大跨度斜拉桥拉索垂度影响分析

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摘要 Vertical effects significantly affect the design and static analysis of large cable-stayed bridges. In the design of large cable-stayed bridges, the impact of cable sag must be considered. Generally, the Ernst equation is suitable when considering the cable sag effect for small spans (or the ratio of cable weight to tension). The Ernst formula assumes that a sag is a parabola curve and disregards the components of gravity. This assumption is inaccurate for some large-span bridges, and other accurate algorithms must thus be considered for analysis. In this work, the gravity and tensile force of cables are considered for long-span cable-stayed bridges. Furthermore, the effects of gravity on the directions of normal cables are considered. Analyses show that the gravitational components for cable directions should not be disregarded if the ratio of cable weight to tension force is large.

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	缪玮
	刘平

关键词 ： bridge engineering, large cable-stayed bridge, effects of vertical degree, non-linear effect

Abstract：Vertical effects significantly affect the design and static analysis of large cable-stayed bridges. In the design of large cable-stayed bridges, the impact of cable sag must be considered. Generally, the Ernst equation is suitable when considering the cable sag effect for small spans (or the ratio of cable weight to tension). The Ernst formula assumes that a sag is a parabola curve and disregards the components of gravity. This assumption is inaccurate for some large-span bridges, and other accurate algorithms must thus be considered for analysis. In this work, the gravity and tensile force of cables are considered for long-span cable-stayed bridges. Furthermore, the effects of gravity on the directions of normal cables are considered. Analyses show that the gravitational components for cable directions should not be disregarded if the ratio of cable weight to tension force is large.

Key words： bridge engineering large cable-stayed bridge effects of vertical degree non-linear effect

收稿日期: 2016-07-22

基金资助:Supported by the Research on the FSI Priciple of Membrane Structure Based on the Compressible Air Flow (No. 51508238)

通讯作者: MIAO Wei,E-mail address:382349957@qq.com E-mail: 382349957@qq.com

引用本文:

缪玮, 刘平. 大跨度斜拉桥拉索垂度影响分析[J]. Journal of Highway and Transportation Research and Development, 2017, 11(1): 38-41.
MIAO Wei, LIU Ping. Vertical Effects of Large Cable-stayed Bridges. Journal of Highway and Transportation Research and Development, 2017, 11(1): 38-41.

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http://manu27.magtech.com.cn/Jwk_gljtkj_en/CN/ 或 http://manu27.magtech.com.cn/Jwk_gljtkj_en/CN/Y2017/V11/I1/38

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