Heat resistance and sorptivity of an air-entrained concrete containing mineral admixtures and CBA

IF 2.6 Q1 ENGINEERING, MULTIDISCIPLINARY Journal of Engineering Design and Technology Pub Date : 2022-06-01 DOI:10.1108/jedt-01-2022-0068
Sandeep Singh, S. Sharma, M. Akbar
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引用次数: 1

Abstract

Purpose The purpose of this work is to improve the air entrainment capacity of a concrete by using fine mineral admixtures such as fly ash (FA) and silica fume (SF) as cement substitute, and coal bottom ash (CBA) as fine aggregate substitute. Air entrainment capacity has been studied indirectly as a measure of heat resistance of concrete. Literature has suggested that mineral admixtures improve the air absorption in the paste component of the concrete, on the one hand, whereas they perform pore and grain size refinement, on the other, thereby reducing the air entrainment. CBA, which being porous, creates the possibility of air adsorption by the aggregate component. Therefore, the study finds out whether a double benefit of adding both of these materials will be achieved, or CBA will try to improve the deficiency in the air entrainment created by the mineral admixtures. Design/methodology/approach Air-entrained concrete (AEC) mixes were constituted in three groups. First group represents mixes with natural fine aggregates only, and second with 25% fine aggregates substituted by CBA. Progressively, the third group has 50% fine aggregates substituted with CBA. In all the three groups, cement was substituted with FA and SF @ 0%, 20% and 40%, and 0%, 5% and 10%, respectively, thereby creating four binary and four ternary mixes corresponding to each group. Compressive and flexural strength tests were conducted at 28 days on the concrete mixes pre and post high-temperature heat treatment, i.e. 100°C, 200°C and 400°C, respectively. This study also examines the microstructure characteristics of AEC after 14 days of curing via X-ray diffraction. Sorptivity test was also conducted to estimate the capillary and air-entrained voids in concrete. Findings It was found that a concrete mix containing 20% FA and 10% SF along with 50% CBA could give similar post-heated strength to a normal (without mineral admixtures) AEC. In AECs where only CBA is present and cement paste is not substituted, both of the pre- and post-heated strengths of concrete reduce. Also, some mixtures containing large amounts of mineral admixtures in concrete with nil CBA show a high reduction in post-heated strength though they show good pre-heated strength. Therefore, mineral admixtures and CBA complement each other in improving the post-heated strength. Air pore structure found from sorptivity test also verifies these results. Originality/value AEC is very helpful for insulation of buildings during summer season by absorbing heat waves. AEC containing FA and CBA reduces carbon footprint because of substitution of cement and it also helps to conserve natural resources by the use of CBA in place of fine aggregates.
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掺有矿物掺合料和CBA的加气混凝土的耐热性和吸附性
目的采用粉煤灰(FA)、硅灰(SF)等细矿物掺合料代替水泥,粉煤灰(CBA)代替细骨料,提高混凝土的掺气性能。掺气能力已被间接研究作为衡量混凝土耐热性的指标。文献表明,矿物掺合料一方面提高了混凝土浆体成分中的空气吸收,另一方面又改善了孔隙和粒度,从而减少了空气夹带。CBA是多孔的,它创造了集料组分吸附空气的可能性。因此,该研究发现,添加这两种材料是否会实现双重效益,或者CBA是否会试图改善矿物掺合料造成的空气夹带不足。设计/方法/方法加气混凝土(AEC)混合料分为三组。第一组代表仅使用天然细骨料的混合物,第二组代表用CBA替代25%细骨料的混合料。逐渐地,第三组有50%的细集料被CBA取代。在所有三组中,分别用FA和SF@0%、20%和40%以及0%、5%和10%代替水泥,从而产生对应于每组的四种二元和四种三元混合物。抗压强度和弯曲强度试验在28 在高温热处理前和高温热处理后,即分别为100°C、200°C和400°C。本研究还考察了14岁后AEC的微观结构特征 通过X射线衍射固化的天数。还进行了吸附性试验,以估计混凝土中的毛细空隙和夹带空气的空隙。研究发现,含有20%FA和10%SF以及50%CBA的混凝土混合物可以提供与正常(不含矿物掺合料)AEC相似的后加热强度。在仅存在CBA且不使用水泥浆的AEC中,混凝土的预热和后加热强度都会降低。此外,一些在无CBA的混凝土中含有大量矿物掺合料的混合物显示出加热后强度的高降低,尽管它们显示出良好的预热强度。因此,矿物掺合料和CBA在提高后热强度方面是相辅相成的。吸附性试验中发现的气孔结构也验证了这些结果。独创性/价值AEC通过吸收热浪对夏季建筑的隔热非常有帮助。含有FA和CBA的AEC由于取代了水泥而减少了碳足迹,并且通过使用CBA代替细骨料也有助于保护自然资源。
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来源期刊
Journal of Engineering Design and Technology
Journal of Engineering Design and Technology ENGINEERING, MULTIDISCIPLINARY-
CiteScore
6.50
自引率
21.40%
发文量
67
期刊介绍: - Design strategies - Usability and adaptability - Material, component and systems performance - Process control - Alternative and new technologies - Organizational, management and research issues - Human factors - Environmental, quality and health and safety issues - Cost and life cycle issues - Sustainability criteria, indicators, measurement and practices - Risk management - Entrepreneurship Law, regulation and governance - Design, implementing, managing and practicing innovation - Visualization, simulation, information and communication technologies - Education practices, innovation, strategies and policy issues.
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