In this research, the size-dependent static behaviour of elastic curved stubby beams is investigated by Timoshenko kinematics. Stress-driven two-phase integral elasticity is adopted to model size effects which soften or stiffen classical local responses. The corresponding governing equations of nonlocal elasticity are established and discussed, non-classical boundary conditions are detected and an effective coordinate-free solution procedure is proposed. The presented mixture approach is elucidated by solving simple curved small-scale beams of current interest in Nanotechnology. The contributed results could be useful for design and optimization of modern sensors and actuators.
Stress-driven two-phase integral elasticity for Timoshenko curved beams / Vaccaro, M. S.; Pinnola, F. P.; Marotti de Sciarra, F.; Canadija, M.; Barretta, R.. - In: PROCEEDINGS OF THE INSTITUTION OF MECHANICAL ENGINEERS. JOURNAL OF NANOMATERIALS, NANOENGINEERING AND NANOSYSTEMS. - ISSN 2397-7914. - 235:1-2(2021), pp. 52-63. [10.1177/2397791421990514]
Stress-driven two-phase integral elasticity for Timoshenko curved beams
Vaccaro M. S.;Pinnola F. P.;Marotti de Sciarra F.;Barretta R.
2021
Abstract
In this research, the size-dependent static behaviour of elastic curved stubby beams is investigated by Timoshenko kinematics. Stress-driven two-phase integral elasticity is adopted to model size effects which soften or stiffen classical local responses. The corresponding governing equations of nonlocal elasticity are established and discussed, non-classical boundary conditions are detected and an effective coordinate-free solution procedure is proposed. The presented mixture approach is elucidated by solving simple curved small-scale beams of current interest in Nanotechnology. The contributed results could be useful for design and optimization of modern sensors and actuators.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
