Open AccessSteady thermal stress and strain rates in a rotating circular cylinder under steady state temperature
Author(s) -
Pankaj Thakur
Publication year - 2012
Publication title -
thermal science
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.339
H-Index - 43
eISSN - 2334-7163
pISSN - 0354-9836
DOI - 10.2298/tsci110318079p
Subject(s) - cylinder , materials science , compressibility , creep , stress (linguistics) , steady state (chemistry) , mechanics , thermal , strain (injury) , composite material , thermodynamics , physics , geometry , chemistry , medicine , linguistics , philosophy , mathematics
Thermal stress and strain rates in a thick walled rotating cylinder under steady state temperature has been derived by using Seth’s transition theory. For elastic-plastic stage, it is seen that with the increase of temperature, the cylinder having smaller radii ratios requires lesser angular velocity to become fully plastic as compared to cylinder having higher radii ratios The circumferential stress becomes larger and larger with the increase in temperature. With increase in thickness ratio stresses must be decrease. For the creep stage, it is seen that circumferential stresses for incompressible materials maximum at the internal surface as compared to compressible material, which increase with the increase in temperature and measure n
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