Mechanical, durable, and microstructural properties of cement mortar mixes containing fine reclaimed asphalt pavement aggregates and zinc waste

IF 1.4 4区工程技术 Q3 CONSTRUCTION & BUILDING TECHNOLOGY

Advances in Cement Research Pub Date : 2023-12-09 DOI:10.1680/jadcr.23.00046

Surendra Kumar Saini, Surya Kant Sahdeo, G.D.R.N. Ransinchung, Praveen Kumar

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引用次数: 0

Abstract

The cement mortar mixes were developed with the intent of testing the suitability of fine graded reclaimed asphalt pavement aggregates as a replacement for naturally fine materials. The natural fine aggregates were replaced in multiple percent levels of 25%, 50%, 75%, and 100% by weight. The results demonstrate that the mechanical qualities of the mortar mix are deteriorating. To address this, zinc industry waste - jarosite was used as a part replacement for cement in proportions of 5%, 10%, and 15%. Jarosite improved the microstructural, mechanical, and shrinkage properties. For instance, when comparing with the control mix, the mix containing 25% fine reclaimed asphalt pavement aggregates shows a reduction of 5.5% in hardened density and 14% in compressive strength. On the other hand, when 10% jarosite is included in the 25% fine reclaimed asphalt pavement mix, there is an observed increase of 4.85% in hardened density and 7% in compressive strength with respect to the mix containing 25% fine reclaimed asphalt pavement aggregates. As a result, the current study proposes using 10% jarosite when fine reclaimed asphalt pavement aggregates are used to make cement mortar mixes. Furthermore, a cost analysis is performed to determine the difference in construction costs. These findings are expected to inspire rational mix design recommendations for mortar mixes including fine reclaimed asphalt pavement aggregates, as well as bring environmental and economic benefits by lowering carbon footprints.

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含有再生沥青路面细集料和锌废料的水泥砂浆混合物的机械、耐久和微观结构特性

开发水泥砂浆混合料的目的是测试细级配再生沥青路面集料替代天然细料的适用性。天然细集料的替代率为 25%、50%、75% 和 100%（按重量计）。结果表明，砂浆混合料的机械质量正在下降。为解决这一问题，锌工业废料--金刚砂被用作水泥的部分替代品，比例分别为 5%、10% 和 15%。金刚砂改善了微观结构、机械和收缩性能。例如，与对照组混合料相比，含有 25% 再生沥青路面细集料的混合料的硬化密度降低了 5.5%，抗压强度降低了 14%。另一方面，如果在 25% 的细再生沥青路面混合料中加入 10%的焦石棉，与含有 25% 细再生沥青路面集料的混合料相比，硬化密度增加了 4.85%，抗压强度增加了 7%。因此，本研究建议在使用再生沥青路面细集料制作水泥砂浆混合料时，使用 10%的焦石棉。此外，还进行了成本分析，以确定施工成本的差异。这些研究结果有望为包括再生沥青路面细集料在内的砂浆混合料提供合理的混合料设计建议，并通过降低碳足迹带来环境和经济效益。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Advances in Cement Research 工程技术-材料科学：综合

CiteScore

3.70

自引率

5.00%

发文量

审稿时长

3.2 months

期刊介绍： Advances in Cement Research highlights the scientific ideas and innovations within the cutting-edge cement manufacture industry. It is a global journal with a scope encompassing cement manufacture and materials, properties and durability of cementitious materials and systems, hydration, interaction of cement with other materials, analysis and testing, special cements and applications.