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地质聚合物废料的掺入对在温度和酸性环境作用下的粘结基体特性的影响。

Influence of the Integration of Geopolymer Wastes on the Characteristics of Binding Matrices Subjected to the Action of Temperature and Acid Environments.

作者信息

Hattaf Rabii, Aboulayt Abdelilah, Lahlou Nouha, Touhami Mohamed Ouazzani, Gomina Moussa, Samdi Azzeddine, Moussa Redouane

机构信息

Laboratory of Physics and Chemistry of Inorganic Materials, Faculty of Sciences Aïn Chock, University Hassan II Casablanca, Casablanca 53306, Morocco.

National School of Architecture of Tetouan, Avenue Baghdad, Touabel Soufla, Tetouan 93040, Morocco.

出版信息

Polymers (Basel). 2022 Feb 25;14(5):917. doi: 10.3390/polym14050917.

DOI:10.3390/polym14050917
PMID:35267740
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8912663/
Abstract

Recycling geopolymer waste, by reusing it as a raw material for manufacturing new geopolymer binding matrices, is an interesting asset that can add to the many technical, technological and environmental advantages of this family of materials in the construction field. This can promote them as promising alternatives to traditional materials, such as Portland cements, which are not so environmentally friendly. Recent studies have shown that the partial replacement of reactive aluminosilicates (metakaolin and fly ash) up to a mass rate of 50% by geopolymer waste does not significantly affect the compressive strength of the new product. In line with these findings, this paper investigates the effects of aggressive environments, i.e., high temperatures (up to 1000 °C) and acid attacks (pH = 2), on the characteristics of these new matrices. Different techniques were used to understand these evolutions: mineralogical analysis by X-ray diffraction (XRD), thermogravimetry-differential thermal analysis (TGA-DTA), mechanical characterization and scanning electron Microscopy (SEM) observations. The results are very satisfactory: in the exposure temperature range explored, the new matrices containing geopolymer waste suffered losses in compressive strength similar to those of the matrices without waste (considered as materials reference). On the other hand, the new matrices exhibited good chemical stability in acid media. These results confirm that the reuse of geopolymer waste is a promising recycling solution in the construction sector.

摘要

通过将地质聚合物废料作为制造新型地质聚合物粘结基体的原材料进行回收利用,是一项有趣的资产,可为该材料家族在建筑领域的诸多技术、工艺和环境优势增添助力。这可以将它们推广为传统材料(如波特兰水泥)的有前途的替代品,因为传统材料对环境不太友好。最近的研究表明,用地质聚合物废料以高达50%的质量比部分替代活性铝硅酸盐(偏高岭土和粉煤灰)不会显著影响新产品的抗压强度。基于这些发现,本文研究了恶劣环境,即高温(高达1000°C)和酸侵蚀(pH = 2)对这些新基体特性的影响。采用了不同的技术来了解这些变化:通过X射线衍射(XRD)进行矿物学分析、热重-差热分析(TGA-DTA)、力学表征以及扫描电子显微镜(SEM)观察。结果非常令人满意:在所探索的暴露温度范围内,含有地质聚合物废料的新基体抗压强度的损失与不含废料的基体(作为材料参考)相似。另一方面,新基体在酸性介质中表现出良好的化学稳定性。这些结果证实,地质聚合物废料的再利用是建筑行业一种有前途的回收解决方案。

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