Homogeneous stress–strain states computed by 3D-stress algorithms of FE-codes: application to material parameter identification

• Published in: Engineering with computers Vol. 31; no. 1; pp. 141 - 159
• Main Authors: Krämer, Stephan, Rothe, Steffen, Hartmann, Stefan
• Format: Journal Article
• Language: English
• Published: London Springer London 01.01.2015; Springer Nature B.V
• Subjects: Algorithms; CAE) and Design; Calculus of Variations and Optimal Control; Optimization; Classical Mechanics; Computer Science; Computer-Aided Engineering (CAD; Control; Finite element method; Math. Applications in Chemistry; Mathematical analysis; Mathematical and Computational Engineering; Mathematical models; Original Article; Parameter identification; Stress-strain relationships; Stresses; Systems Theory; Three dimensional; Finite elements; DAE-systems; Stress algorithms; Plane stress; Material parameter identification
• ISSN: 0177-0667; 1435-5663
• DOI: 10.1007/s00366-013-0337-7

In view of code verification of finite element implementations and for material parameter identification purposes it is of interest to make use of stress algorithms developed for three-dimensional finite element computations. In the case of homogeneous deformations various boundary-conditions for given displacements or stresses are possible and define a sub-problem of three-dimensional stress–strain states, which are either one-, two- or three-dimensional. Examples are uniaxial tension/compression, plane stress conditions or biaxial tensile problems. Caused by the fact that the stress algorithms are strain-driven, the constraints of zero stresses in a specific direction lead for elastic and inelastic constitutive models to a particular system of differential-algebraic equations. How to treat such stress algorithms and how to solve the resulting system of differential-algebraic equations, which are developed for finite element programs, for specific stress and displacement boundary conditions is discussed in this article. Additionally, it is worked out that the consistent tangent operator is required in the same manner as in 3D-FE computations. The second topic treats the extension of the entire procedure for material parameter identification procedure applied to test data for different materials such as steel, rubber material and powder. In this respect, uniaxial tensile, biaxial tensile tests, and laterally constrained loading paths are exemplarily investigated. These investigations and the proposed procedure are applied for small and finite strain problems. In this investigation measure of the quality of identification is discussed as well.