An isogeometric finite element formulation for boundary and shell viscoelasticity based on a multiplicative surface deformation split

Abstract: This work presents a numerical formulation to model isotropic viscoelastic material behavior for membranes and thin shells. The surface and the shell theory are formulated within a curvilinear coordinate system, which allows the representation of general surfaces and deformations. The kinematics follow from Kirchhoff-Love theory and the discretization makes use of isogeometric shape functions. A multiplicative split of the surface deformation gradient is employed, such that an intermediate surface configuratio… Show more

An isogeometric FSDT approach for the study of nonlinear vibrations in truncated viscoelastic conical shells

An isogeometric FSDT approach for the study of nonlinear vibrations in truncated viscoelastic conical shells

A simple and efficient hybrid discretization approach to alleviate membrane locking in isogeometric thin shells

A new anisotropic bending model for nonlinear shells: Comparison with existing models and isogeometric finite element implementation