Ghorbel Elhem, Omary Safiullah, Karrech Ali
Department of Civil Engineering, CY Cergy Paris Université, 5 Mail Gay Lussac, Neuville-sur-Oise, 95031 Cergy Pontoise Cedex, France.
INSA de Strasbourg-ICube Laboratory UMR 7357, 24, Boulevard de la Victoire, 67084 Strasbourg Cedex, France.
Materials (Basel). 2025 Apr 17;18(8):1849. doi: 10.3390/ma18081849.
This study explores the innovative use of recovered tire-derived aggregates in cement-based mortars to enhance thermal insulation and reduce environmental impact. The research addresses the pressing global challenge of managing end-of-life tires (ELTs), which are non-biodegradable and contribute significantly to waste management issues. By incorporating crumb rubber from recycled tires into mortars, this study investigates the feasibility of creating lightweight, thermally insulating mortars suitable for building repair and rehabilitation. The primary objective is to develop mortars that minimize structural load, decrease energy consumption in buildings, and promote the recycling of ELTs as a valuable resource. The study focuses on evaluating how varying crumb rubber content affects key properties such as workability, thermal conductivity, compressive strength, and fracture energy. Experimental tests were conducted to assess these properties, with the results indicating that mortars with up to 50% crumb rubber content exhibit improved thermal insulation and meet industry standards for non-structural repair applications. The methodology involved creating eight different mortar mixtures with varying proportions of crumb rubber particles (ranging from 0% to 100%). Each mixture was tested for physical and mechanical properties, including density, workability, air content, setting time, thermal conductivity, and strength. The experimental results showed that as the crumb rubber content increased, the thermal conductivity of the mortars decreased, indicating enhanced insulation properties. However, higher crumb rubber content led to reduced mechanical strength, highlighting the need for a balanced approach in material design. Key findings reveal that the air content of early-age mortar paste increases linearly with the crumb rubber replacement ratio, impacting the hardened behavior by concentrating stresses or facilitating the infiltration of damaging elements. The study also establishes relationships between mortar properties and crumb rubber content, contributing to the development of sustainable construction materials. The environmental benefits of recycling ELTs are emphasized, as this practice reduces the reliance on natural sand, a resource that is the second most consumed globally after water. This study underscores the viability of using crumb rubber from recycled tires in mortars for repair and rehabilitation purposes. The developed mortars, particularly those with 25% to 50% crumb rubber content, show promise as non-structural repair products, offering improved thermal insulation and reduced environmental impact.
本研究探索了回收轮胎衍生骨料在水泥基砂浆中的创新应用,以提高保温性能并减少环境影响。该研究应对了全球管理废旧轮胎(ELTs)的紧迫挑战,废旧轮胎不可生物降解,对废物管理问题有重大影响。通过将回收轮胎的胶粉掺入砂浆中,本研究调查了制造适用于建筑修复的轻质保温砂浆的可行性。主要目标是开发能使结构负荷最小化、降低建筑物能耗并促进将废旧轮胎作为宝贵资源进行回收利用的砂浆。该研究着重评估不同胶粉含量如何影响诸如工作性、导热系数、抗压强度和断裂能等关键性能。进行了实验测试以评估这些性能,结果表明胶粉含量高达50%的砂浆保温性能有所改善,并符合非结构修复应用的行业标准。该方法包括制备八种不同比例胶粉颗粒(从0%到100%)的砂浆混合物。每种混合物都测试了物理和力学性能,包括密度、工作性、含气量、凝结时间、导热系数和强度。实验结果表明,随着胶粉含量增加,砂浆的导热系数降低,表明保温性能增强。然而,较高的胶粉含量导致机械强度降低,突出了材料设计中采用平衡方法的必要性。主要发现表明,早期砂浆浆体的含气量随胶粉替代率呈线性增加,通过集中应力或促进有害元素的渗透影响硬化行为。该研究还建立了砂浆性能与胶粉含量之间的关系,有助于可持续建筑材料的开发。强调了回收废旧轮胎的环境效益,因为这种做法减少了对天然砂的依赖,天然砂是全球仅次于水的第二大消耗资源。本研究强调了在修复和翻新用途的砂浆中使用回收轮胎胶粉的可行性。所开发的砂浆,特别是胶粉含量为25%至50%的砂浆,有望成为非结构修复产品,具有改善的保温性能并减少环境影响。
