Accession Number : AD1016225


Title :   Predictive Simulation of Material Failure Using Peridynamics -- Advanced Constitutive Modeling, Verification and Validation


Descriptive Note : Technical Report,01 Apr 2014,31 Mar 2016


Corporate Author : University of Texas at San Antonio San Antonio United States


Personal Author(s) : Foster,John T ; O'Grady,James ; Millwater,Harry


Full Text : https://apps.dtic.mil/dtic/tr/fulltext/u2/1016225.pdf


Report Date : 31 Mar 2016


Pagination or Media Count : 121


Abstract : Peridynamics is a nonlocal formulation of continuum mechanics in which forces are calculated as integral functions of displacement fields rather than spatial derivatives. The peridynamic model has major advantages over classical continuum mechanics when displacements are discontinuous, such as in the case of material failure. While multiple peridynamic material models capture the behavior of solid materials, not all structures are conveniently analyzed as solids. Finite Element Analysis often uses 1D and 2D elements to model thin features that would otherwise require a great number of 3D elements, but peridynamic thin features remain underdeveloped despite great interest in the engineering community. This work develops nonordinary state-based peridynamic models for the simulation of thin features. Beginning from an example nonordinary state-based model, lower dimensional peridynamic models of plates, beams, and shells are developed and validated against classical models. These peridynamic models are extended to incorporate brittle and plastic material failure, compounding the peridynamic ad- vantages of discontinuity handling with the computational simplicity of reduced- dimension features. These models will allow peridynamic modeling of complex structures such as aircraft skin that may experience damage from internal forces or external impacts.


Descriptors :   predictive modeling , continuum mechanics , failure (mechanics) , numerical analysis , Verification , Validation


Subject Categories : Theoretical Mathematics
      Operations Research
      Mechanics


Distribution Statement : APPROVED FOR PUBLIC RELEASE