4.7 Article

An Axially Compressed Moving Nanobeam Based on the Nonlocal Couple Stress Theory and the Thermoelastic DPL Model

期刊

MATHEMATICS
卷 11, 期 9, 页码 -

出版社

MDPI
DOI: 10.3390/math11092155

关键词

nanobeams; nonlocality; DPL model; axial excitation; MCS model

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This article presents a new model for describing elastic thermal vibrations in elastic nanobeams caused by temperature changes. It uses nonlocal elasticity and the dual-phase lagging thermoelastic model to explain small-scale effects. The proposed theory is verified by studying the thermodynamic response of nanobeams subjected to a periodic thermal load. The numerical results show that the behavior of the thermal nanobeam changes with phase delay factors and the length scale parameter.
This article introduces a new model that can be used to describe elastic thermal vibrations caused by changes in temperature in elastic nanobeams in response to transverse external excitations. Using the idea of nonlocal elasticity and the dual-phase lagging thermoelastic model (DPL), the coupled equations of motion and heat transfer were derived to explain small-scale effects. Additionally, modified couple stress theory (MCST) and Euler-Bernoulli (EB) beam assumptions were considered. The proposed theory was verified by considering the thermodynamic response of nanobeams moving horizontally at a constant speed while one end is subjected to a periodic thermal load. The system of governing equations has been solved numerically with the help of Laplace transforms and one of the tested evolutionary algorithms. The effects of changing the nonlocal modulus, the magnitude of the external force, and the length scale parameter on the system fields were investigated. It is also shown how the behavior of the thermal nanobeam changes depending on the phase delay factors in addition to the horizontal velocity of the beam. To determine this model's accuracy, its results were compared with the results of the classical continuity model and thermoelastic concepts. The numerical results show that when the nanobeam moves, the length scale can change the studied thermal and mechanical vibration wave patterns and physical fields. Additionally, during thermally stimulated vibrations, thermodynamic effects that have implications for the dynamic design and performance improvement of nanostructures must be considered.

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