水压作用下水和水中氯离子对混凝土的渗透

Y. Zhao, F. Wittmann, P. Zhang, P. Wang, T. Zhao
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引用次数: 1

摘要

近年来,人们对溶解离子通过毛细管吸收(对流)和扩散向混凝土中的迁移进行了详细的研究。这两个过程被认为是氯离子渗透到与海水或含除冰盐的水接触的混凝土中的主要机制。然而,在实践中,存在许多钢筋混凝土结构,如港口建筑、海底隧道或桥梁支柱,在相当大的静水压力下与含盐水永久或暂时接触。到目前为止,对静水压力作用下氯化物渗入混凝土的研究也进行了相同程度的研究。研究了在静水压力作用下氯化物对五种混凝土的渗透性能。特别研究了混合水泥的影响。结果表明,小于0.1 MPa的压力对氯离子渗透几乎没有影响。当水压超过0.3 MPa时,在一定暴露时间内,水和氯化物的渗透深度以及氯化物含量均显著增加。粉煤灰和矿渣掺入硅酸盐水泥后,其抗水渗透能力和抗氯离子渗透能力均有所提高。较长的潮湿固化时间降低了氯化物渗透的速度。如果含水盐溶液在静水压力下渗透到混凝土中,溶解的氯化物不跟随渗透的水,而是积聚在表面附近的区域。混凝土的多孔结构显然起着分子过滤器的作用。水与氯离子渗透深度之比可以用指数函数表示。
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Penetration of Water and Chloride Dissolved in Water into Concrete under Hydraulic Pressure
Migration of dissolved ions into concrete by capillary absorption (convection) and by diffusion has been studied in great detail in recent years. These two processes are considered to be major mechanisms of chloride penetration into concrete in contact with seawater or with water containing deicing salt. In practice, however, there exist many reinforced concrete structures, such as harbor constructions, subsea tunnels or bridge pillars, which are in permanent or temporary contact with salt containing water under considerable hydrostatic pressure. Penetration of chloride into concrete under hydrostatic pressure has been investigated to the same extent so far. Chloride penetration into concrete under the influence of a hydrostatic pressure has been studied on five types of concrete. The influence of blended cements has been investigated in particular. The results indicate that a pressure less than 0.1 MPa has hardly any influence on chloride penetration. Once the water pressure overcomes 0.3 MPa, the water and chloride penetration depth as well as the chloride content at a given exposure time increase significantly. If fly ash and slag are added to Portland cement, the resistance with respect to water and chloride penetration increases. Longer moist curing reduces the rate of chloride penetration. If an aqueous salt solution penetrates into concrete under hydrostatic pressure, the dissolved chloride does not follow the penetrating water but it is accumulated in a surface near zone. The porous structure of concrete obviously acts like a molecular filter. The ratio between water and chloride penetration depths can expressed by means of an exponential function.
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