A high-precision curvature constrained Bernoulli–Euler planar beam element for geometrically nonlinear analysis

“…Recent studies have examined the performance of the developed elements under large rotations by solving this problem using meshes ranging from three up to a hundred of elements. 18,19 The exact solution to this problem is a circular arc with radius R = EI∕M. To deform the rod into a full closed circle, an end moment M = 2𝜋EI∕L needs to be applied.…”

“…The first test, serving as a benchmark, deals with a cantilever of length L and bending stiffness loaded by a concentrated end moment M on its right end. Recent studies have examined the performance of the developed elements under large rotations by solving this problem using meshes ranging from three up to a hundred of elements 18,19 . The exact solution to this problem is a circular arc with radius .…”

Efficient finite difference formulation of a geometrically nonlinear beam element

“…Recent studies have examined the performance of the developed elements under large rotations by solving this problem using meshes ranging from three up to a hundred of elements. 18,19 The exact solution to this problem is a circular arc with radius R = EI∕M. To deform the rod into a full closed circle, an end moment M = 2𝜋EI∕L needs to be applied.…”

“…The first test, serving as a benchmark, deals with a cantilever of length L and bending stiffness loaded by a concentrated end moment M on its right end. Recent studies have examined the performance of the developed elements under large rotations by solving this problem using meshes ranging from three up to a hundred of elements 18,19 . The exact solution to this problem is a circular arc with radius .…”

Efficient finite difference formulation of a geometrically nonlinear beam element

“…Then, the application range of their methods is limited. In addition, these elements [19][20][21][22][23][24][25] were all developed in an inertia coordinate system. The shape functions of these elements are used to ensure the continuity of the global displacement field and cannot take the constitutive relationship of the materials into account.…”

“…An element-independent framework is established by using the same shape functions to derive the nonlinear equations of motion of the element based on Hamilton's principle. In contrast with the curved beam elements [19][20][21][22][23][24][25][26][27][28] developed in the inertia coordinate system, the shape functions of the presented element are used to describe the local displacement field. Then, many standard elements, [5][6][7][8] developed based on exact solutions in a curvilinear coordinate system, can be embedded into the framework.…”

“…Doğruoğlu and Kömürcü 23 presented two mixed finite element formulations for the geometrically nonlinear analysis of planar curved beams. Zhang et al 24 developed a high‐precision curvature constrained beam element based on the gradient deficient beam elements of the ANCF. In recent years, Choi et al 25 developed a novel finite element formulation based on isogeometric analysis (IGA) 26 and GET to bridge the gap between computer‐aided design and finite element analysis.…”

A two‐dimensional corotational curved beam element for dynamic analysis of curved viscoelastic beams with large deformations and rotations

Efficiency improvement on the ANCF cable element by using the dot product form of curvature