Mechanical properties of circular thin-tubed molybdenum tailing concrete stubs

•The axial performance degradation of 16 TTMoTC and 4 MoTCFT stubs were tested.•An approximate linear degradation trend is noticed on the axial strength of TTMoTC.•Increasing the MoT replacement ratio would reduce the ultimate displacement.•A uniaxial compressive constitutive model for the TTMoTC st...

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Bibliographic Details
Published inConstruction & building materials Vol. 268; p. 121215
Main Authors Gao, Shan, Zhao, Guohao, Guo, Lanhui, Zhou, Linqiang, Cui, Xiaowei, Yang, Haipeng
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 25.01.2021
Subjects
Axial behavior
Fine aggregates
Molybdenum tailing
Stub column
Thin-tubed concrete
Molybdenum tailing
Fine aggregates
Stub column
Axial behavior
Thin-tubed concrete
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Summary:•The axial performance degradation of 16 TTMoTC and 4 MoTCFT stubs were tested.•An approximate linear degradation trend is noticed on the axial strength of TTMoTC.•Increasing the MoT replacement ratio would reduce the ultimate displacement.•A uniaxial compressive constitutive model for the TTMoTC stubs is proposed.•A full-range prediction analysis is performed for TTMoTC stub. The configuration of thin-tubed concrete is a preferable method to enhance the mechanical properties of concrete. In this paper, the axial behavior of circular thin-tubed molybdenum tailing concrete (TTMoTC) stubs is experimentally and theoretically studied in detail by considering the molybdenum tailing (MoT) replacement ratio and concrete grade. The results show that EC4-04 model is the most reliable model to predict the elastic modulus of molybdenum tailing concrete by using the corresponding compressive strength. The usage of MoT in the core concrete has little effect on the failure modes of thin-tubed concrete stubs and concrete-filled tubes. An approximate linear degradation trend is noticed on the axial strength of TTMoTC. Increasing the MoT replacement ratio would reduce the ultimate displacement, rather than the ductility index of the stubs, regardless of concrete grade. A uniaxial compressive constitutive model for the TTMoTC stubs is proposed and validated. Based on the proposed design method for TTMoTC stub, a full-range prediction analysis is performed.
ISSN:0950-0618
1879-0526
DOI:10.1016/j.conbuildmat.2020.121215