Seismic Performance of Curved Bridges with Longitudinal Slope

Peng Su; Yanjiang Chen; Zhongwei Zhao; Weiming Yan

doi:10.3390/app9040771

Seismic Performance of Curved Bridges with Longitudinal Slope

Applied Sciences ◽

10.3390/app9040771 ◽

2019 ◽

Vol 9 (4) ◽

pp. 771

Author(s):

Peng Su ◽

Yanjiang Chen ◽

Zhongwei Zhao ◽

Weiming Yan

Keyword(s):

Ground Motion ◽

Structural Response ◽

Seismic Excitation ◽

Tangential Displacement ◽

Site Conditions ◽

Rotation Effect ◽

Curved Bridges ◽

Curved Bridge ◽

Displacement Response ◽

Main Girder

A curved bridge test model with a scale ratio of 1:10 was constructed to investigate the influence of site conditions on curved bridges with longitudinal slopes based on a similar theory. The natural ground motions of five different groups, namely, Sites A–E, were selected from the Pacific Earthquake Engineering Center (PEER) seismic database, and the shaking table model test was conducted under horizontal unidirectional and bidirectional excitations. Results showed that the structural response of the curved bridge is sensitive to the ground motion of different site conditions. Spatial characteristics are observed in the main girder structural response of the curved bridge. When the curved bridge is parallel to the direction of the principal ground motion, the rotation effect of the main girder is greater than that perpendicular to the direction of the principal ground motion. The rotation effect of the main girder leads to evident beam end and bearing displacements at the low pier. The seismic excitation direction and pier height notably affect the displacement response of the pier, and the tangential displacement response of the fixed pier is sensitive to seismic excitation.

Download Full-text

A Multi-Objective Ground Motion Selection Approach Matching the Acceleration and Displacement Response Spectra

Sustainability ◽

10.3390/su10124659 ◽

2018 ◽

Vol 10 (12) ◽

pp. 4659 ◽

Cited By ~ 1

Author(s):

Yabin Chen ◽

Longjun Xu ◽

Xingji Zhu ◽

Hao Liu

Keyword(s):

Ground Motion ◽

Response Spectrum ◽

Structural Response ◽

Response Spectra ◽

Computationally Efficient ◽

Ground Motion Selection ◽

Displacement Response ◽

Rc Frames ◽

Selection Approach ◽

Displacement Response Spectra

For seismic resilience-based design (RBD), a selection of recorded time histories for dynamic structural analysis is usually required. In order to make individual structures and communities regain their target functions as promptly as possible, uncertainty of the structural response estimates is in great need of reduction. The ground motion (GM) selection based on a single target response spectrum, such as acceleration or displacement response spectrum, would bias structural response estimates leading significant uncertainty, even though response spectrum variance is taken into account. In addition, resilience of an individual structure is not governed by its own performance, but depends severely on the performance of other systems in the same community. Thus, evaluation of resilience of a community using records matching target spectrum at whole periods would be reasonable because the fundamental periods of systems in the community may be varied. This paper presents a GM selection approach based on a probabilistic framework to find an optimal set of records to match multiple target spectra, including acceleration and displacement response spectra. Two major steps are included in that framework. Generation of multiple sub-spectra from target displacement response spectrum for selecting sets of GMs was proposed as the first step. Likewise, the process as genetic algorithm (GA), evolvement of individuals previously generated, is the second step, rather than using crossover and mutation techniques. A novel technique improving the match between acceleration response spectra of samples and targets is proposed as the second evolvement step. It is proved computationally efficient for the proposed algorithm by comparing with two developed GM selection algorithms. Finally, the proposed algorithm is applied to select GM records according to seismic codes for analysis of four archetype reinforced concrete (RC) frames aiming to evaluate the influence of GM selection considering two design response spectra on structural responses. The implications of design response spectra especially the displacement response spectrum and GM selection algorithm are summarized.

Download Full-text

A Practical Response Spectrum Method in Considering the Input Angle of Seismic Excitation

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.438-439.1506 ◽

2013 ◽

Vol 438-439 ◽

pp. 1506-1509

Author(s):

Shi Mei Liu ◽

Ling Tao Xia

Keyword(s):

Random Vibration ◽

Response Spectrum ◽

Power Spectra ◽

Structural Response ◽

Seismic Excitation ◽

Response Spectrum Method ◽

Displacement Response ◽

Spectrum Method

To the asymmetric-plan structures, the torsion model is obvious, and the influence of input angle of excitation on structural response is sensitive, so a practical response spectrum method for analyzing the behaviors of this kind of structure is studied. Based on the achievements about the multi-components accelerations power spectra matrix, a rational formula, considering the input angle of excitation, is deduced by using stationary random vibration principle. A practical formula is proposed by introducing displacement response spectrum as equally as to considering the non-stationarity of excitation.

Download Full-text

Effect of Frequency Characteristics of Ground Motion on Response of Tuned Mass Damper Controlled Inelastic Concrete Frame

Buildings ◽

10.3390/buildings11020074 ◽

2021 ◽

Vol 11 (2) ◽

pp. 74

Author(s):

Md Motiur Rahman ◽

Tahmina Tasnim Nahar ◽

Dookie Kim

Keyword(s):

Ground Motion ◽

Structural Response ◽

Tuned Mass Damper ◽

Frequency Characteristics ◽

Building Frames ◽

Concrete Frame ◽

Finite Element Software ◽

Mass Damper ◽

Lateral Displacements ◽

Modal Mass

This paper investigates the performance of tuned mass damper (TMD) and dynamic behavior of TMD-controlled concrete structure considering the ground motion (GM) characteristics based on frequency content. The effectiveness of TMD in reducing the structural response and probability of collapse of the building frames are affected by the frequency characteristics of GMs. To attenuate the seismic vibration of the buildings, the TMD controlled building has been designed based on the modal analysis (modal frequencies and modal mass participation ratio). In this study, to investigate the performance of TMD, four different heights (i.e., 3, 5, 10, 20 stories) inelastic concrete moment-resisting frames equipped with TMDs are developed using an open-source finite element software. A series of numerical analyses have been conducted using sixty earthquakes classified into three categories corresponding to low, medium, and high-frequency characteristics of GMs. To evaluate the proposed strategy, peak lateral displacements, inter-story drift, and the probability of collapse using fragility analysis have been investigated through the structures equipped with and without TMD. The results appraise the effect of TMD and compare the seismic responses of earthquake frequency contents and the vibration control system of the inelastic building frames.

Download Full-text

Attention-Based Sequence-to-Sequence Learning for Online Structural Response Forecasting Under Seismic Excitation

IEEE Transactions on Systems Man and Cybernetics Systems ◽

10.1109/tsmc.2020.3048696 ◽

2021 ◽

pp. 1-17

Author(s):

Teng Li ◽

Yuxin Pan ◽

Kaitai Tong ◽

Carlos E. Ventura ◽

Clarence W. de Silva

Keyword(s):

Sequence Learning ◽

Structural Response ◽

Seismic Excitation

Download Full-text

An approach to quantify the influence of ground motion uncertainty on elastoplastic system acceleration in incremental dynamic analysis

Advances in Structural Engineering ◽

10.1177/1369433217693630 ◽

2017 ◽

Vol 20 (11) ◽

pp. 1744-1756 ◽

Cited By ~ 1

Author(s):

Peng Deng ◽

Shiling Pei ◽

John W. van de Lindt ◽

Hongyan Liu ◽

Chao Zhang

Keyword(s):

Dynamic Analysis ◽

Ground Motion ◽

Earthquake Engineering ◽

Structural Response ◽

Incremental Dynamic Analysis ◽

Degree Of Freedom ◽

Maximum Acceleration ◽

Single Degree Of Freedom ◽

Single Degree ◽

Performance Based Earthquake Engineering

Inclusion of ground motion–induced uncertainty in structural response evaluation is an essential component for performance-based earthquake engineering. In current practice, ground motion uncertainty is often represented in performance-based earthquake engineering analysis empirically through the use of one or more ground motion suites. How to quantitatively characterize ground motion–induced structural response uncertainty propagation at different seismic hazard levels has not been thoroughly studied to date. In this study, a procedure to quantify the influence of ground motion uncertainty on elastoplastic single-degree-of-freedom acceleration responses in an incremental dynamic analysis is proposed. By modeling the shape of the incremental dynamic analysis curves, the formula to calculate uncertainty in maximum acceleration responses of linear systems and elastoplastic single-degree-of-freedom systems is constructed. This closed-form calculation provided a quantitative way to establish statistical equivalency for different ground motion suites with regard to acceleration response in these simple systems. This equivalence was validated through a numerical experiment, in which an equivalent ground motion suite for an existing ground motion suite was constructed and shown to yield statistically similar acceleration responses to that of the existing ground motion suite at all intensity levels.

Download Full-text