硅酸盐学报

外加电压下氯离子在水泥基材料中的迁移特性及

相互作用的研究进展

作者：何宗旭史才军胡翔张家科

单位：湖南大学土木工程学院长沙 410082

关键词：水泥基材料氯离子迁移电加速试验氯离子结合微观结构

分类号：TQ172

出版年,卷(期):页码：2015,43(8):1111-1119

DOI：10.14062/j.issn.0454-5648.2015.08.13

摘要：

实验室常用外加电压来加速氯离子在水泥基材料中的迁移，缩短试验时间。本文对外加电压下不同因素对氯离子迁移特性的影响、外加电压对氯离子结合和解吸附、水泥基材料孔结构及水化产物的影响进行了综述。外加电压的变化对非稳态电迁移系数影响不明显，氯离子浓度对稳态迁移系数有影响，使用矿物掺合料时不同试验得到的迁移系数间的差异变小，硅灰作用最明显，其次是粉煤灰。不同试验条件时电压对氯离子的结合的影响也不同。反加电压会促使结合氯离子的解吸附及200 nm 以下孔结构的细化，同时对水化硅酸钙(C–S–H)的分解及Friedel’s 盐形成也有一定的影响。

Applied voltage methods are used to accelerate the migration of chloride ions and to shorten the testing time. This paperreviewed the influence of factors on the chloride ion migration characteristics in an electrical field, and the effect of applied voltageon the chloride binding-desorption, pore structure and hydration products. The applied voltage has a slight effect on the unsteadyelectro-migration coefficient. Chloride ion concentration mainly affects the steady state migration coefficient. The use of mineraladmixture can reduce the difference between chloride diffusion coefficients obtained by different test methods under applied voltage,especially the use of silica fume. The effect of applied voltage on the chloride ion binding is varying under different test conditions.The reverse voltage can prompt the desorption of combined chloride ions, which has an effect on the refinement of pore structure ofbelow 200 nm, decomposition of hydrated calcium silicate (C–S–H) and formation of Friedel’s salt.

基金项目：

国家自然科学基金（51378196；U1305243）项目资助。

作者简介：

第一作者：何宗旭(1990—)，男，硕士研究生。通信作者：史才军(1963—)，男，博士，教授。

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