Synergistic Effects of Silica Fume And Steel Slag And Steel Slag In Advanced Concrete Composites

Rishabh Hirwani, Dr. R.R.L Birali
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Abstract

Concrete is highly versatile, capable of withstanding harsh environments and achieving inspirational forms. Modern advancements focus on enhancing its performance through innovative chemical admixtures and supplementary cementitious materials (SCMs). SCMs, often industrial byproducts like fly ash, silica fume, ground granulated blast furnace slag, and steel slag, replace a portion of Portland cement, reducing costs and environmental impact while improving concrete properties. Silica fume, a particularly successful SCM, significantly enhances concrete's strength and durability, especially in high-strength applications. Steel slag, a byproduct of steel manufacturing, shows potential as an aggregate in concrete, despite its tendency to expand due to free lime and magnesium oxides. Proper treatment and the use of pozzolanic materials like silica fume can mitigate this expansion. This study investigates the mechanical properties of concrete mixes using ACC brand slag cement, fly ash cement, and their blend (1:1), modified with 10% and 20% silica fume. Natural sand (zone II, IS 383-1982) serves as the fine aggregate, and steel slag (20 mm down) as the coarse aggregate, mixed in a 1:1.5:3 ratio. Tests on 7-day, 28- day, and 56-day compressive strengths, flexural strength, porosity, and capillary absorption were conducted. Key findings include an increased water requirement with higher silica fume content, higher early strength gain with fly ash cement, and better later strength with slag cement. Silica fume reduces capillary absorption and porosity, particularly with fly ash cement. Keywords: Concrete, Steel Slag, Silica Fume, Supplementary Cementitious Materials, Durability, Strength.
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硅灰、钢渣和钢渣在先进混凝土复合材料中的协同效应
混凝土用途广泛,能够抵御恶劣的环境,并实现灵感迸发的造型。现代技术的进步主要是通过创新的化学外加剂和胶凝补充材料(SCM)来提高混凝土的性能。SCM 通常是粉煤灰、硅灰、磨细高炉矿渣和钢渣等工业副产品,可替代部分波特兰水泥,在改善混凝土性能的同时降低成本,减少对环境的影响。硅灰是一种特别成功的 SCM,可显著提高混凝土的强度和耐久性,尤其是在高强度应用中。钢渣是钢铁生产的副产品,尽管由于含有游离石灰和镁氧化物而容易膨胀,但作为混凝土的骨料仍有潜力。适当的处理方法和使用硅灰等混合材料可以缓解这种膨胀。本研究调查了使用 ACC 牌矿渣水泥、粉煤灰水泥和它们的混合材(1:1),并用 10% 和 20% 的硅灰进行改性的混凝土混合物的机械性能。天然砂(II 区,IS 383-1982)作为细骨料,钢渣(20 毫米)作为粗骨料,以 1:1.5:3 的比例混合。对 7 天、28 天和 56 天的抗压强度、抗折强度、孔隙率和毛细管吸收率进行了测试。主要发现包括硅灰含量越高,需水量越大,粉煤灰水泥的早期强度增益越高,矿渣水泥的后期强度越好。硅灰降低了毛细管吸收率和孔隙率,尤其是粉煤灰水泥。关键词混凝土、钢渣、硅灰、辅助胶凝材料、耐久性、强度。
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