TWISTING STATICS AND DYNAMICS FOR CIRCULAR ELASTIC NANOSOLIDS BY NONLOCAL ELASTICITY THEORY |
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Authors: | Cheng Li C. W. Lim Jilin Yu |
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Affiliation: | 1School of Urban Rail Transportation, Soochow University, Suzhou 215006, China) (2Department of Building and Construction, City University of Hong Kong, Hong Kong, China) (3Department of Modern Mechanics, University of Science and Technology of China, Hefei 230026, China, and USTC-CityU Joint Advanced Research Center, Suzhou 215123, China) |
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Abstract: | The torsional static and dynamic behaviors of circular nanosolids such as nanoshafts, nanorods and nanotubes are established based on a new nonlocal elastic stress field theory. Based on a new expression for strain energy with a nonlocal nanoscale parameter, new higher-order governing equations and the corresponding boundary conditions are first derived here via the variational principle because the classical equilibrium conditions and/or equations of motion can- not be directly applied to nonlocal nanostructures even if the stress and moment quantities are replaced by the corresponding nonlocal quantities. The static twist and torsional vibration of circular, nonlocal nanosolids are solved and discussed in detail. A comparison of the conventional and new nonlocal models is also presented for a fully fixed nanosolid, where a lower-order governing equation and reduced stiffness are found in the conventional model while the new model reports opposite solutions. Analytical solutions and numerical examples based on the new nonlocal stress theory demonstrate that nonlocal stress enhances stiffness of nanosolids, i.e. the angular displacement decreases with the increasing nonlocal nanoscale while the natural frequency increases with the increasing nonlocal nanoscale. |
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Keywords: | angular displacement nanoscale nonlocal stress torsion vibration |
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