A hybrid-mixed finite element formulation for the geometrically exact analysis of three-dimensional framed structures

This paper addresses the development of a hybrid-mixed finite element formulation for the quasi-static geometrically exact analysis of three-dimensional framed structures with linear elastic behavior. The formulation is based on a modified principle of stationary total complementary energy, involving, as independent variables, the generalized vectors of stress-resultants and displacements and, in addition, a set of Lagrange multipliers defined on the element boundaries. The finite element discretization scheme adopted within the framework of the proposed formulation leads to numerical solutions that strongly satisfy the equilibrium differential equations in the elements, as well as the equilibrium boundary conditions. This formulation consists, therefore, in a true equilibrium formulation for large displacements and rotations in space. Furthermore, this formulation is objective, as it ensures invariance of the strain measures under superposed rigid body rotations, and is not affected by the so-called shear-locking phenomenon. Also, the proposed formulation produces numerical solutions which are independent of the path of deformation. To validate and assess the accuracy of the proposed formulation, some benchmark problems are analyzed and their solutions compared with those obtained using the standard two-node displacement/ rotation-based formulation.

[1]  Paulo M. Pimenta,et al.  Hybrid and multi-field variational principles for geometrically exact three-dimensional beams , 2010 .

[2]  Jean-Louis Batoz,et al.  On the role of geometrically exact and second-order theories in buckling and post-buckling analysis of three-dimensional beam structures , 1996 .

[3]  K. Washizu Variational Methods in Elasticity and Plasticity , 1982 .

[4]  Gao Yang,et al.  Rate variational extremum principles for finite elastoplasticity , 1990 .

[5]  D. White,et al.  A mixed finite element for three-dimensional nonlinear analysis of steel frames , 2004 .

[6]  H. Ziegler Principles of structural stability , 1968 .

[7]  E.A.W. Maunder A composite triangular equilibrium element for the flexural analysis of plates , 1986 .

[8]  S. Atluri,et al.  Stability analysis of structures via a new complementary energy method , 1981 .

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

[10]  P. Pimenta Geometrically exact analysis of initially curved rods , 1996 .

[11]  Base force element method of complementary energy principle for large rotation problems , 2009 .

[12]  Dinar Camotim,et al.  On the differentiation of the Rodrigues formula and its significance for the vector‐like parameterization of Reissner–Simo beam theory , 2002 .

[13]  David Yang Gao,et al.  Complementary finite-element method for finite deformation nonsmooth mechanics , 1996 .

[14]  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 .

[15]  Miran Saje,et al.  The quaternion-based three-dimensional beam theory , 2009 .

[16]  S. Atluri,et al.  Primal and mixed variational principles for dynamics of spatial beams , 1996 .

[17]  S. Atluri,et al.  On a consistent theory, and variational formulation of finitely stretched and rotated 3-D space-curved beams , 1988 .

[18]  Alex H. Barbat,et al.  Static analysis of beam structures under nonlinear geometric and constitutive behavior , 2007 .

[19]  D. W. Scharpf,et al.  On large displacement-small strain analysis of structures with rotational degrees of freedom , 1978 .

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

[21]  O. C. Holister,et al.  Stress Analysis , 1965 .

[22]  Satya N. Atluri,et al.  On Some New General and Complementary Energy Theorems for the Rate Problems in Finite Strain. Classical Elastoplasticity , 1980 .

[23]  Miran Saje,et al.  The three-dimensional beam theory: Finite element formulation based on curvature , 2001 .

[24]  Robert L. Taylor,et al.  On the role of frame-invariance in structural mechanics models at finite rotations , 2002 .

[25]  M. Géradin,et al.  Flexible Multibody Dynamics: A Finite Element Approach , 2001 .

[26]  K. Spring Euler parameters and the use of quaternion algebra in the manipulation of finite rotations: A review , 1986 .

[27]  J. C. Simo,et al.  On the Dynamics of Flexible Beams Under Large Overall Motions—The Plane Case: Part II , 1986 .

[28]  Magdi Mohareb,et al.  Buckling analysis of thin-walled open members—A finite element formulation , 2008 .

[29]  A variational principle for finite planar deformation of straight slender elastic beams , 1990 .

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

[31]  D. Gao Duality Principles in Nonconvex Systems , 2000 .

[32]  Paulo M. Pimenta,et al.  Geometrically Exact Analysis of Spatial Frames , 1993 .

[33]  M. Iura,et al.  A consistent theory of finite stretches and finite rotations, in space-curved beams of arbitrary cross-section , 2001 .

[34]  B. D. Veubeke Displacement and equilibrium models in the finite element method , 1965 .

[35]  D. Zupan,et al.  Rotational invariants in finite element formulation of three-dimensional beam theories , 2002 .

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

[37]  R. Ogden,et al.  Inequalities associated with the inversion of elastic stress-deformation relations and their implications , 1977, Mathematical Proceedings of the Cambridge Philosophical Society.

[38]  Continuity conditions for finite element analysis of solids , 1992 .

[39]  M. Géradin,et al.  A beam finite element non‐linear theory with finite rotations , 1988 .

[40]  S. Atluri,et al.  Finite Elasticity Solutions Using Hybrid Finite Elements Based on a Complementary Energy Principle—Part 2: Incompressible Materials , 1979 .

[41]  Rakesh K. Kapania,et al.  On a geometrically exact curved/twisted beam theory under rigid cross-section assumption , 2003 .

[42]  Alf Samuelsson,et al.  Finite Elements in Nonlinear Mechanics , 1978 .

[43]  D. Gao Duality Principles in Nonconvex Systems: Theory, Methods and Applications , 2000 .

[44]  Rakesh K. Kapania,et al.  A formulation and implementation of geometrically exact curved beam elements incorporating finite strains and finite rotations , 2003 .

[45]  J. P. Moitinho de Almeida,et al.  Equilibrium-Based Finite-Element Formulation for the Geometrically Exact Analysis of Planar Framed Structures , 2010 .

[46]  S. Atluri,et al.  Analysis of flexible multibody systems with spatial beams using mixed variational principles , 1998 .

[47]  A. Ibrahimbegovic,et al.  Variational principles and membrane finite elements with drilling rotations for geometrically non-linear elasticity , 1995 .

[48]  Bernt Jakobsen,et al.  The Sleipner accident and its causes , 1994 .

[49]  A. Ibrahimbegovic,et al.  Computational aspects of vector-like parametrization of three-dimensional finite rotations , 1995 .

[50]  Gangan Prathap,et al.  Reduced integration and the shear-flexible beam element , 1982 .

[51]  A. Ibrahimbegovic,et al.  Finite element analysis of linear and non‐linear planar deformations of elastic initially curved beams , 1993 .

[52]  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.

[53]  S. Atluri,et al.  On newly developed assumed stress finite element formulations for geometrically and materially nonlinear problems , 1995 .

[54]  G. Strang,et al.  Dual extremum principles in finite deformation elastoplastic analysis , 1989 .

[55]  Alberto Cardona,et al.  A nonlinear beam element formulation in the framework of an energy preserving time integration scheme for constrained multibody systems dynamics , 2008 .

[56]  H. Santos,et al.  Dual extremum principles for geometrically exact finite strain beams , 2011 .

[57]  Dinar Camotim,et al.  Work-conjugacy between rotation-dependent moments and finite rotations , 2003 .

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

[59]  Goran Turk,et al.  A kinematically exact finite element formulation of elastic–plastic curved beams , 1998 .

[60]  S. Timoshenko Theory of Elastic Stability , 1936 .

[61]  E. Reissner,et al.  On One‐Dimensional Large‐Displacement Finite‐Strain Beam Theory , 1973 .

[62]  Pierre Beckers,et al.  Dual analysis with general boundary conditions , 1995 .

[63]  M. Saje Finite element formulation of finite planar deformation of curved elastic beams , 1991 .

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

[65]  P. Betsch,et al.  Frame‐indifferent beam finite elements based upon the geometrically exact beam theory , 2002 .

[66]  D. W. Scharpf,et al.  Finite element method — the natural approach , 1979 .

[67]  S. Atluri,et al.  Dynamic analysis of finitely stretched and rotated three-dimensional space-curved beams , 1988 .

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

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

[70]  Miran Saje,et al.  A quadratically convergent algorithm for the computation of stability points: The application of the determinant of the tangent stiffness matrix , 1999 .

[71]  J. Mäkinen Total Lagrangian Reissner's geometrically exact beam element without singularities , 2007 .

[72]  H. Bufler Conservative systems, potential operators and tangent stiffness: reconsideration and generalization , 1993 .

[73]  S. Atluri,et al.  Finite Elasticity Solutions Using Hybrid Finite Elements Based on a Complementary Energy Principle , 1978 .

[74]  A. Ibrahimbegovic On finite element implementation of geometrically nonlinear Reissner's beam theory: three-dimensional curved beam elements , 1995 .

[75]  J. C. Simo,et al.  A Geometrically-exact rod model incorporating shear and torsion-warping deformation , 1991 .

[76]  J. P. Moitinho de Almeida,et al.  Alternative approach to the formulation of hybrid equilibrium finite elements , 1991 .

[77]  E. Stein,et al.  On the parametrization of finite rotations in computational mechanics: A classification of concepts with application to smooth shells , 1998 .