Effect of limestone fillers on CO2 and water vapour diffusion in carbonated concrete

Sarah Steiner , Tilo Proske , Frank Winnefeld , Barbara Lothenbach
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引用次数: 3

Abstract

Replacing Portland cement clinker partially with limestone powder offers economic and ecological benefits but may decrease the resistance against carbonation. The diffusivity of carbon dioxide and the moisture conditions in concrete significantly influence the carbonation rate. Thus a test method was developed to determine the effective CO2 diffusion coefficient (DCO2). Additionally, the water vapour diffusion coefficients (DH2O) were analysed. DCO2 and DH2O increase with increasing water-to-cement ratios (w/c, related to the CEM I content in the binder). At the same w/c ratio, higher amounts of limestone decrease DCO2 and DH2O and increase compressive strength. DCO2 and DH2O show a linear correlation for samples with w/c ≥ 0.6 but a non-linear relationship for dense concrete (w/c ≤ 0.5). DCO2 ranges from 2.6−9 m2/s to 1.9−7 m2/s for w/c of 0.5 and 1.25, respectively. DH2O were between 2.8−8 m2/s and 4.5−7 m2/s. A model for estimating DCO2 in concrete with high limestone contents was derived based on the experimental analysis of the correlations between mix design, compressive strength, and CO2 diffusion.

Abstract Image

石灰石填料对碳化混凝土中CO2和水蒸气扩散的影响
用石灰石粉代替部分硅酸盐水泥熟料具有经济效益和生态效益,但可能会降低抗碳化能力。二氧化碳的扩散率和混凝土中的水分条件对碳化速率有显著影响。因此,开发了一种测定有效CO2扩散系数(DCO2)的测试方法。此外,还分析了水蒸气扩散系数(DH2O)。DCO2和DH2O随着水灰比(w/c,与胶结剂中CEM I含量有关)的增加而增加。在相同的w/c比下,石灰石掺量的增加降低了DCO2和DH2O,提高了抗压强度。DCO2与DH2O在w/c≥0.6时呈线性相关,而在w/c≤0.5时呈非线性关系。当w/c为0.5和1.25时,DCO2变化范围为2.6 ~ 9 m2/s ~ 1.9 ~ 7 m2/s。DH2O在2.8 ~ 8 m2/s ~ 4.5 ~ 7 m2/s之间。通过对配合比设计、抗压强度和二氧化碳扩散之间相关性的实验分析,推导出了一个估算高石灰石含量混凝土DCO2的模型。
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