Development of novel ultra-high-performance lightweight concrete modified with dehydrated cement powder and aerogel

IF 4.7 3区 工程技术 Q1 CONSTRUCTION & BUILDING TECHNOLOGY Journal of Sustainable Cement-Based Materials Pub Date : 2023-11-05 DOI:10.1080/21650373.2023.2278134
Ahmed Ali A. Shohan, Osama Zaid, Mohamed M. Arbili, Saleh Hamed Alsulamy, Wafeek Mohamed Ibrahim
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Abstract

AbstractCurrently, researchers emphasize creating eco-friendly, ultra-high-performance lightweight concrete (UHPLC) due to the extensive cement demand of ultra-high-performance concrete. This study aimed to develop such UHPLC by incorporating dehydrated cement powder (DCP) and aerogel (AG) at varying levels (5-25%) alongside double-hooked end steel fibers (DHE-SFs). Objectives were to enhance strength, durability, density, and thermal/acoustic properties. Results revealed reduced flowability with higher DCP and AG content. 5%, 10%, and 15% DCP and AG improved compressive strength (17.3%) via better packing and bond formation. Density decreased up to 8.3% with more DCP and AG. Modified mixtures resisted sulfate attack and exhibited increased compressive strength retention. Shrinkage reduced to 958 µ with more DCP and AG, notably in M6-DCP25-AG25. Thermal stability improved with only 75.4% mass loss at 1000 °C, while thermal conductivity decreased to 0.274 W/m·°C. Sound absorption and pore volume increased in modified mixes. X-ray diffraction analysis showed higher crystalline phases with increased DCP and AG.Keywords: thermal analysisacousticspore structureshrinkageporosity AcknowledgementsThe authors extend their appreciation to the Deanship of Scientific Research at King Khalid University for funding this work through a large group Research Project under grant number RGP2/351/44.Disclosure statementNo potential conflict of interest was reported by the authors.Data availability statementThe data are available from the corresponding author upon request.Ethical approvalAll authors approve that the research was performed under all the ethical norms.Consent to publishAll authors consent to publish this paper.Additional informationFundingThe authors extend their appreciation to the Deanship of Scientific Research at King Khalid University for funding this work through a large group Research Project under grant number RGP2/351/44.
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脱水水泥粉和气凝胶改性新型超高性能轻量化混凝土的研制
摘要目前,由于高性能混凝土对水泥的广泛需求,研究人员强调创造环保,高性能轻质混凝土(UHPLC)。本研究旨在通过加入不同水平(5-25%)的脱水水泥粉(DCP)和气凝胶(AG)以及双钩端钢纤维(dhe - sf)来开发这种UHPLC。目的是提高强度、耐久性、密度和热/声学性能。结果表明,随着DCP和AG含量的增加,流动性降低。5%、10%和15%的DCP和AG通过更好的填料和粘结形成提高了抗压强度(17.3%)。随着DCP和AG的增加,密度降低了8.3%。改性混合物抗硫酸盐侵蚀,并表现出增加的抗压强度保持。随着DCP和AG的增加,收缩率降低到958µ,特别是在M6-DCP25-AG25中。在1000℃时,热稳定性得到改善,质量损失仅为75.4%,导热系数降至0.274 W/m·°C。改性后的混合料吸声量和孔隙体积增加。x射线衍射分析表明,随着DCP和AG的增加,晶相增多。关键词:热分析;声学;孢子结构;收缩;孔隙度作者感谢国王哈立德大学的科学研究主任通过一个大型小组研究项目为这项工作提供资金,资助号为RGP2/351/44。披露声明作者未报告潜在的利益冲突。数据可用性声明数据可根据要求从通讯作者处获得。伦理批准所有作者同意该研究是在所有伦理规范下进行的。所有作者同意发表这篇论文。作者感谢哈立德国王大学的科学研究主任通过一个大型团体研究项目为这项工作提供资金,资助号为RGP2/351/44。
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来源期刊
CiteScore
6.60
自引率
15.90%
发文量
71
期刊介绍: The Journal of Sustainable Cement-Based Materials aims to publish theoretical and applied researches on materials, products and structures that incorporate cement. The journal is a forum for discussion of research on manufacture, hydration and performance of cement-based materials; novel experimental techniques; the latest analytical and modelling methods; the examination and the diagnosis of real cement and concrete structures; and the potential for improved cement-based materials. The journal welcomes original research papers, major reviews, rapid communications and selected conference papers. The Journal of Sustainable Cement-Based Materials covers a wide range of topics within its subject category, including but are not limited to: • raw materials and manufacture of cement • mixing, rheology and hydration • admixtures • structural characteristics and performance of cement-based materials • characterisation techniques and modeling • use of fibre in cement based-materials • degradation and repair of cement-based materials • novel testing techniques and applications • waste management
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