论文信息 - Finite element dynamic analysis of geometrically exact planar beams

Finite element dynamic analysis of geometrically exact planar beams

We present a new strain-based finite element formulation for the dynamic analysis of highly flexible elastic planar beams. The formulation employs the geometrically exact Reissner planar beam theory which accounts for finite displacements and rotations, and finite membrane, shear and bending strains. The system of semi-discrete dynamic equations of motion is derived from the modified Hamilton principle in which only the strain variables are interpolated. Such a choice of the interpolated variables is an advantage over approaches, in which the displacements and rotations are interpolated, since the field consistency problem and related locking phenomena do not arise. The performance and accuracy of the formulation are illustrated by several numerical examples.

Matija Gams | Miran Saje | Igor Planinc | Stanislav Srpčič

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

[2] Peter Wriggers,et al. A finite element approach to the chaotic motion of geometrically exact rods undergoing in-plane deformations , 1996 .

[3] E. Stein,et al. An energy‐conserving planar finite beam element for dynamics of flexible mechanisms , 1996 .

[4] Adnan Ibrahimbegovic,et al. Nonlinear dynamics of flexible beams in planar motion: formulation and time-stepping scheme for stiff problems , 1999 .

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

[6] K. Hsiao,et al. Dynamic analysis of planar flexible mechanisms by co-rotational formulation , 1991 .

[7] M. Crisfield,et al. A co‐rotational element/time‐integration strategy for non‐linear dynamics , 1994 .

[8] Nathan M. Newmark,et al. A Method of Computation for Structural Dynamics , 1959 .

[9] Goran Turk,et al. A kinematically exact finite element formulation of planar elastic - plastic frames , 1997 .

[10] Miran Saje,et al. A consistent equilibrium in a cross-section of an elastic–plastic beam , 1999 .

[11] Miran Saje,et al. On the local stability condition in the planar beam finite element , 2001 .

[12] S. Atluri,et al. Dynamic analysis of planar flexible beams with finite rotations by using inertial and rotating frames , 1995 .