Analysis and stiffeners' design of a steel bridge girder

Journal of Structural Engineering & Applied Mechanics Pub Date : 2022-09-30 DOI:10.31462/jseam.2022.03181196

Tuğçe Sevil Yaman

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Abstract

Plate girders are designed to carry massive loads over large spans. Flanges resist moment and web resists shear forces. Shear strength of steel girders having slender webs is much less than the yielding shear capacity. It is mainly due to the buckling of the web prior to reaching the yield strength of the material. Webs are generally reinforced with transverse stiffeners to increase their buckling strength. Stiffened webs resist shear also after buckling, which is called as post buckling strength. Tension field theories explain the formation of the post buckling strength and predict the stiffened web’s ultimate shear strength. Most design code provisions are set on tension field theories. There exists plenty of tension field theories proposed until today. This paper covers the design shear strength check and design flexural strength check and the stiffeners’ design of a steel girder specimen which was designed intentionally to fail in shear buckling. Analysis and stiffeners’ design were performed according to the provisions for load and resistance factor design (LRFD) in the ANSI/American Institute of Steel Construction (AISC) 360-16 - Specification for Structural Steel Buildings.

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某钢桥主梁的分析与加劲设计

板梁的设计是为了在大跨度上承载巨大的荷载。法兰抗弯矩，腹板抗剪力。细长腹板钢梁的抗剪强度远小于屈服抗剪能力。这主要是由于腹板在达到材料屈服强度之前发生屈曲。腹板一般采用横向加强筋来提高其屈曲强度。加劲腹板在屈曲后也能抵抗剪切，称为屈曲后强度。张力场理论解释了后屈曲强度的形成，并预测了加筋腹板的极限抗剪强度。大多数设计规范的规定是建立在张力场理论的基础上的。迄今为止，存在着大量的张力场理论。本文介绍了设计抗剪强度校核和设计抗弯强度校核以及故意设计为抗剪屈曲破坏的钢梁试件的加强筋设计。根据ANSI/美国钢结构协会(AISC) 360-16 -钢结构建筑规范中荷载和阻力系数设计(LRFD)的规定进行分析和加强筋设计。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal of Structural Engineering & Applied Mechanics

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