Significance of thermal stress in a convective-radiative annular fin with magnetic field and heat generation: application of DTM and MRPSM-Propulsion and Power Research
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Significance of thermal stress in a convective-radiative annular fin with magnetic field and heat generation: application of DTM and MRPSM

Author:Ganeshappa Sowmya, Fehmi Gamaoun, Amal Abdulrahman, Ravikumar Shashikala Varun Kumar, Ballajja Chan [Date]:2023-01-12 [Source]:317 [Click]:

Significance of thermal stress in a convective-radiative annular fin with magnetic field and heat generation: application of DTM and MRPSM

Ganeshappa Sowmya a, Fehmi Gamaoun b, Amal Abdulrahman c, Ravikumar Shashikala Varun Kumar d, Ballajja Chandrappa Prasannakumara d,*

a.Department of Mathematics, M S Ramaiah Institute of Technology, Bangalore-560054, Karnataka, 560070, India
         b.Department of Mechanical Engineering, College of Engineering, King Khalid University, Abha, 61421,
   Saudi Arabia
         c.Department of Chemistry, College of Science, King Khalid University, Abha, 61421, Saudi Arabia
         d.Department of Studies in Mathematics, Davangere University, Davangere, Karnataka, 577002, India

Abstract: The present paper explains the temperature attribute of a convective-radiative rectangular profiled annular fin with the impact of magnetic field. The effect of thermal radiation, convection, and magnetic field on thermal stress distribution is also studied in this investigation. The governing energy equation representing the steady-state heat conduction, convection, and radiation process is transformed into its dimensionless nonlinear ordinary differential equation (ODE) with corresponding boundary conditions using non-dimensional terms. The obtained ODE is then solved analytically by employing the Pade approximant-differential transform method (DTM) and modified residual power series method (MRPSM). Moreover, the important characteristics of the temperature field, the thermal stress, and the impact of some non-dimensional parameters are inspected graphically, and a physical explanation is provided to aid in comprehension. The significant findings of the investigation reveal that temperature distribution enhances with an increase in the magnitude of the heat generation parameter and thermal conductivity parameter, but it gradually decreases with an increment of convective-conductive parameter, Hartmann number, and radiative-conductive parameter. The thermal stress distribution of the fin varies considerably in the applied magnetic field effect.

Keywords: Annular fin; Differential transform method (DTM); Magnetic field; Modified residual power series method (MRPSM); Radiative heat transfer

https://doi.org/10.1016/j.jppr.2022.11.001