and thermal radiation by varying parameters such as the Darcy parameter, thermal Grashof number, and Forchheimer parameters graphically. Our observations indicated a significant influence on flow characteristics and heat transfer rates due to changes in these parameters. This research contributes to a better understanding of the complex interplay between radiation, porous media, and rotating geometries.