Promoting Sustainable Green Infrastructure: Experimental and Numerical Investigation of Concrete Reinforced with Recycled Steel Fibers

Izhar Ahmad, M. Shokouhian
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Abstract

Accumulation of waste tires and their respective fast increase are posing a great threat to the environment. Recycled steel fiber (RSF) extracted from the waste tires can be used in reinforced concrete considering proper fiber content and aspect ratio. Current research study aims to investigate the influence of RSF content (0.5, 1.5 and 2.25%) on the mechanical properties such as compressive strength, split tensile and flexural strength of recycled steel fiber reinforced concrete (RSFRC). The study also focused on developing numerical models such as fracture-plastic constitutive models using ATENA to validate the experimental results. The study was further extended by developing a slab model as a bus pad to find the behavior of RSFRC bus pad in response to the service loads and soil stiffness. In Baltimore City, inadequate design of bus pads posed strength and serviceability problems and needed to be investigated. From the test results, it was found that RSFRC mixture containing 1.5% RSF exhibited optimized behavior. Test results showed that 28-day compressive, split tensile and flexural strength increased by 10.7, 39.3, and 10.4%, respectively for the RSFRC mixture containing 1.5% RSF as compared to the control mixture without RSF and other RSF containing mixtures. The Numerical model was developed and validated using experimental data. Various models of bus pads were then analyzed, focusing on their maximum load-bearing capacity and flexural toughness. It was observed that the maximum load-bearing capacity and flexural toughness of the bus pads increased with the use of RSFRC. These findings offer valuable insights for the construction industry, facilitating the efficient utilization of RSFRC in concrete applications.
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促进可持续绿色基础设施:用回收钢纤维加固混凝土的实验和数值研究
废旧轮胎的积累及其相应的快速增长对环境构成了巨大威胁。考虑到适当的纤维含量和长径比,从废旧轮胎中提取的回收钢纤维(RSF)可用于钢筋混凝土。目前的研究旨在调查 RSF 含量(0.5%、1.5% 和 2.25%)对再生钢纤维加固混凝土(RSFRC)机械性能(如抗压强度、劈裂拉伸强度和抗折强度)的影响。研究还重点开发了数值模型,如使用 ATENA 的断裂-塑性构造模型,以验证实验结果。研究还进一步扩展,将板块模型开发成公交车站垫,以了解 RSFRC 公交车站垫对服务荷载和土壤刚度的响应行为。在巴尔的摩市,公交车停靠站设计不当会造成强度和适用性问题,因此需要进行调查。测试结果表明,含有 1.5% RSF 的 RSFRC 混合物具有最佳性能。试验结果表明,与不含 RSF 的对照混合物和其他含 RSF 的混合物相比,含 1.5% RSF 的 RSFRC 混合物的 28 天抗压、劈裂拉伸和抗弯强度分别提高了 10.7%、39.3% 和 10.4%。利用实验数据开发并验证了数值模型。然后分析了各种母线垫模型,重点是它们的最大承载能力和抗弯韧性。结果表明,随着 RSFRC 的使用,母线槽的最大承载能力和抗弯韧性都有所提高。这些发现为建筑行业提供了宝贵的见解,有助于在混凝土应用中有效利用 RSFRC。
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