Seismic Fragility Evaluation of Retrofitted Low-Rise RC Structures

Although embankment seismic damages are very complex, there has been little seismic fragility research yet. Researches on seismic fragility of bridges, dams and reinforced concrete (RC) structures have achieved fruitful results, which can provide references for embankment seismic fragility assessment. Meanwhile, the influencing degrees of retaining structures, such as retaining walls on the embankment seismic performances are still unclear. The K1025+470 embankment of the Xi’an-Baoji expressway was selected as the research object, and the finite difference models of the embankment fill-soil foundation system and embankment fill-soil foundation-retaining wall system were established. The ground-motion records for Incremental Dynamic Analysis (IDA) were selected and the dynamic response analysis were conducted. Probabilistic Seismic Demand Analysis (PSDA) was used to deal with the IDA results and the seismic fragility curves were generated. Based on the assessment results, the influences of the retaining wall on the embankment seismic fragility were further verified. The research results show that regardless of which seismic damage parameter is considered or the presence or absence of the retaining wall, larger PGAs always correspond to higher probabilities of each seismic damage grade. Seismic damages to the embankment fill-soil foundation-retaining wall system are always lower than those of the embankment fill-soil foundation system under the same PGA actions, thus, the retaining wall can decrease the embankment seismic fragility significantly.

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SEISMIC FRAGILITY OF RC STRUCTURES UNDER MAINSHOCK-AFTERSHOCK SEQUENCES RECORDED ON SOFT SOIL CONDITIONS

Proceedings of the 7th International Conference on Computational Methods in Structural Dynamics and Earthquake Engineering (COMPDYN 2015) ◽

10.7712/120119.7100.19183 ◽

2019 ◽

Author(s):

Duofa Ji ◽

Evangelos Katsanos

Keyword(s):

Soft Soil ◽

Seismic Fragility ◽

Soil Conditions ◽

Rc Structures ◽

Aftershock Sequences

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Time-Variant Seismic Performance of Offshore RC Bridge Columns with Uncertainty

International Journal of Structural Stability and Dynamics ◽

10.1142/s0219455418501493 ◽

2018 ◽

Vol 18 (12) ◽

pp. 1850149

Author(s):

Hong-Nan Li ◽

Hu Cheng ◽

Dong-Sheng Wang

Keyword(s):

Seismic Performance ◽

Bridge Columns ◽

Column Height ◽

Seismic Fragility ◽

Initiation Time ◽

Rc Structures ◽

Material Parameters ◽

Corrosion Initiation ◽

Corrosion Initiation Time ◽

Rc Bridge Columns

To establish a framework for evaluating the time-variant seismic performance of deteriorated reinforced concrete (RC) structures with uncertainty, offshore RC bridge columns exposed to marine environments are studied in this paper. The uncertainties from the material parameters, corrosion initiation time and earthquake ground motions are taken into account. Due to the different corrosion characteristics in various zones (i.e. the submerged zone, splash and tidal zone, and atmospheric zone) along the column height, corrosion-induced damages in each zone are considered separately, and the geometric mean of the yield displacements of the three zones is used to define the structural capacity (limit state). Meanwhile, the time-variant limit states are determined based on nonlinear static analyses, which reflect the current state of deteriorating RC columns. A total of four cases are studied using the Latin hypercube sampling (LHS) technique based on the probability distributions of the material parameters and corrosion initiation time, including the effects of statistical correlations among the material parameters. The results reveal that the seismic fragility is underestimated by a deterministic numerical model. The uncertainty in the corrosion initiation time influences the seismic fragility less significantly than that in the structural material parameters whether or not anti-corrosion measures are implemented. It is suggested that probabilistic methods should be used for seismic evaluation of deteriorating RC structures to consider the uncertainty involved.

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State of Development of Seismic Retrofit of RC Structures with Post-Installed Plate-Anchored Shear Reinforcement

Concrete Journal ◽

10.3151/coj.56.7_570 ◽

2018 ◽

Vol 56 (7) ◽

pp. 570-578

Author(s):

A. Hata ◽

K. Kawamura ◽

W. Zhao ◽

M. Chujo

Keyword(s):

Seismic Retrofit ◽

Shear Reinforcement ◽

Rc Structures

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Comparison of steel frames with RWS and WFP beam-to-column connections through seismic fragility analysis

Advances in Structural Engineering ◽

10.1177/1369433220977284 ◽

2020 ◽

pp. 136943322097728

Author(s):

Haoran Yu ◽

Weibin Li

Keyword(s):

Limit State ◽

Pushover Analysis ◽

Steel Frames ◽

Fragility Analysis ◽

Structural Safety ◽

Seismic Fragility ◽

Fe Modelling ◽

Collapse Resistance ◽

Seismic Collapse ◽

Probabilistic Seismic Demand

Reduced web section (RWS) connections and welded flange plate (WFP) connections can both effectively improve the seismic performance of a structure by moving plastic hinges to a predetermined location away from the column face. In this paper, two kinds of steel frames—with RWS connections and WFP connections—as well as different frames with welded unreinforced flange connections were studied through seismic fragility analysis. The numerical simulation was conducted by using multiscale FE modelling. Based on the incremental dynamic analysis and pushover analysis methods, probabilistic seismic demand analysis and seismic capability analysis were carried out, respectively. Finally, combined with the above analysis results, probabilistic seismic fragility analysis was conducted on the frame models. The results showed that the RWS connection and WFP connection (without double plates) have little influence on reducing the maximum inter-storey drift ratio under earthquake action. RWS connections slightly reduce the seismic capability in non-collapse stages and improve the seismic collapse resistance of a structure, which exhibits good structural ductility. WFP connections can comprehensively improve the seismic capability of a structure, but the seismic collapse resistance is worse than that of RWS connections when the structure has a large number of storeys. The frame with WFP connections has a lower failure probability at every seismic limit state, while the frame with RWS connections sacrifices some of its structural safety in non-collapse stages to reduce the collapse probability.

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Comparative study of base-isolated irregular RC structures subjected to pulse-like ground motions with low and high PGA/PGV ratios

Structures ◽

10.1016/j.istruc.2021.02.021 ◽

2021 ◽

Vol 31 ◽

pp. 1053-1071

Author(s):

Ahed Habib ◽

Ausamah AL Houri ◽

Umut Yildirim

Keyword(s):

Comparative Study ◽

Ground Motions ◽

Rc Structures

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Numerical Evaluation of Soil-Pile-Structure Interaction Effects in Nonlinear Analysis of Seismic Fragility Curves

Transportation Infrastructure Geotechnology ◽

10.1007/s40515-021-00161-y ◽

2021 ◽

Author(s):

Nesrine Guettafi ◽

Djarir Yahiaoui ◽

Khelifa Abbeche ◽

Tayeb Bouzid

Keyword(s):

Nonlinear Analysis ◽

Numerical Evaluation ◽

Fragility Curves ◽

Interaction Effects ◽

Seismic Fragility ◽

Structure Interaction

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Flexural Performance of RC Beams Strengthened with Externally-Side Bonded Reinforcement (E-SBR) Technique Using CFRP Composites

Materials ◽

10.3390/ma14112809 ◽

2021 ◽

Vol 14 (11) ◽

pp. 2809

Author(s):

Md. Akter Hosen ◽

Fadi Althoey ◽

Mohd Zamin Jumaat ◽

U. Johnson Alengaram ◽

N. H. Ramli Sulong

Keyword(s):

Absorption Capacity ◽

Experimental Program ◽

Rc Beams ◽

Rc Structures ◽

Functional Changes ◽

Flexural Strengthening ◽

Cfrp Laminates ◽

Flexural Performance ◽

Design Loads ◽

Predicted Values

Reinforced concrete (RC) structures necessitate strengthening for various reasons. These include ageing, deterioration of materials due to environmental effects, trivial initial design and construction, deficiency of maintenance, the advancement of design loads, and functional changes. RC structures strengthening with the carbon fiber reinforced polymer (CFRP) has been used extensively during the last few decades due to their advantages over steel reinforcement. This paper introduces an experimental approach for flexural strengthening of RC beams with Externally-Side Bonded Reinforcement (E-SBR) using CFRP fabrics. The experimental program comprises eight full-scale RC beams tested under a four-point flexural test up to failure. The parameters investigated include the main tensile steel reinforcing ratio and the width of CFRP fabrics. The experimental outcomes show that an increase in the tensile reinforcement ratio and width of the CFRP laminates enhanced the first cracking and ultimate load-bearing capacities of the strengthened beams up to 141 and 174%, respectively, compared to the control beam. The strengthened RC beams exhibited superior energy absorption capacity, stiffness, and ductile response. The comparison of the experimental and predicted values shows that these two are in good agreement.

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