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Advances in Civil and Architectural Engineering, Vol. 16 No. 31, 2025.

Original scientific paper

https://doi.org/10.13167/2025.31.12

Post-fire strengths and morphological properties of high-strength concrete reinforced with kenaf fibres

Oluwatobi Aluko orcid id orcid.org/0000-0002-3221-5730 ; Ekiti State University, Faculty of Engineering, Iworoko, 362103, Ado Ekiti, Ekiti State, Nigeria *
Mariyana Abd Kadir ; Universiti Teknologi Malaysia, Faculty of Civil Engineering, 81310 Skudai, Johor, Malaysia
Paul Awoyera ; Prince Mohammad Bin Fahd University, Faculty of Engineering, 31952, Al Kobar, Saudi Arabia
Naraindas Bheel ; AROR University of Art, Architecture, Design & Heritage Sukkur, 65170, Sindh, Pakistan
Jamaludin Yatim ; Universiti Teknologi Malaysia, Faculty of Civil Engineering, 81310 Skudai, Johor, Malaysia

* Corresponding author.

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Abstract

The high manufacturing cost of conventional fibres and the need for greener and more sustainable constructions necessitate the adoption of plant-based fibres in concrete. Previous research has shown that fibres remarkably influence the post-fire behaviour of concrete. Post-fire concrete strengths and micro-imageries are vital to the serviceability requirements of concrete. Therefore, this paper presents an experimental report on a 28-day cured kenaf fibrous high-strength concrete (KFHSC), heated from ambient temperature to 800 ºC at 100 ºC intervals, sustained for 1, 2, and 3 h, and tested after being cooled naturally to ambient temperature. The fibres were treated and examined through SEM to ascertain their interfacial properties. Test samples of concrete grade 60 were prepared using an optimum volume (0,75 %) and length (25 mm). The KFHSC's residual strength characteristics, weight, ultrasonic pulse velocity, and morphology were determined and compared with plain (unreinforced) high-strength concrete. The findings show that samples of both mixes degraded with an increase in temperature and exposure durations. However, kenaf fibre retrained crack extension at a lower temperature phase and through networks of channels within the matrices, reduced pore pressure build-up at a higher temperature phase and consequently lessened the explosive spalling of the heated concrete.

Keywords

biofibres; kenaf fibre; residual mechanical properties; microstructures; elevated temperature

Hrčak ID:

342864

URI

https://hrcak.srce.hr/342864

Publication date:

14.11.2025.

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