生物炭水泥基复合材料的防火性能

IF 5.3 Q2 MATERIALS SCIENCE, COMPOSITES
Rhoda Afriyie Mensah , Dong Wang , Vigneshwaran Shanmugam, Gabriel Sas, Michael Försth, Oisik Das
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引用次数: 0

摘要

该研究旨在验证生物炭的独特特性(如微孔结构)可以增强混凝土耐高温能力的假设。尽管预期会减少裂缝的形成并增强耐火性,但实验结果表明,生物炭对混凝土的耐火性能影响有限。调查涉及使用两种生物炭,即细生物炭和粗生物炭,分别替代水泥和集料。细生物炭的吸水率和杨氏模量高于粗生物炭,但两者在 35 kW/m2 的辐射热通量下都能阻燃,且峰值热释放率低于 40 kW/m2。将这些生物炭以不同的重量百分比(10、15 和 20 wt.%)掺入混凝土中会导致抗压和抗拉强度逐渐下降,原因是随着生物炭含量的增加,结合能力降低。暴露在 1000 °C 的温度下会影响所有样品的机械性能。然而,与对照组相比,生物炭混凝土在暴露于 600 °C后仍能保持抗压强度(与对照组相比),其中生物炭作为细骨料替代物的含量最高可达 20 wt.%,而作为水泥替代物的生物炭混凝土在暴露于 200 °C后仍能保持抗压强度。这种替代品还显著减少了混凝土生产过程中的二氧化碳排放量(生物炭装载量增加一倍,二氧化碳排放量减少 50%),展示了生物炭在可持续建筑实践中的潜力。尽管这项研究没有完全支持最初的假设,但它证明了生物炭在减少碳足迹方面的可行性,同时还能在特定的火灾条件下保持混凝土强度。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Fire behaviour of biochar-based cementitious composites

The study aimed to test the hypothesis that biochar's unique properties, such as its microporous structure, can enhance concrete's resilience to high temperatures. Despite expectations of reduced crack formation and enhanced fire resistance, the experimental results revealed a limited impact on concrete's fire behaviour. The investigation involved the use of two biochar types, fine and coarse biochar as replacements for cement and aggregates, respectively. Fine biochar exhibited higher water absorption and Young's modulus than coarse biochar, but both resisted ignition at 35 kW/m2 radiative heat flux and had peak heat release rates below 40 kW/m2. Incorporating these biochars at varying weight percentages (10, 15, and 20 wt.%) into concrete led to a gradual decline in compressive and tensile strength due to reduced binding ability with increased biochar content. Exposure to 1000 °C compromised mechanical properties across all the samples. However, the biochar concrete maintained compressive strength (compared to the control) with up to 20 wt.% biochar as a fine aggregate substitute after exposure to 600 °C, and as a cement replacement after exposure to 200 °C. This substitution also yielded a significant reduction in CO2 emissions (50 % reduction as the biochar loading amount doubled) from concrete manufacturing, showcasing biochar's potential for sustainable construction practices. Despite not fully supporting the initial hypothesis, the study demonstrated biochar's viability in reducing carbon footprint while maintaining concrete strength under certain fire conditions.

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来源期刊
Composites Part C Open Access
Composites Part C Open Access Engineering-Mechanical Engineering
CiteScore
8.60
自引率
2.40%
发文量
96
审稿时长
55 days
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