Gust Loading Factor: New Model
Publication: Journal of Structural Engineering
Volume 127, Issue 2
Abstract
Wind loads on structures under the buffeting action of wind gusts have traditionally been treated by the “gust loading factor” (GLF) method in most major codes and standards around the world. In this scheme, the equivalent static wind loading used for design is equal to the mean wind force multiplied by the GLF. Although the traditional GLF method ensures an accurate estimation of the displacement response, it may fall short in providing a reliable estimate of other response components. To overcome this shortcoming, a more realistic procedure for determining design loads on tall structures is proposed. This paper highlights the new model, in which the GLF is based on the base bending moment rather than the displacement. The expected extreme base moment is computed by multiplying the mean base moment by the proposed GLF. The base moment is then distributed to each floor in terms of the floor load in a format that is very similar to the one used to distribute the base shear in earthquake engineering practice. In addition, a simple relationship between the proposed base moment GLF and the traditional GLF is derived, which makes it convenient to employ the proposed approach while utilizing the existing background information. Numerical examples are presented to demonstrate the efficacy of the proposed procedure in light of the traditional approach.
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Received: Feb 8, 2000
Published online: Feb 1, 2001
Published in print: Feb 2001
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