Effect of Material and Geometry Variations on Beam under Patch Loading
Publication: Journal of Structural Engineering
Volume 127, Issue 8
Abstract
This work was initiated to study the influence of geometry and material variations on the structural response of an aluminum I-beam subjected to concentrated loading. The beam behavior was computed with a previously validated LS-DYNA model, and an analytical response surface expression for the maximum load capacity was established. The deviation between the response surface estimate and the numerical analysis result was within 1.1%, and <0.35% in the most interesting parameter range. The probability distributions of all the material parameters, the thicknesses, and the geometrical imperfections were established on measurements from former works, and the code PROBAN was used to evaluate the influence of variability in the model parameters. It was found practical to separate two different cases: (1) one reflecting the variation occurring in a certain extrusion; and (2) the other indicating the scatter in a random batch. The first case was shown to give 20% higher design capacity indicating that it may be attractive to improve the control of the production process.
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Received: Apr 19, 2000
Published online: Aug 1, 2001
Published in print: Aug 2001
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