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Experimental investigation on leaching behavior of ultra-high performance concrete submitted to a flow environment

材料科学 抗压强度 抗弯强度 浸出(土壤学) 复合材料 高效减水剂 氯化铵 胶凝的 多孔性 耐久性 氯化物 纤维 水泥 冶金 化学 环境科学 土壤水分 有机化学 土壤科学
作者
Liang Tao,Jikai Zhou,Qingqing Wu
出处
期刊:Construction and Building Materials [Elsevier BV]
卷期号:372: 130843-130843 被引量:1
标识
DOI:10.1016/j.conbuildmat.2023.130843
摘要

Ultra-high performance concrete (UHPC) is a cementitious material with exceptional durability. Uncertain is, however, the leaching behavior of UHPC in a flow environment. To investigate the leaching behavior of UHPC under the influence of moving water, accelerated tests simulating various naturally flowing solution conditions were conducted. The effect of flow environment, steel fiber content, and superplasticizer content on the degradation of UHPC was investigated. There are three flow velocities: static (0 m/s), low (0.3 m/s), and high (2 m/s), as well as three leaching solutions: 6 mol/L ammonium chloride, 3 mol/L ammonium chloride, and natural groundwater. Mass loss, porosity, degradation depth, flexural strength, and compressive strength were measured. The result showed that the maximum degradation of UHPC was observed in a high-velocity flow environment containing 6 mol/L ammonium chloride. Porosity, mass loss, degradation depth, and compressive strength loss following deterioration declined as the steel fiber content rose, reaching a minimum at 2% steel fiber in the same flow environment. The loss of flexural strength decreases and subsequently increases as the steel fiber content increases. The largest reduction in compressive strength was 16.4%, and the maximum reduction in flexural strength was 48.2%. At the same degraded ratio, the compressive strength loss of UHPC is significantly less than that of ordinary concrete. A predicted model for the loss of UHPC's cubic compressive strength is established.

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