A smeared crack modeling framework accommodating multi-directional fracture at finite strains

• Published in: International journal of fracture Vol. 239; no. 1; pp. 87 - 109
• Main Authors: Giffin, Brian D., Zywicz, Edward
• Format: Journal Article
• Language: English
• Published: Dordrecht Springer Netherlands 01.01.2023; Springer Nature B.V
• Subjects: Automotive Engineering; Characterization and Evaluation of Materials; Civil Engineering; Classical Mechanics; Crack opening displacement; Engineering; Equations of motion; Equilibrium; Equilibrium conditions; Failure surface; Frictionless contact; Mathematical models; Mechanical Engineering; Modelling; Nonlinear systems; Original Research; Time integration; Traction; Smeared crack approach; Continuum damage mechanics; Dynamic fracture; Finite deformation; Cohesive-zone model
• ISSN: 0376-9429; 1573-2673
• DOI: 10.1007/s10704-022-00665-9

A generic smeared crack modeling framework predicated on the deformation gradient decomposition (DGD) approach is proposed for use in dynamic fracture problems at finite strains, accommodating failure along multiple mutually orthogonal fracture planes embedded within an independently defined bulk material model. Within this constitutive framework, the traction equilibrium conditions imposed at each failure surface are used to determine the associated crack displacements stored as internal state variables. In general, the enforcement of interfacial equilibrium entails the implicit solution of a non-linear system of equations within the constitutive update procedure. However, if inertial effects arising due to the relative motion of the fractured material are incorporated within the model, the traction equilibrium conditions are shown to give rise to corresponding dynamic equations of motion governing the time-evolution of the crack opening displacements. For dynamic problems, an explicit time-integration procedure is devised to efficiently update the material state, subject to a set of internal frictionless contact constraints to prevent material inversion. The efficacy of the proposed modeling framework is investigated through several benchmark dynamic fracture problems run within the explicit finite element code DYNA3D.