Al-anodizing waste as a supplementary cementitious material for 3D-printed Portland cement

Waste Management Bulletin Pub Date : 2025-03-04 DOI:10.1016/j.wmb.2025.03.001

Jairon Gomes da Silveira Júnior , Rafael Dors Sakata , Lucas Onghero , Paulo Ricardo de Matos , Erich David Rodríguez , Lisandro Simão , Antonio Pedro Novaes de Oliveira , Ruan Carlos de Araújo Moura , Carlos Eduardo Maduro de Campos , José Renato de Castro Pessôa , Marcelo Tramontin Souza

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Abstract

This study investigates the use of Al-anodizing waste (AAW), a byproduct of the anodizing process for aluminum and its alloys, in cement composites designed for 3D printing applications. For cementitious materials to be suitable for 3D printing, they must maintain adequate stability to support overlapping layers while also exhibiting sufficient flowability and open time for effective pumping. The incorporation of AAW aims to improve the rheological properties of these mixtures, enhancing both their open time and buildability. To evaluate the potential of AAW in 3D printing cement composites, a comprehensive approach was adopted. This included rheological analysis, flow table testing, investigations into buildability, and assessments of mechanical performance. Additional techniques, such as isothermal calorimetry and in situ X-ray diffraction, were employed to examine the effect of AAW on the hydration kinetics of cement pastes. The findings highlighted several advantages of incorporating AAW into cement-based formulations, such as improved buildability, quick adjustments in rheological properties, prolonged open times, enhanced mechanical performance, cost-effectiveness, and increased sustainability by transforming a commonly discarded material into a valuable resource for civil construction.

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铝阳极氧化废料作为3d打印硅酸盐水泥的补充胶凝材料

本研究调查了铝阳极氧化废料（AAW）在3D打印水泥复合材料中的应用，AAW是铝及其合金阳极氧化过程的副产品。对于适合3D打印的胶凝材料，它们必须保持足够的稳定性以支持重叠层，同时还具有足够的流动性和打开时间以进行有效泵送。加入AAW的目的是改善这些混合物的流变特性，提高它们的打开时间和可建造性。为了评估AAW在3D打印水泥复合材料中的潜力，采用了一种综合方法。这包括流变分析、流表测试、可建造性调查和机械性能评估。采用等温量热法和原位x射线衍射等技术，研究了AAW对水泥浆体水化动力学的影响。研究结果强调了将AAW加入水泥基配方的几个优点，例如改善可建造性、快速调整流变特性、延长打开时间、增强机械性能、成本效益，并通过将一种常见的废弃材料转化为民用建筑的宝贵资源而提高可持续性。

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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Waste Management Bulletin

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