Title: Non-prismatic Timoshenko-like beam model: Numerical solution via isogeometric collocation
Language: English
Authors: Balduzzi, Giuseppe
Morganti, Simone 
Auricchio, Ferdinando
Reali, Alessandro 
Category: Research Article
Forschungsartikel
Keywords: Non-prismatic beams; Tapered beams; Isogeometric analysis; Mixed collocation methods; B-splines
Issue Date: 2017
Journal: Computers and Mathematics with Applications
Abstract: 
The present paper combines an effective beam theory with a simple and accurate numerical technique opening the door to the prediction of the structural behavior of planar beams characterized by a continuous variation of the cross-section geometry, that in general deeply influences the stress distribution and, therefore, leads to non-trivial constitutive relations. Accounting for these peculiar aspects, the beam theory is described by a mixed formulation of the problem represented by six linear Ordinary Differential Equations (ODEs) with non-constant coefficients depending on both the cross-section displacements and the internal forces. Due to the ODEs’ complexity, the solution can be typically computed only numerically also for relatively simple geometries, loads, and boundary conditions; however, the use of classical numerical tools for this problem, like a (six-field) mixed finite element approach, might entail several issues (e.g., shear locking, ill-conditioned matrices, etc.). Conversely, the recently proposed isogeometric collocation method, consisting of the direct discretization of the ODEs in strong form and using the higher-continuity properties typical of spline shape functions, allows an equal order approximation of all unknown fields, without affecting the stability of the solution. This makes such an approach simple, robust, efficient, and particularly suitable for solving the system of ODEs governing the non-prismatic beam problem. Several numerical experiments confirm that the proposed mixed isogeometric collocation method is actually cost-effective and able to attain high accuracy.
DOI: 10.1016/j.camwa.2017.04.025
Library ID: AC11362481
URN: urn:nbn:at:at-ubtuw:3-3008
ISSN: 0898-1221
Organisation: E202 - Institut für Mechanik der Werkstoffe und Strukturen 
Publication Type: Article
Artikel
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