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http://dx.doi.org/10.12989/sss.2015.15.3.505

Mechanisms of thermally induced deflection of a long-span cable-stayed bridge  

Zhou, Yi (State Key Lab for Disaster Reduction in Civil Engineering, Tongji University)
Sun, Limin (State Key Lab for Disaster Reduction in Civil Engineering, Tongji University)
Peng, Zhijian (Shanghai Highway Investment Construction & Development Co., Ltd.)
Publication Information
Smart Structures and Systems / v.15, no.3, 2015 , pp. 505-522 More about this Journal
Abstract
Variation of temperature is a primary environmental factor that affects the behavior of structures. Therefore, understanding the mechanisms of normal temperature-induced variations of structural behavior would help in distinguishing them from anomalies. In this study, we used the structural health monitoring data of the Shanghai Yangtze River Bridge, a steel girder cable-stayed bridge, to investigate the mechanisms of thermally induced vertical deflection ($D_T$) at mid-span of such bridges. The $D_T$ results from a multisource combination of thermal expansion effects of the cable temperature ($T_{Cab}$), girder temperature ($T_{Gir}$), girder differential temperature ($T_{Dif}$), and tower temperature ($T_{Tow}$). It could be approximated by multiple linear superpositions under operational conditions. The sensitivities of $D_T$ of the Shanghai Yangtze River Bridge to the above temperatures were in the following order: $T_{Cab}$ > $T_{Gir}$ > $T_{Tow}$ > $T_{Dif}$. However, the direction of the effect of $T_{Cab}$ was observed to be opposite to that of the other three temperatures, and the magnitudes of the effects of $T_{Cab}$ and $T_{Gir}$ were found to be almost one order greater than those of $T_{Dif}$ and $T_{Tow}$. The mechanisms of the thermally induced vertical deflection variation at mid-span of a cable-stayed bridge as well as the analytical methodology adopted in this study could be applicable for other long-span cable-stayed bridges.
Keywords
cable-stayed bridge; temperature effect; mid-span deflection; mechanisms; structural health monitoring;
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