Heat transfer modelling in an annular disc under heating and cooling processes with stress analysis

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ORIGINAL PAPER

Heat transfer modelling in an annular disc under heating and cooling processes with stress analysis

Indrajeet Varhadpande ¹

,

VRK Murty ¹

,

Navneet Kumar Lamba ²

1

Mathematics, Department of S & H, VIGNAN’S Foundation for Science, Technology & Research, Guntur, A.P., India

2

Mathematics, Shri Lemdeo Patil Mahavidyalaya, Mandhal, India

These authors had equal contribution to this work

Submission date: 2024-01-19

Final revision date: 2024-02-17

Acceptance date: 2024-04-11

Publication date: 2024-09-12

Corresponding author

Navneet Kumar Lamba

Mathematics, Shri Lemdeo Patil Mahavidyalaya, Mandhal, Nagpur, 441210, Mandhal, India

International Journal of Applied Mechanics and Engineering 2024;29(3):166-181

DOI: https://doi.org/10.59441/ijame/187052

References (40)

KEYWORDS

integral transform

Memory related derivatives

heating and cooling process

stress functions

TOPICS

mechanics of structures

material science

materials engineering

ABSTRACT

The goal of this effort is to determine the interaction among the heating and cooling processes in order to understand how solids behave when subjected to temperature changes. In this instance, the temperature, displacement, and stress relations are determined analytically and numerically while a thin annular disc is subjected to both the heating and cooling processes. The ability of a material to withstand stress is essential for the design of diverse mechanical structures that aim to enhance performance, durability, characteristics, and strength. This ability is demonstrated in many physical processes where the material structure crosses over into heating and cooling processes. Furthermore, memory derivatives used in the modelling of heat transfer equations more accurately depict the memory behaviour of an imagined disc and explain its physical significance.

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