Properties and improvement of ultra-high performance concrete with coarse aggregates and polypropylene fibers after high-temperature damage

•The finer PP fibers maintained the best relative value of properties after high temperature.•The effect of post-fire curing was particularly effective in environments containing water.•The improvement of UHPC after post-fire curing is the result of both chemical and physical reaction processes. Ult...

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Bibliographic Details
Published in:Construction & building materials 2023-01, Vol.364, p.129925, Article 129925
Main Authors: Qian, Yunfeng, Yang, Dingyi, Xia, Yanghao, Gao, Han, Ma, Zhiming
Format: Article
Language:English
Subjects:
High temperature
Polypropylene fiber
Post-fire curing
Properties evaluation
Ultra-high performance concrete with coarse aggregates
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Summary:•The finer PP fibers maintained the best relative value of properties after high temperature.•The effect of post-fire curing was particularly effective in environments containing water.•The improvement of UHPC after post-fire curing is the result of both chemical and physical reaction processes. Ultra-high performance concrete containing coarse aggregates (UHPC-CA) is more cost-effective, with its low cost and easy access to materials, but its high-temperature performance and self-healing capability after post-fire curing remain to be further explored. In this paper, after high temperature, the compressive strength increases by approximately 20 MPa within 400 °C, and the micro-characteristics reveal that this is mainly because the temperature promotes the cement hydration reaction and pozzolanic reaction, which plays the role of secondary accelerated curing. Due to the continuous decomposition of substances, the flexural strength and ultrasonic pulse velocity gradually decrease; the mass loss, total porosity, and the amount of absorbed water increase, especially the sorptivity coefficient, which increases by more than 100 times after 800 °C. The residual values of all properties of UHPC-CA are best maintained by adding all of the finer PP fibers. Relying on many unhydrated gelling materials, UHPC has a more significant self-healing potential, improving its mechanical properties and permeability in all three post-fire curing environments. The most significant effect is seen in the water environment, where its recovery rate of strength exceeds 50 % in all cases. The self-healing enhancement of UHPC does not come from a single source, but from multiple combinations of physical and chemical reaction processes.
ISSN:0950-0618
1879-0526
DOI:10.1016/j.conbuildmat.2022.129925