A locking-free finite element formulation and reduced models for geometrically exact Kirchhoff rods

In this work, we suggest a locking-free geometrically exact finite element formulation incorporating the modes of axial tension, torsion and bending of thin Kirchhoff beams with arbitrary initial curvatures and cross-section shapes. The proposed formulation has been designed in order to represent general load cases and three-dimensional problem settings in the geometrically nonlinear regime of large deformations. From this comprehensive theory, we not only derive a general beam model but also several reduced formulations, which deliver accurate solutions for special problem classes concerning the beam geometry and the external loads. The advantages of these reduced models arise for example in terms of simplified finite element formulations, less degrees of freedom per element and consequently a higher computational efficiency of the corresponding numerical models. A second core topic of this publication is the treatment of membrane locking, which is a locking phenomenon predominantly occurring in highly slender curved structures, thus, exactly in the prime field of application for Kirchhoff theories. In order to address the membrane locking effect, we will propose a new interpolation strategy for the axial strain field and compare this method with common approaches such as Assumed Natural Strains (ANS) or reduced integration. The effectiveness of this method as well as the consistency and accuracy of the general finite element formulation and the reduced beam models will be illustrated with selected numerical examples.

[1]  Ahmed K. Noor,et al.  Mixed models and reduced/selective integration displacement models for nonlinear analysis of curved beams , 1981 .

[2]  S. Antman Nonlinear problems of elasticity , 1994 .

[3]  Michel Géradin,et al.  Finite element theory for curved and twisted beams based on exact solutions for three-dimensional solids. Part 1: Beam concept and geometrically exact nonlinear formulation , 1998 .

[4]  J. C. Simo,et al.  On the Variational Foundations of Assumed Strain Methods , 1986 .

[5]  T. Belytschko,et al.  Membrane Locking and Reduced Integration for Curved Elements , 1982 .

[6]  E. Reissner On one-dimensional finite-strain beam theory: The plane problem , 1972 .

[7]  Yuri Bazilevs,et al.  Isogeometric rotation-free bending-stabilized cables: Statics, dynamics, bending strips and coupling with shells , 2013 .

[8]  J. C. Simo,et al.  A three-dimensional finite-strain rod model. Part II: Computational aspects , 1986 .

[9]  Gangan Prathap,et al.  The curved beam/deep arch/finite ring element revisited , 1985 .

[10]  E. Reissner On finite deformations of space-curved beams , 1981 .

[11]  Ignacio Romero,et al.  The interpolation of rotations and its application to finite element models of geometrically exact rods , 2004 .

[12]  H. Weiss,et al.  Dynamics of Geometrically Nonlinear Rods: II. Numerical Methods and Computational Examples , 2002 .

[13]  Alexander Tessler,et al.  Curved beam elements with penalty relaxation , 1986 .

[14]  Olivier Bruls,et al.  Geometrically exact beam finite element formulated on the special Euclidean group SE(3) , 2014 .

[15]  Christian J. Cyron,et al.  A torsion-free non-linear beam model , 2014 .

[16]  Gordan Jelenić,et al.  Geometrically exact 3D beam theory: implementation of a strain-invariant finite element for statics and dynamics , 1999 .

[17]  Pere Roca,et al.  A new deformable catenary element for the analysis of cable net structures , 2006 .

[18]  Rolf Stenberg,et al.  A stable bilinear element for the Reissner-Mindlin plate model , 1993 .

[19]  P. Frank Pai,et al.  Problems in geometrically exact modeling of highly flexible beams , 2014 .

[20]  I. Fried,et al.  Shape functions and the accuracy of arch finite elements. , 1973 .

[21]  Jang-Keun Lim,et al.  General curved beam elements based on the assumed strain fields , 1995 .

[22]  H. Weiss Dynamics of Geometrically Nonlinear Rods: I. Mechanical Models and Equations of Motion , 2002 .

[23]  Ignacio Romero,et al.  An objective finite element approximation of the kinematics of geometrically exact rods and its use in the formulation of an energy–momentum conserving scheme in dynamics , 2002 .

[24]  Debasish Roy,et al.  A frame-invariant scheme for the geometrically exact beam using rotation vector parametrization , 2009 .

[25]  Jose Manuel Valverde,et al.  Invariant Hermitian finite elements for thin Kirchhoff rods. II: The linear three-dimensional case , 2012 .

[26]  Hyo-Chol Sin,et al.  Locking‐free straight beam element based on curvature , 1993 .

[27]  J. Howard,et al.  Mechanics of Motor Proteins and the Cytoskeleton , 2001 .

[28]  G. Kirchhoff,et al.  Ueber das Gleichgewicht und die Bewegung eines unendlich dünnen elastischen Stabes. , 1859 .

[29]  Thomas J. R. Hughes,et al.  A simple and efficient finite element for plate bending , 1977 .

[30]  Frank Koschnick Geometrische Locking-Effekte bei Finiten Elementen und ein allgemeines Konzept zu ihrer Vermeidung , 2004 .

[31]  Peter Betsch,et al.  Director‐based beam finite elements relying on the geometrically exact beam theory formulated in skew coordinates , 2014 .

[32]  Frédéric Boyer,et al.  Finite element of slender beams in finite transformations: a geometrically exact approach , 2004 .

[33]  M. Crisfield,et al.  Objectivity of strain measures in the geometrically exact three-dimensional beam theory and its finite-element implementation , 1999, Proceedings of the Royal Society of London. Series A: Mathematical, Physical and Engineering Sciences.

[34]  Gangan Prathap,et al.  Analysis of locking and stress oscillations in a general curved beam element , 1990 .

[35]  Martin Arnold,et al.  Pantograph and catenary dynamics: a benchmark problem and its numerical solution , 2000 .

[36]  Debasish Roy,et al.  Consistent quaternion interpolation for objective finite element approximation of geometrically exact beam , 2008 .

[37]  Luisa Molari,et al.  A mixed stress model for linear elastodynamics of arbitrarily curved beams , 2008 .

[38]  Cv Clemens Verhoosel,et al.  Non-Linear Finite Element Analysis of Solids and Structures , 1991 .

[39]  Ignacio Romero,et al.  A comparison of finite elements for nonlinear beams: the absolute nodal coordinate and geometrically exact formulations , 2008 .

[40]  A. B. Sabir,et al.  Further studies in the application of curved finite elements to circular arches , 1971 .

[41]  Jose Manuel Valverde,et al.  Invariant Hermitian finite elements for thin Kirchhoff rods. I: The linear plane case ☆ , 2012 .

[42]  Oliver Sander,et al.  Geodesic finite elements for Cosserat rods , 2009 .

[43]  Wolfgang A. Wall,et al.  Numerical method for the simulation of the Brownian dynamics of rod‐like microstructures with three‐dimensional nonlinear beam elements , 2012 .

[44]  Damien Durville,et al.  Simulation of the mechanical behaviour of woven fabrics at the scale of fibers , 2010 .

[45]  A. Love A treatise on the mathematical theory of elasticity , 1892 .

[46]  Miran Saje,et al.  Finite-element formulation of geometrically exact three-dimensional beam theories based on interpolation of strain measures , 2003 .

[47]  Wolfgang A. Wall,et al.  An objective 3D large deformation finite element formulation for geometrically exact curved Kirchhoff rods , 2014 .

[48]  Leopoldo Greco,et al.  B-Spline interpolation of Kirchhoff-Love space rods , 2013 .

[49]  D. G. Ashwell,et al.  Limitations of certain curved finite elements when applied to arches , 1971 .

[50]  J. C. Simo,et al.  A finite strain beam formulation. The three-dimensional dynamic problem. Part I , 1985 .

[51]  Dimitrios Karamanlidis,et al.  Curved mixed beam elements for the analysis of thin-walled free-form arches , 1987 .