Experimental study on PVC-CFRP confined concrete columns under low cyclic loading

•Different failure modes of PVC-CFRP confined concrete columns under low cyclic loading were found.•The effect of the axial compression ratio, shear span ratio, and hoop spacing of CFRP strips on the ultimate bearing capacity was established.•The effect of the axial compression ratio, shear span rat...

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Bibliographic Details
Published in:Construction & building materials 2018-07, Vol.177, p.287-302
Main Authors: Yu, Feng, Xu, Guoshi, Niu, Ditao, Cheng, Anchun, Wu, Ping, Kong, Zhengyi
Format: Article
Language:English
Subjects:
Analysis
Axial compression ratio
Chemical properties
Cyclic behavior
Ductility capacity
Failure mode
Failure mode and effects analysis
Hoop spacing of CFRP strips
Mechanical properties
Polyvinyl chloride
PVC-FRP confined concrete
Reinforced concrete
Reinforced plastics
Shear span ratio
Ultimate bearing capacity
Ultimate strain
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Summary:•Different failure modes of PVC-CFRP confined concrete columns under low cyclic loading were found.•The effect of the axial compression ratio, shear span ratio, and hoop spacing of CFRP strips on the ultimate bearing capacity was established.•The effect of the axial compression ratio, shear span ratio, and hoop spacing of CFRP strips on the strain evolution was established.•The effect of the axial compression ratio, shear span ratio, and hoop spacing of CFRP strips on the ductility capacity was established. This paper presented an experimental study on the failure mode, ultimate bearing capacity and ductility capacity of PVC-CFRP confined reinforced concrete columns subject to low cyclic loading. Several parameters, such as the axial compression ratio, shear span ratio, and hoop spacing of CFRP strips were considered in the analysis. The results showed that all columns at low axial compression ratio failed by bending. The long and short columns with large hoop spacing at high axial compression ratio failed by flexural shear while the short columns with small hoop spacing at high axial compression ratio failed by shear. The ultimate bearing capacity increased as the axial compression ratio increased or the shear span ratio decreased while the ultimate bearing capacity decreased as the hoop spacing of CFRP strips increased. The ultimate strains located at the bottom of the column increased as the axial compression ratio increased while the ultimate strains decreased as the shear span ratio increased. The confining effect of CFRP strips increased gradually as the hoop spacing of CFRP strips decreased. The ductility capacity decreases as the axial compression ratio or the shear span ratio increased while the ductility capacity increases as the hoop spacing of CFRP strips increased.
ISSN:0950-0618
1879-0526
DOI:10.1016/j.conbuildmat.2018.05.111