Autori: Barretta Raffaele, Faghidian S. Ali, Luciano Raimonso, Medaglia Carlo Maria, Penna Rosa

Editore: Elsevier

Tipologia Prodotto: Contributo in rivista – Articolo scientifico (Article)

DOI: http://dx.doi.org/10.1016/j.compositesb.2018.02.020

Titolo della Rivista: COMPOSITES. PART B, ENGINEERING

Numero; Volume: 145

Numero prima e ultima pagina: 62 – 69

Codice ISSN: 1359-8368

Anno di Pubblicazione: 2018

Link: https://www.sciencedirect.com/science/article/abs/pii/S1359836818301264

Abstract:

Size-dependent structural behavior of nano-beams under torsion is investigated by two-phase integral elasticity. An effective torsional model is proposed by convexly combining the purely nonlocal integral stress-driven relation with a local phase. Unlike Eringen’s strain-driven mixture, the projected model does not exhibit singular behaviors and leads to well-posed elastostatic problems in all cases of technical interest. The new theory is illustrated by studying torsional responses of cantilever and doubly-clamped nano-beams under simple loading conditions. Specifically, the integral convolution of the two-phase mixture is done by considering the special bi-exponential kernel. With this choice, the stress-driven two-phase model is shown to be equivalent to a differential problem equipped with higher-order constitutive boundary conditions. Exact solutions are established and comparisons with pertinent results obtained by the Eringen strain-driven two-phase mixture and by the strain gradient theory of elasticity are carried out. The outcomes could be useful for the design and optimization of nano-devices and provide new benchmarks for numerical analyses.

Keywords: Torsion; Nonlocal integral elasticity; Mixtures; Nano-beams; Size effects; Hellinger-Reissner variational principle; Analytical modeling

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