Myriad Convention Center Floor System Reinforcement

玻璃钢 Pub Date : 1999-08-01 DOI:10.14359/5702

T. Hogue, R. C. Cornforth, A. Nanni

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引用次数: 22

Abstract

It was determined that additional flexural strength, ductility and crack-control and shear strength were needed in the Myriad convention center unbonded post-tensioned street-level floor system. Fiber reinforced polymer (FRP) reinforcement was designed to correct the insufficiencies. The challenge in the project, aside from the mechanics unique to FRP reinforcement, was to present the design in such a way as to allow and encourage as many bidders as possible to bid on the construction. In particular, since there are no standardized properties for any given type of FRP, the possibility that not all bids would involve the same properties had to be accommodated--especially in the flexural design. Generally, for each strengthening location, two flexural designs were completed: one giving required FRP force level at minimum ultimate FRP strain and one required FRP force level on concrete crushing at the limit state of failure, the latter associated FRP ultimate strain termed "High Threshold" ultimate strain. Required force level for any ultimate strain could then be obtained by linear interpolation. Ability to use FRP for shear reinforcement was limited due to low available beam stem development length. Both glass, with restrictions, and carbon FRP were allowed for shear reinforcement.

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万利亚会议中心地板系统加固

确定麦利亚德会议中心无粘结后张拉地面系统需要额外的抗弯强度、延性、裂缝控制和抗剪强度。纤维增强聚合物(FRP)的设计是为了纠正这一不足。除了FRP加固的独特力学外，项目的挑战在于以允许和鼓励尽可能多的投标人参与投标的方式呈现设计。特别是，由于任何特定类型的FRP都没有标准化的性能，因此必须考虑到并非所有投标都涉及相同性能的可能性——特别是在弯曲设计中。一般来说，对于每个加固位置，完成了两个弯曲设计:一个给出了最低FRP极限应变时所需的FRP力水平，另一个给出了极限破坏状态下混凝土破碎时所需的FRP力水平，后者与FRP极限应变相关，称为“高阈值”极限应变。任何极限应变所需的力水平都可以通过线性插值得到。由于可用的梁杆发展长度较低，使用FRP进行抗剪加固的能力受到限制。有限制的玻璃和碳玻璃钢都被允许用于剪切加固。

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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玻璃钢

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357