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A computationally tractable framework for nonlinear dynamic multiscale modeling of membrane woven fabrics

Philip Avery, Daniel Z. Huang, Wanli He, Johanna Ehlers, Armen Derkevorkian, Charbel Farhat

2021International Journal for Numerical Methods in Engineering23 citationsDOIOpen Access PDF

Abstract

Abstract A general‐purpose computational homogenization framework is proposed for the nonlinear dynamic analysis of membranes exhibiting complex microscale and/or mesoscale heterogeneity characterized by in‐plane periodicity that cannot be effectively treated by a conventional method, such as woven fabrics. The framework is a generalization of the “finite element squared” (or FE 2 ) method in which a localized portion of the periodic subscale structure is modeled using finite elements. The numerical solution of displacement driven problems involving this model can be adapted to the context of membranes by a variant of the Klinkel–Govindjee method 1 originally proposed for using finite strain, three‐dimensional material models in beam and shell elements. This approach relies on numerical enforcement of the plane stress constraint and is enabled by the principle of frame invariance. Computational tractability is achieved by introducing a regression‐based surrogate model informed by a physics‐inspired training regimen in which FE 2 is utilized to simulate a variety of numerical experiments including uniaxial, biaxial and shear straining of a material coupon. Several alternative surrogate models are evaluated including an artificial neural network. The framework is demonstrated and validated for a realistic Mars landing application involving supersonic inflation of a parachute canopy made of woven fabric.

Topics & Concepts

Microscale chemistryFinite element methodHomogenization (climate)Nonlinear systemMultiscale modelingComputer scienceDiscretizationHyperelastic materialGalerkin methodContext (archaeology)Numerical analysisTrussSolverSupersonic speedLevel set methodShell (structure)Surrogate modelApplied mathematicsMathematical optimizationAlgorithmStructural engineeringDisplacement (psychology)Mesoscale meteorologyMathematicsComputational mechanicsBoundary value problemvon Mises yield criterionFrame (networking)Computational fluid dynamicsContinuum mechanicsComposite Material MechanicsComposite Structure Analysis and OptimizationNonlocal and gradient elasticity in micro/nano structures
A computationally tractable framework for nonlinear dynamic multiscale modeling of membrane woven fabrics | Litcius