碳化与氯盐复合作用下水泥浆体的微结构演变

复合材料学报, 2015, 32(5): 1536-1546. doi: 10.13801/j.cnki.fhc1xb.20150428.005

碳化与氯盐复合作用下水泥浆体的微结构演变

柳俊哲 ^1, , 袁伟静 ^2, , 贺智敏 ^3, , 巴明芳 ^4, , 陈剑斌 ^5,

1.宁波大学建筑工程与环境学院,宁波,315211

2.宁波大学建筑工程与环境学院,宁波,315211

3.宁波大学建筑工程与环境学院,宁波,315211

4.宁波大学建筑工程与环境学院,宁波,315211

5.宁波大学建筑工程与环境学院,宁波,315211

基金项目: 宁波市科技计划(2013C51006,2015A610300) 国家自然科学基金(51278255,51308308,51478227)

关键词：水泥浆体 , 碳化 , 氯盐 , 复合作用 , 微结构特征

Microstructural evolution of cement paste under combined effect of carbonation and chloride salt

Keywords： cement paste , carbonation , chloride salt , combined effect , microstructure characteristic

为了阐明碳化与氯盐复合作用下硬化水泥浆体的微结构,基于X射线计算机断层扫描成像(X-CT)和电子探针微区分析(EPMA)技术探明了氯盐对水泥浆体碳化速率的影响,测定了碳化作用下水泥浆体内Cl、S和Na元素的浓度分布.结果表明:氯盐可细化养护龄期为28 d的水泥浆体孔结构,提高其密实度并减缓碳化速度;碳化作用下水泥浆体的碳化区易出现裂缝,二氧化碳气体通过这些裂缝扩散到水泥浆体内部进行碳化,致使水泥浆体碳化深度不均匀;碳化过程中Cl、S和Na元素向非碳化区迁移和浓缩,初始均匀分布的元素在碳化区含量减少,在非碳化区含量升高.所得结论为混凝土结构耐久性设计提供科学的理论依据.

参考文献

[1]	E. Zitrou;J. Nikolaou;P.E. Tsakiridis.Atmospheric corrosion of steel reinforcing bars produced by various manufacturing processes[J].Construction and Building Materials,20076(6):1161-1169.
[2]	柳俊哲;闫加利;巴明芳;贺智敏;陈剑斌.碳化对水泥混凝土内氯离子分布的影响[J].建筑材料学报,2015(1):113-117.
[3]	Pedro Faustino Marques;Carlos Chastre;Angela Nunes.Carbonation service life modelling of RC structures for concrete with Portland and blended cements[J].Cement & concrete composites,2013:171-184.
[4]	Service life of RC structures: Carbonation induced corrosion. Prescriptive vs. performance-based methodologies[J].Construction and Building Materials,20103(3):258.
[5]	Ha-Won Song;Chang-Hong Lee;Ki Yong Ann.Factors influencing chloride transport in concrete structures exposed to marine environments[J].Cement & concrete composites,20082(2):113-121.
[6]	杨礼明;余红发;麻海燕;周鹏;韩丽娟.混凝土在碳化和干湿循环作用下的抗硫酸盐腐蚀性能[J].复合材料学报,2012(5):127-133.
[7]	柳俊哲;邢锋;贺智敏;丁铸.钢筋混凝土中亚硝酸根与氯离子的临界摩尔比[J].硅酸盐学报,2010(4):615-620.
[8]	柳俊哲;孙武;陈剑斌;巴明芳;贺智敏;袁伟静.高碱含量水泥净浆的显微结构特征及碳化速率[J].硅酸盐学报,2014(8):1005-1010.
[9]	M. Castellote;C. Andrade;X. Turrillas.Accelerated carbonation of cement pastes in situ monitored by neutron diffraction[J].Cement and Concrete Research,200812(12):1365-1373.
[10]	Yang T.;Keller B.;Magyari E.;Hametner K.;Gunther D..Direct observation of the carbonation process on the surface of calcium hydroxide crystals in hardened cement paste using an Atomic Force Microscope[J].Journal of Materials Science,20039(9):1909-1916.
[11]	Seung-Jun Kwon;Ha-Won Song.Analysis of carbonation behavior in concrete using neural network algorithm and carbonation modeling[J].Cement and Concrete Research,20101(1):119-127.
[12]	Z. Owsiak.Alkali-aggregate reaction in concrete containing high-alkali cement and granite aggregate[J].Cement and Concrete Research,20041(1):7-11.
[13]	Rossella Pignatelli;Claudia Comi;Paulo J.M. Monteiro.A coupled mechanical and chemical damage model for concrete affected by alkali-silica reaction[J].Cement and Concrete Research,2013:196-210.
[14]	Zanqun Liu;Dehua Deng;Geert De Schutter;Zhiwu Yu.Chemical sulfate attack performance of partially exposed cement and cement + fly ash paste[J].Construction and Building Materials,20121(1):230-237.
[15]	E. A. Kishar.Hydration reaction of tricalciumaluminate in different systems[J].Cement and Concrete Research,20058(8):1638-1640.

上一张下一张

计量

下载量()
访问量()

作者相关

文章评分

您的评分：
1

0%
2

0%
3

0%
4

0%
5

0%

材料期刊网