Performance of Three-Dimensional Reinforced Concrete Beam-Column Substructures under Loss of a Corner Column Scenario

Qian, Kai; Li, Bing

doi:10.1061/(asce)st.1943-541x.0000630

Cited by 143 publications

(42 citation statements)

References 7 publications

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“…For the simulated column removal scenarios corresponding to the least vertical deformations, the resistance of the progressive collapse was primarily provided by Vierendeel frame action, floor system in-plane action, and axial compressive force-moment interaction of beams. Several research studies were performed by Qian and Li (2013a, 2013b, 2012a, 2012b to predict beam-slab behaviour to mitigate progressive collapse as a result of corner column removal. Qian and Li (2013a) performed push-down tests on seven one-third scale RC beam-column connections to investigate their behaviour.…”

Section: Introductionmentioning

confidence: 99%

“…Several research studies were performed by Qian and Li (2013a, 2013b, 2012a, 2012b to predict beam-slab behaviour to mitigate progressive collapse as a result of corner column removal. Qian and Li (2013a) performed push-down tests on seven one-third scale RC beam-column connections to investigate their behaviour. Parameters considered in their tests included transverse steel reinforcement ratios, beam detailing, and beam shear span ratios.…”

Section: Introductionmentioning

confidence: 99%

“…Performance results showed that columns with drop panels increase the strength by 124.7% and; therefore, substantially reduce progressive collapse. Qian and Li (2012a) carried out a number of dynamic tests on six one-third scale RC beam-column specimens to simulate progressive collapse behaviour in the event of a corner column failure. Each specimen had different length, design detailing, and shear span ratio and was designed for testing to investigate the dynamic load redistribution performance following a sudden removal of a corner support.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Enhanced external progressive collapse mitigation scheme for RC structures

Elkholy

El-Ariss

2016

IJSTRUCTE

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This paper discusses enhancement of an external mitigating scheme to maximise the resistance of reinforced concrete continuous beams to progressive collapse due to interior support failure. The mitigating scheme using external unbounded fibre reinforced plastic straight cables and a relevant numerical model were presented by the authors in a published companion paper to predict the progressive collapse resistance of the mitigated beams. This study extends the previous work to efficiently enhance the resistance of mitigated beams by inspecting different mitigating scheme setups. Straight and deviated cable profiles are considered, different cable deviator locations are examined, and different cable deviations are accounted for to compare the corresponding mitigated beam resistance enhancements. The mitigating scheme setup that provides maximum increase in the beam resistance is considered the enhanced setup that efficiently maximises the increase in the mitigated beam resistance and could economically prevent progressive collapse of beams due to interior column failure.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Enhanced external progressive collapse mitigation scheme for RC structures

Elkholy

El-Ariss

2016

IJSTRUCTE

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“…The experimental results showed that the frame with middle column failed would go through three phases including elastic, plastic and catenary phases. Qian and Li [10] conducted seven one-third scale RC beam-column substructures to investigate the behavior under the scenario of being subjected to the loss of one ground corner column. It was proposed that increasing the flexural capacity of the beam section and upgrading the shear strength of the corner joint could improve the performance of frames against progressive collapse.…”

Section: Introductionmentioning

confidence: 99%

Analysis on Dynamic Response of Reinforced Concrete Frame for Resisting Progressive Collapse

Wang¹,

Zhang²,

Zhao³

et al. 2016

TOBCTJ

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Abstract:In order to investigate the dynamic response of reinforced concrete spatial frames caused by initial damages, a six-story frame model is analyzed by employing the nonlinear dynamic methodology in accordance with the alternate path method issued by General Services Administration. In this paper, the fiber model and force-based beam-column element are utilized in OpenSees. Four various scenarios are separately analyzed with incremental dynamic analysis. It is shown that the model does not collapse and the internal force redistribution mainly appears in the components adjacent to the failure column. The model has the worst capacity to resist progressive collapse in the inner column demolition scenario. It is observed that the plastic hinges mainly concentrate on the beam ends of the failure bay at the beginning of the demolition of columns. Several plastic hinges emerge at the top-floor beam ends of some other bays in latter period. The number of plastic hinges in columns is much less than that in beams, which corresponds to the design principle 'strong column and weak beam'.

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“…Four first-story columns were physically removed from the building to understand the subsequent load redistribution within the building. In Qian and Li (2013) experimental study of seven one-third scale RC beam-column substructures were tested to investigate the effect of beam transverse reinforcement ratios, type of design detailing, and beam span aspect ratios. Recently Qian et al (2015) tested 6 one-quarter scaled specimens to investigate the progressive collapse resisting capacity of RC frames including secondary mechanisms such as membrane actions developed in slabs.…”

Section: Introductionmentioning

confidence: 99%

Monotonic Loading Tests of RC Beam-Column Subassemblage Strengthened to Prevent Progressive Collapse

Kim

Choi

2015

International Journal of Concrete Structures and Materials

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In this study the progressive collapse resisting capacity of a RC beam-column subassemblage with and without strengthening was investigated. Total of five specimens were tested; two unreinforced specimens, the one designed as gravity loadresisting system and the other as seismic load-resisting system, and three specimens reinforced with: (i) bonded strand, (ii) unbonded strand, and (iii) side steel plates with stud bolts. The two-span subassemblages were designed as part of an eight-story RC building. Monotonically increasing load was applied at the middle column of the specimens and the force-displacement relationships were plotted. It was observed that the gravity load-resisting specimen failed by fractures of re-bars in the beams. In the other specimens no failure was observed until the maximum displacement capacity of the actuator was reached. Highest strength was observed in the structure with unbonded strand. The test result of the specimen with side steel plates in beam-column joints showed that the force-displacement curve increased without fracture of re-bars. Based on the test results it was concluded that the progressive collapse resisting capacity of a RC frame could be significantly enhanced using unbonded strands or side plates with stud bolts.

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Performance of Three-Dimensional Reinforced Concrete Beam-Column Substructures under Loss of a Corner Column Scenario

Cited by 143 publications

References 7 publications

Enhanced external progressive collapse mitigation scheme for RC structures

Enhanced external progressive collapse mitigation scheme for RC structures

Analysis on Dynamic Response of Reinforced Concrete Frame for Resisting Progressive Collapse

Monotonic Loading Tests of RC Beam-Column Subassemblage Strengthened to Prevent Progressive Collapse

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