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A platform for research: civil engineering, architecture and urbanism
Typhoon-induced non-stationary buffeting response of long-span bridges in complex terrain
Highlights Propose a framework for typhoon-induced non-stationary buffeting analysis of a bridge. Model non-stationary wind as time-varying mean wind plus evolutionary random process. Consider effects of time-dependent force coefficients and flutter derivatives. Use pseudo excitation method to compute evolutionary response spectra of a bridge. It is necessary to consider non-stationary effects on bridge buffeting response.
Abstract This paper presents a framework for predicting typhoon-induced non-stationary buffeting response of long-span cable-supported bridges located in a complex terrain. First, a non-stationary typhoon wind model is proposed based on observations from measured typhoon wind data. The wind model includes mainly time-varying mean wind speed, mean wind speed profile and evolutionary power spectral density (EPSD) function. Typhoon-induced wind loading on a bridge deck is then represented by time-varying mean wind forces, non-stationary buffeting forces associated with time-dependent aerodynamic coefficients and self-excited forces characterized by time-dependent aerodynamic derivatives. A nonlinear static analysis is performed to determine time-varying mean wind response, whereas the pseudo excitation method is employed to compute the EPSD-expressed non-stationary buffeting response of a long-span cable-supported bridge. The proposed framework is finally applied to predict non-stationary buffeting responses of a long-span cable-stayed bridge located in a complex terrain during a strong typhoon as a case study. The case study demonstrates how to apply the proposed framework and the results show that the proposed framework is feasible and necessary.
Typhoon-induced non-stationary buffeting response of long-span bridges in complex terrain
Highlights Propose a framework for typhoon-induced non-stationary buffeting analysis of a bridge. Model non-stationary wind as time-varying mean wind plus evolutionary random process. Consider effects of time-dependent force coefficients and flutter derivatives. Use pseudo excitation method to compute evolutionary response spectra of a bridge. It is necessary to consider non-stationary effects on bridge buffeting response.
Abstract This paper presents a framework for predicting typhoon-induced non-stationary buffeting response of long-span cable-supported bridges located in a complex terrain. First, a non-stationary typhoon wind model is proposed based on observations from measured typhoon wind data. The wind model includes mainly time-varying mean wind speed, mean wind speed profile and evolutionary power spectral density (EPSD) function. Typhoon-induced wind loading on a bridge deck is then represented by time-varying mean wind forces, non-stationary buffeting forces associated with time-dependent aerodynamic coefficients and self-excited forces characterized by time-dependent aerodynamic derivatives. A nonlinear static analysis is performed to determine time-varying mean wind response, whereas the pseudo excitation method is employed to compute the EPSD-expressed non-stationary buffeting response of a long-span cable-supported bridge. The proposed framework is finally applied to predict non-stationary buffeting responses of a long-span cable-stayed bridge located in a complex terrain during a strong typhoon as a case study. The case study demonstrates how to apply the proposed framework and the results show that the proposed framework is feasible and necessary.
Typhoon-induced non-stationary buffeting response of long-span bridges in complex terrain
Hu, Liang (author) / Xu, You-Lin (author) / Huang, Wen-Feng (author)
Engineering Structures ; 57 ; 406-415
2013-09-30
10 pages
Article (Journal)
Electronic Resource
English
Typhoon-induced non-stationary buffeting response of long-span bridges in complex terrain
| Online Contents | 2013