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引用本文:	张云清,余红发,孙伟,王甲春,曹文涛,周鹏.城市混凝土桥梁盐冻病害调查与研究[J].建筑材料学报,2012,(5):665-670

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城市混凝土桥梁盐冻病害调查与研究
张云清¹, 余红发², 孙伟³, 王甲春⁴, 曹文涛⁵, 周鹏⁶
1.南京农业大学工学院，江苏南京210031;2.南京航空航天大学土木工程系，江苏南京210016;3.东南大学材料科学与工程学院，江苏南京211189;4.厦门理工学院建筑工程系，福建厦门361024;5.江苏省交通科学研究院股份有限公司，江苏南京211112;6.南京市长安建筑规划设计有限公司，江苏南京210002

摘要:

为了探究盐冻作用下城市混凝土桥梁的破坏特征及评价盐冻环境混凝土桥梁主体结构的服役现状，通过现场调研、检测、取样和室内试验，研究了混凝土的主要物理力学性能、氯离子质量分布和表层混凝土及钢筋锈蚀物的微观结构.结果表明：盐冻作用下混凝土桥梁使用13a以后，其主体结构发生了严重的除冰盐冻融破坏和钢筋锈蚀破坏，混凝土的氯离子结合能力很低，自由氯离子浓度很高，钢筋锈蚀物中物理吸附了大量的氯离子，且氯离子迁移多堆积于靠近钢筋表面的混凝土层，其总氯离子质量高于钢筋表面及受力钢筋间混凝土近2倍；实际混凝土结构工程在盐冻作用下，混凝土保护层的氯离子浓度分布规律并不符合Fick第二扩散定律；在盐冻环境作用下进行混凝土桥梁结构的耐久性设计时，必须提高其抗盐冻能力、抗氯离子扩散渗透能力，氯离子扩散模型必须考虑表层效应.

关键词: 混凝土除冰盐冻融循环剥落氯离子

DOI：10.3969/j.issn.1007 9629.2012.05.016

分类号:

基金项目:国家重点基础研究发展计划（973计划）项目（2009CB623203）；国家自然科学基金资助项目（51178221）；2008年江苏省“六大人才高峰”高层次人才项目；南京航空航天大学博士生创新基金资助项目（BCXJ07 04）

Investigation and Study of Durability of Bridge under Salt Scaling

ZHANG Yun qing¹, YU Hong fa², SUN Wei³, WANG Jia chun⁴, CAO Wen tao⁵, ZHOU Peng⁶

1.College of Engineering, Nanjing Agricultural University, Nanjing 210031, China;2.Department of Civil Engineering, Nanjing University of Aeronautics and Astronautics, Nanjing 210016, China;3.School of Materials Science and Engineering, Southeast University, Nanjing 211189, China;4.Department of Construction Engineering, Xiamen University of Technology, Xiamen 361024, China;5.Jiangsu Transportation Research Institute Co., Ltd, Nanjing 211112, China;6.Nanjing Chang an Town Planning and Architectural Design Co., Ltd., Nanjing 210002, China

Abstract:

For the purpose of exploring the failure characteristics of urban concrete bridge under deicing salt scaling and evaluating the existing structure condition, main physical and mechanical properties of the material, chloride ion concentration distribution, and the microstructure of concrete cover and corroded steel bar were studied through site investigation, sampling and laboratory experiments. The results show that serious salt freezing damage and steel bar corrosion occur in the main structure of the bridge, when the bridge has been used under deicing salt scaling for 13 years. Chloride ion binding capacity of concrete is quite weak; meanwhile, free chloride ion concentration is very high. The products from bar corrosion adsorb a large amount of chloride ions physically. Microstructure analysis indicates that chloride ions migrate to the interface of rebar and concrete, and its total chlorine concentration is almost twice that in other location, such as surface or interface of steel bars. The distribution behavior of chloride ion concentration of concrete cover does not fit the Ficks second diffusion law. Therefore, durability design of bridge structures under deicing salt scaling needs to improve salt freezing resistance and chloride ion permeability, moreover, surface effects must be taken into account in the chloride diffusion model when life design is carried on.

Key words: concrete deicing salt freeze thaw cycle spalling chloride ion