混凝土无机表面处理技术研究进展

doi:10.11896/j.issn.1005-023X.2017.013.014

《材料导报》期刊社

2017, Vol. 31

Issue (13): 113-119 https://doi.org/10.11896/j.issn.1005-023X.2017.013.014

材料综述

混凝土无机表面处理技术研究进展

史才军, 汪越, 潘晓颖, 张健

湖南大学土木工程学院,长沙 410082

Advances in Inorganic Surface Treatment of Concrete

SHI Caijun, WANG Yue, PAN Xiaoying, ZHANG Jian

College of Civil Engineering, Hunan University, Changsha 410082

摘要
参考文献
相关文章
推荐阅读
Metrics

下载:

全文 ( PDF ) ( 1572KB )
输出: BibTeX | EndNote (RIS)

摘要混凝土表面处理能够显著改善混凝土表面渗透性,与有机表面处理相比,无机表面处理既能提升混凝土的耐久性,又具有较强的抗老化性能,发展前景比有机表面处理更广阔。对不同无机表面处理研究工作进行了总结对比,分析了无机表面处理的作用机理及其对混凝土耐久性的影响,以期为无机表面处理技术的进一步研究和其在工程中的应用提供指导和帮助。

	服务
	把本文推荐给朋友
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	史才军
	汪越
	潘晓颖
	张健

关键词: 无机表面处理方法抗老化作用机理耐久性

Abstract: Surface treatment could significantly improve the permeability of concrete surface. Compared with organic surface treatment agent, inorganic surface treatment agent could not only improve the durability of concrete but also ameliorate aging resis-tance. This paper compared different inorganic surface treatment technologies and analyzed the influences on permeability and the mechanism of inorganic surface treatment. Finally, suggestions are proposed for the further study and application of inorganic surface treatment technology.

Key words: inorganic surface treatment aging resistance function mechanism durability

出版日期: 2017-07-10 发布日期: 2018-05-04

ZTFLH:

TQ172

作者简介: 史才军:男,1963年生,博士,教授,主要从事土木工程材料方面的研究 E-mail:cshi@hnu.edu.cn

引用本文:

史才军, 汪越, 潘晓颖, 张健. 混凝土无机表面处理技术研究进展[J]. 《材料导报》期刊社, 2017, 31(13): 113-119.
SHI Caijun, WANG Yue, PAN Xiaoying, ZHANG Jian. Advances in Inorganic Surface Treatment of Concrete. Materials Reports, 2017, 31(13): 113-119.

链接本文:

https://www.mater-rep.com/CN/10.11896/j.issn.1005-023X.2017.013.014 或 https://www.mater-rep.com/CN/Y2017/V31/I13/113

1 Aguiar J B. Coatings for concrete protection against aggressive environments[J]. J Adv Concr Technol, 2008,6(1):243.
2 Moradllo M K, Shekarchi M, Hoseini M. Time-dependent perfor-mance of concrete surface coatings in tidal zone of marine environment[J]. Construction Building Mater,2012,30(5):198.
3 Yu Hongfa, Sun Wei. Diffusion equations of chloride ion in concrete under the combined action of durability factors[J]. J Building Mater,2002,5(3):240(in Chinese).
余红发, 孙伟. 混凝土在多重因素作用下的氯离子扩散方程[J]. 建筑材料学报,2002,5(3):240.
4 Mehta P K. Concrete technology at the crossroads--problems and opportunities[J]. ACI Special Publication, 1994,144:1.
5 Baltazar L, Santana J, Lopes B, et al. Surface skin protection of concrete with silicate-based impregnations: Influence of the substrate roughness and moisture[J]. Construction Building Mater,2014,70(3):191.
6 Ibrahim M, Al-Gahtani A S, Maslehuddin M, et al. Effectiveness of concrete surface treatmentmaterials in reducing chloride-induced reinforcement corrosion[J]. Construction Building Mater,1997,11:443.
7 Baltazar, Rodrigues L, Correia M P, et al. Hydrophobic protection for concrete: Short-term performance and durability[J]. Restoration Buildings Monuments,2016,19(4):267.
8 Zhu Y G, Kou S C, Poon C S, et al. Influence of silane-based water repellent on the durability properties of recycled aggregate concrete[J]. Cem Concr Compos,2013,35(1):32.
9 Pigino B, Leemann A, Franzoni E, et al. Ethyl silicate for surface treatment of concrete—PartⅡ: Characteristics and performance[J]. Cem Concr Compos,2012,34(3):313.
10 Levi M, Ferro C, Regazzoli D, et al. Comparative evaluation method of polymer surface treatments applied on high performance concrete[J]. J Mater Sci,2002,37(22):4881.
11 Jones M R, Dhir R K, Gill J P. Concrete surface treatment: Effect of exposure temperature on chloride diffusion resistance[J]. Cem Concr Res,1995,25(1):197.
12 Buenfeld N R, Zhang J Z. Chloride diffusion through surface-treated mortar specimens—Corrosion and corrosion protection of steel in concrete[J]. Cem Concr Res,1998,28(28):665.
13 Almusallam A A, Khan F M, Dulaijan S U, et al. Effectiveness of surface coatings in improving concrete durability[J]. Cem Concr Compos,2003,25(25):473.
14 Batis G, Pantazopoulou P, Routoulas A. Corrosion protection investigation of reinforcement by inorganic coating in the presence of alkanolamine-based inhibitor[J]. Cem Concr Compos,2003,25(3):371.
15 Franzoni E, Varum H, Natali M E, et al. Improvement of historic reinforced concrete/mortars by impregnation and electrochemical methods[J]. Cem Concr Compos,2014,49(5):50.
16 Mcgettigan E. Silicon-based weatherproofing materials[J]. Concr Int,1992,14:52.
17 Thompson L R, Silsbee M R, Gill P M, et al. Characterization of silicate sealers on concrete[J]. Cem Concr Res,1997,27(10):1561.
18 Brenna A, Bolzoni F, Beretta S, et al. Long-term chloride-induced corrosion monitoring of reinforced concrete coated with commercial polymer-modified mortar and polymeric coatings[J]. Construction Building Mater,2013,48(48):734.
19 Cardenas H E, Struble L J. Electrokinetic nanoparticle treatment of hardened cement paste for reduction of permeability[J]. J Mater Civil Eng,2006,18(4):554.
20 Jiang L, Xue X, Zhang W, et al. The investigation of factors affec-ting the water impermeability of inorganic sodium silicate-based concrete sealers[J]. Construction Building Mater,2015,93:729.
21 Chourasia A. Protection of bio-deteriorated reinforced concrete using concrete sealers[J]. Int J Mater Chem Phys,2015,1(1):11.
22 Li G, Yang B, Guo C, et al. Time dependence and service life prediction of chloride resistance of concrete coatings[J]. Construction Building Mater,2015,83:19.
23 Setyowatia E, Amalia S F, Nazriati, et al. Hydrophobic silica coa-ting based on waterglass on copper by electrophoretic deposition[J]. Appl Mech Mater,2014,493:749.
24 Owusua Y A. Physical-chemistry study of sodium silicate as a foundry sand binder[J]. Adv Colloid Interface Sci,1982,18(1):57.
25 Xue X, Yang J, Zhang W, et al. The study of an energy efficient cool white roof coating based on styrene acrylate copolymer and cement for waterproofing purpose—Part Ⅱ: Mechanical and water impermeability properties[J]. Construction Building Mater,2015,96:666.
26 Song Z, Xue X, Li Y, et al. Experimental exploration of the waterproofing mechanism of inorganic sodium silicate-based concrete sea-lers[J]. Construction Building Mater,2016,104:276.
27 Chen Xiuqin, Yang Shaoming. Preparation of sodium silicate composite coating with high water tolerance[J]. J Huaqiao University: Nat Sci,2000,21(3):271(in Chinese).
陈秀琴, 杨少明. 耐水性水玻璃复合涂料的研制[J]. 华侨大学学报:自然科学版,2000,21(3):271.
28 Yang Jie. Study of solid phase preparation of high degree of polyme-rization of condensed aluminum phosphate and its application in so-dium silicate cement[D]. Nanning: Guangxi University,2012 (in Chinese).
杨杰. 固相法制备高聚合度缩合磷酸铝及其在水玻璃胶泥中的应用研究[D]. 南宁:广西大学, 2012.
29 Wang Yafeng. Sodium silicate inorganic coatings development and development trend[J]. Public Communication Sci Technol,2011(7):114(in Chinese).
王亚峰. 水玻璃无机涂料的研制及发展趋势[J]. 科技传播, 2011(7):114.
30 Zellmann H D, Kaps C. Chemically modified water-glass binders for acid-resistant mortars[J]. J Am Ceram Soc,2006,89(4):1369.
31 Pan X, Shi Z, Shi C, et al. Interactions between inorganic surface treatment agents and matrix of Portland cement-based materials[J]. Construction Building Mater,2016,113:721.
32 Keck R H. Improving concrete durability with cementitious materials[J]. Concr Int,2001,23(9):47.
33 Sprouts S, Huang L, Amey S L. Evaluating the performance of cementitious waterproofing systems for concrete[J]. Concr Int, 1994,16:1.
34 Bao Wang, Han Dongdong, et al. The analysis and research status on mechanism of cementitious capillary crystalline waterproofing coating[J]. New Building Mater, 2011,38(9):79(in Chinese).
鲍旺, 韩冬冬,等. 水泥基渗透结晶型防水涂料作用机理研究进展和分析[J]. 新型建筑材料, 2011,38(9):79.
35 Kagi D A, Ren K B. Reduction of water absorption in silicate treated concrete by post-treatment with cationic surfactants[J]. Building Environment,1995,30(2):237.
36 Jia L, Shi C, Pan X, et al. Effects of inorganic surface treatment on water permeability of cement-based materials[J]. Cem Concr Compos,2016,67(3):85.
37 Hou P, et al. Effects and mechanisms of surface treatment of har-dened cement-based materials with colloidal nanoSiO₂ and its precursor[J]. Construction Building Mater,2014,53(53):66.
38 Diamanti M V, Brenna A, Bolzoni F, et al. Effect of polymer modified cementitious coatings on water and chloride permeability in concrete[J]. Construction Building Mater,2013,49(6):720.
39 Woo R S C, Zhu H, Chow M M K, et al. Barrier performance of silane-clay nanocomposite coatings on concrete structure[J]. Compos Sci Technol,2008,68(14):2828.
40 Dai J G, Akira Y, Wittmann F H, et al. Water repellent surface impregnation for extension of service life of reinforced concrete structures in marine environments: The role of cracks[J]. Cem Concr Compos, 2010,32(2):101.
41 Ibrahim M, Al-Gahtani A S, Maslehuddin M, et al. Use of surface treatment materials to improve concrete durability[J]. J Mater Civil Eng,1999,11(1):36.
42 Franzoni E, Pigino B, Pistolesi C. Ethyl silicate for surface protection of concrete: Performance in comparison with other inorganic surface treatments[J]. Cem Concr Compos,2013,44(11):69.
43 Pan X, Shi C, Jia L, et al. Effect of inorganic surface treatment on air permeability of cement-based materials[J]. J Mater Civil Eng,2015,28(3):401.
44 Cˇalogovic＇ V. Gas permeability measurement of porous materials (concrete) by time-variable pressure difference method[J]. Cem Concr Res,1995,25(5):1054.
45 Yang K, Basheer P A M, Magee B, et al. Investigation of moisture condition and Autoclam sensitivity on air permeability measurements for both normal concrete and high performance concrete[J]. Construction Building Mater,2013,48(48):306.
46 Yang K, Basheer P A M, Bai Y, et al. Development of a new in situ test method to measure the air permeability of high performance concretes[J]. Ndt E Int,2014,64(2):30.
47 Preez A A D, Alexander M G. A site study of durability indexes for concrete in marine conditions[J]. Mater Structures, 2004,37(3):146.
48 Kucharczyková B, Misák P, Vymazal T. Determination and evaluation of the air permeability coefficient using torrent permeability tes-ter[J]. Russian J Nondestructive Testing,2010,46(3):226.
49 Aguiar J B, Júnior C. Carbonation of surface protected concrete[J]. Construction Building Mater, 2013,49(4):478.
50 Shi H S, Xu B W, Zhou X C. Influence of mineral admixtures on compressive strength, gas permeability and carbonation of high performance concrete[J]. Construction Building Mater,2009,23(5):1980.
51 Jiang Qian, Mu Song, Liu Jianzhong, et al. Research on factors affecting penetration depth of modified water glass coatings[J]. Paint Coat Ind,2015,45(8):67(in Chinese).
姜骞, 穆松, 刘建忠, 等. 水玻璃涂料渗透深度的影响因素研究[J]. 涂料工业,2015,45(8):67.
52 Han Y M, Dong G S, Choi D S. Evaluation of the durability of mortar and concrete applied with inorganic coating material and surface treatment system[J]. Construction Building Mater,2007,21(2):362.
53 Weng Zailong, Zhuo Shiwei, Yang Zhongjia. Effects of surface penetration sealer on concrete characteristics[J]. Corrosion Eng,2002,26(3):181(in Chinese).
翁在龙, 卓世伟, 扬仲家. 表面渗透涂封剂对混凝土特性影响之研究[J]. 防蚀工程,2002,26(3):181.
54 Zhang Rui. The effects of nano-SiO₂ and its precursor on the performance of cement-based materials and the study on the mechanism[D]. Jinan: Jinan University,2016(in Chinese).
张蕊. 纳米SiO₂及其前驱体对表层水泥基材料性能影响及作用机理研究[D]. 济南:济南大学,2016.
55 Huang Bo, Deng Dehua, Chen Huiyu. Effect of deep penetration sealer (DPS) on concrete resistance to sulfate attack[J]. J Central South University:Sci Technol,2011,42(12):3858(in Chinese).
黄波, 邓德华, 陈蕙玉. 深度渗透密封剂(DPS)对混凝土抗硫酸盐侵蚀性能的影响[J]. 中南大学学报:自然科学版,2011, 42(12):3858.

[1]	白鹏飞, 杨聪仁, 马昆林, 丁亚蓉, 詹启贤, 孟庆胤, 陈荣健, 范佳志. 助磨剂影响矿物浮选的作用机理及研究进展[J]. 材料导报, 2025, 39(3): 24010120-7.
[2]	龙武剑, 余阳, 何闯, 李雪琪, 熊琛, 冯甘霖. 纳米增强水泥基复合材料抗氯离子迁移及固化性能综述[J]. 材料导报, 2024, 38(7): 22090138-10.
[3]	王元战, 杨旻鑫, 龚晓龙, 王禹迟, 郭尚. 考虑地下水位影响的碱渣土地基半埋混凝土内氯离子传输试验研究[J]. 材料导报, 2024, 38(7): 22010226-7.
[4]	褚洪岩, 汤金辉, 王群, 高李, 赵志豪. 采用纳米氧化铝制备高弹性模量超高性能混凝土的可行性研究[J]. 材料导报, 2024, 38(5): 22110073-6.
[5]	靳红华, 任青阳, 肖宋强, 任小坤. 模拟酸雨侵蚀环境下悬臂抗滑桩耐久性极限寿命预测[J]. 材料导报, 2024, 38(5): 22070148-8.
[6]	郑直, 郭乃胜, 金鑫, 房辰泽, 尤占平, 谭忆秋. 水性丙烯酸交通标线涂料研究现状与发展趋势[J]. 材料导报, 2024, 38(21): 22120007-12.
[7]	赵增丰, 蒲紫盈, 林璨, 肖建庄, 姚磊, 姬宸源, 刘雅婕. 免烧陶粒及陶粒混凝土性能研究进展[J]. 材料导报, 2024, 38(20): 23100019-13.
[8]	于乐乐, 王爱国, 仲小凡, 刘开伟, 潘耀辉, 肖必华, 孙道胜. 煤矸石骨料混凝土力学和耐久性能研究进展[J]. 材料导报, 2024, 38(20): 23080244-9.
[9]	褚洪岩, 史文芳, 王群, 蒋金洋. 采用城市生活垃圾焚烧飞灰制备绿色水泥砂浆的可行性研究[J]. 材料导报, 2024, 38(19): 23070076-7.
[10]	杨尊, 李碧雄, 张治博, 李梁慧. 高钛矿渣在水泥混凝土中的研究应用进展[J]. 材料导报, 2024, 38(18): 22120226-9.
[11]	王家滨, 张凯峰, 郑康华, 符梦涛. 完全浸泡再生混凝土Mg²⁺-SO₄^2--Cl^-侵蚀耐久性损伤规律与机理[J]. 材料导报, 2024, 38(18): 23050184-11.
[12]	曾田, 陈啸洋, 王南, 张婷婷, 关岩, 毕万利, 常钧. 镁质胶凝材料综述:研究进展与低碳路径探讨[J]. 材料导报, 2024, 38(17): 24010170-15.
[13]	张立卿, 余家乐, 王云洋, 韩宝国, 陈梦成, 许开成. 渗透结晶水泥基复合材料研究综述[J]. 材料导报, 2024, 38(13): 22100014-16.
[14]	黄京立, 侯杰, 郑沛祺, 王嘉伟, 陶文宏, 段广彬, 张秀芝. 粉煤灰-矿渣基免烧人造轻集料的制备及性能研究[J]. 材料导报, 2024, 38(13): 23010034-9.
[15]	袁小亚, 蒲云东, 桂尊曜, 张惠一, 杨森, 金湛, 曹蔚琦. 羟基化石墨烯对粉煤灰-水泥基复合材料性能的影响[J]. 材料导报, 2024, 38(11): 23020017-8.

[1]	Huanchun WU, Fei XUE, Chengtao LI, Kewei FANG, Bin YANG, Xiping SONG. Fatigue Crack Initiation Behaviors of Nuclear Power Plant Main Pipe Stainless Steel in Water with High Temperature and High Pressure[J]. Materials Reports, 2018, 32(3): 373 -377 .
[2]	Miaomiao ZHANG,Xuyan LIU,Wei QIAN. Research Development of Polypyrrole Electrode Materials in Supercapacitors[J]. Materials Reports, 2018, 32(3): 378 -383 .
[3]	Congshuo ZHAO,Zhiguo XING,Haidou WANG,Guolu LI,Zhe LIU. Advances in Laser Cladding on the Surface of Iron Carbon Alloy Matrix[J]. Materials Reports, 2018, 32(3): 418 -426 .
[4]	Huaibin DONG,Changqing LI,Xiahui ZOU. Research Progress of Orientation and Alignment of Carbon Nanotubes in Polymer Implemented by Applying Electric Field[J]. Materials Reports, 2018, 32(3): 427 -433 .
[5]	Xiaoyu ZHANG,Min XU,Shengzhu CAO. Research Progress on Interfacial Modification of Diamond/Copper Composites with High Thermal Conductivity[J]. Materials Reports, 2018, 32(3): 443 -452 .
[6]	Anmin LI,Junzuo SHI,Mingkuan XIE. Research Progress on Mechanical Properties of High Entropy Alloys[J]. Materials Reports, 2018, 32(3): 461 -466 .
[7]	Qingqing DING,Qian YU,Jixue LI,Ze ZHANG. Research Progresses of Rhenium Effect in Nickel Based Superalloys[J]. Materials Reports, 2018, 32(1): 110 -115 .
[8]	Yaxiong GUO,Qibin LIU,Xiaojuan SHANG,Peng XU,Fang ZHOU. Structure and Phase Transition in CoCrFeNi-M High-entropy Alloys Systems[J]. Materials Reports, 2018, 32(1): 122 -127 .
[9]	Changsai LIU,Yujiang WANG,Zhongqi SHENG,Shicheng WEI,Yi LIANG,Yuebin LI,Bo WANG. State-of-arts and Perspectives of Crankshaft Repair and Remanufacture[J]. Materials Reports, 2018, 32(1): 141 -148 .
[10]	Xia WANG,Liping AN,Xiaotao ZHANG,Ximing WANG. Progress in Application of Porous Materials in VOCs Adsorption During Wood Drying[J]. Materials Reports, 2018, 32(1): 93 -101 .

Viewed

Full text

Abstract

Cited

Shared

Discussed