Litcius/Paper detail

Higher-gradient and micro-inertia contributions on the mechanical response of composite beam structures

Mohammad Ayad, Nikolaos Karathanasopoulos, Jean‐François Ganghoffer, Hassan Lakiss

2020International Journal of Engineering Science40 citationsDOIOpen Access PDF

Abstract

In the current work, we study the role of higher-order and micro-inertia contributions on the mechanical behavior of composite structures. To that scope, we compute the complete set of the effective static and dynamic properties of composite beam structures using a higher-order dynamic homogenization method which incorporates micro-inertia effects. We consider different inner composite element designs, with material constituents that are of relevance for current engineering practice. Thereupon, we compute the effective static longitudinal higher-gradient response, quantifying the relative difference with respect to the commonly employed, Cauchy-mechanics formulation. We observe that within the static analysis range, higher-order effects require high internal length values and highly non-linear strain profile distributions for non-negligible higher-order effects to appear. We subsequently analyze the longitudinal, higher-gradient eigenfrequency properties of composite structural members, accounting for the role of micro-inertia contributions. Thereupon, we derive analytical expressions that relate the composite material's effective constitutive parameters with its macroscale vibration characteristics. We provide for the first-time evidence that micro-inertia contributions can counteract the effect of second-gradient properties on the eigenfrequencies of the structure, with their relative significance to depend on the mode of interest. What is more, we show that the internal length plays a crucial role in the significance of micro-inertia contributions, with their effect to be substantial for low, rather than for high internal length values, thus for a wide range of materials used in engineering practice.

Topics & Concepts

InertiaHomogenization (climate)MechanicsComposite numberCauchy distributionMoment of inertiaContinuum mechanicsMaterials scienceVibrationClassical mechanicsMathematicsPhysicsMathematical analysisComposite materialAcousticsBiodiversityBiologyEcologyNonlocal and gradient elasticity in micro/nano structuresComposite Structure Analysis and OptimizationComposite Material Mechanics