Litcius/Paper detail

Elasticity problems of beams on reaction-driven nonlocal foundation

Francesco Paolo Pinnola, Marzia Sara Vaccaro, Raffaele Barretta, Francesco Marotti de Sciarra, Giuseppe Ruta

2022Archive of Applied Mechanics16 citationsDOIOpen Access PDF

Abstract

Abstract A challenging task in nonlocal continuum mechanics consists in formulating constitutive relations leading to well-posed structural problems. Several strategies have been adopted to overcome issues inherent applicability of Eringen’s pure nonlocal theory to nanostructures, such as local/nonlocal mixtures of elasticity and integral models involving modified averaging kernels. These strategies can be applied to the ill-posed problem of flexure of a beam on Wieghardt nonlocal foundation without considering any fictitious boundary forces of constitutive type. A consistent formulation of nonlocal elastic foundation underlying a Bernoulli–Euler beam is thus conceived in the present paper by requiring that transverse displacements are convex combination of reaction-driven local and nonlocal phases governed by Winkler and Wieghardt laws, respectively. The proposed integral mixture is proven to be equivalent to a more convenient differential problem, equipped with nonlocal boundary conditions, which can be effectively exploited to solve nonlocal problems of beams resting on mixture reaction-driven continuous foundation. Effectiveness of the developed nonlocal approach is illustrated by analytically solving simple elasto-static problems of structural mechanics.

Topics & Concepts

Boundary value problemElasticity (physics)Euler's formulaConstitutive equationMathematicsBeam (structure)Continuum mechanicsRegular polygonClassical mechanicsMathematical analysisApplied mathematicsPhysicsStructural engineeringGeometryFinite element methodEngineeringThermodynamicsNonlocal and gradient elasticity in micro/nano structuresNumerical methods in engineeringComposite Structure Analysis and Optimization