基于当地材料制备高延性水泥基复合材料的研究(英文) 被引量：11

Development of engineered cementitious composites with local ingredients

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摘要为了降低高性能聚乙烯醇(polyvinyl alcohol,PVA)纤维增强水泥基复合材料ECC(engineered cemen-titious composites)的成本,用国产PVA纤维和其他本地原材料如粉煤灰、水泥和细砂等研制了高延性ECC材料.采用四点弯曲试验和光学显微镜研究了ECC的弯曲变形能力、裂缝宽度及裂缝自愈合现象,并对其进行了经济性分析.实验结果表明:利用国产原料制备的ECC均表现出大变形能力,平均裂缝宽度能控制在60μm左右;开裂的试件经过干湿循环养护之后,裂缝中出现了自愈合现象;经济性分析表明利用国产PVA纤维可以极大地降低ECC成本.利用国产PVA纤维等材料制备高性价比的ECC是可行的. In order to reduce the cost of high performance polyvinyl alcohol（PVA） fiber reinforced cementitious material（called engineered cementitious composites,ECC）,a ductile ECC material is developed using domestic PVA fibers along with other local ingredients,such as fly ash,cement and sand.In addition to the economic analysis of ECC,the four-point bending test and the optical microscope are employed to investigate the deflection capacity of ECC,its crack width and the occurrence of the self-healing phenomenon.The experimental results suggest that ECC made with domestic ingredients exhibits larger deformability and the average crack width is controlled around 60 μm.Furthermore,the self-healing behavior is observed in cracks of the specimens after cycles of wet and dry curing.The economic analysis shows that the cost of ECC can be greatly reduced via employing domestic PVA fibers.It is,therefore,feasible to produce low cost ECC material employing domestic PVA fibers,while simultaneously retaining high material ductility.

作者钱吮智张志刚

机构地区东南大学交通学院

出处《Journal of Southeast University(English Edition)》 EI CAS 2012年第3期327-330,共4页 东南大学学报（英文版）

基金 The National Natural Science Foundation of China (No.51008071,51278097) the Natural Science Foundation of Jiangsu Province(No.BK2010413) Teaching & Research Excellence Grant for Young Faculty Member at Southeast University the Program for Special Talents in Six Major Fields of Jiangsu Province(No.2011-JZ-011) the Scientific Research Innovation Project for College Graduates in Jiangsu Province(No.CXLX_0136)

关键词高延性水泥基复合材料高延性材料成本可行性分析 engineered cementitious composites（ECC） high tensile ductility material cost feasibility study

分类号 U444 [建筑科学—桥梁与隧道工程]

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参考文献11

1Li V C. Engineered cementitious composites-tailored composites through micromechanical modeling [ C ]//Fiber Reinforced Concrete: Present and the Future. Montreal, Canada: Canadian Society for Civil Engineer- ing, 1998: 64-97.
2Li V C, Wu C, Wang S, et al. Interface tailoring for strain-hardening polyvinyl alcohol-engineered cementi- tious composite (PVA-ECC)[ J ]. ACI Materials Jour- nal, 2002, 99 (5) : 463 - 472.
3Li V C. Strategies for high performance fiber reinforced cementitious composites development [ C ]//Proceedings of the North American/European Workshop on Advances in Fiber Reinforced Concrete. Bergamo, Italy, 2004 : 93 -98.
4Qian s z, Li V C. Simplified inverse method for deter- mining the tensile strain capacity of strain hardening ce- mentitious composites [ J ]. Journal of Advanced Con- crete Technology, 2007, 5(2): 235-246.
5Li M, Li V C. High-early-strength ECC for rapid durable repair-material properties [J]. ACI Materials, 2011, 108(1): 3-12.
6Sahmaran M, Li V C. Engineered cementitious compos- ites: Can composites be accepted as a crack-free con- crete? [ J]. Transportation Research Record: Journal of the Transportation Research Board, 2010, 2164:1 -8.
7Jacobsen S, Marchand J, Gerard B. Concrete cracks I: durability and self-healing-a review [ C ]//Proceedings of the 2nd International Conference on Concrete under Severe Conditions, Environment and Loading. Tromso, Norway, 1998 : 217 -231.
8Kenneth R L, Floyd O S. Autogenous healing of cement paste [J]. ACIJournal, 1956, 52(6): 52-63.
9I Edvardsen C. Water permeability and autogenous healing of cracks in concrete [ J]. ACI Materials Journal, 1999, 96(6) : 448 -455.
10Li V C, Yang E H. Self-healing materials: an alternative approach to 20 centuries of materials science [ M]. Dor- drecht, The Netherlands : Springer, 2007.

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3张远淼,余江滔,陆洲导,张锐.ECC修复震损剪力墙抗震性能试验研究[J].工程力学,2015,32(1):72-80. 被引量：28
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5LI Victor C.高延性纤维增强水泥基复合材料的研究进展及应用[J].硅酸盐学报,2007,35(4):531-536. 被引量：189
6Li VC, Wang S, Wu C. Tensile strain-hardening behavior of polyvinyl alcohol engineered cementitious composite (PVA- UHTCC) [J].ACI Materials Journal, 2001, 98(6):483-492.
7Ahmaran M, Li VC. Engineered Cementitious Composites, Transportation Research Record[J].Journal of the Transportation Research Board, 2010,2164(1):1-8.
8Lepeeh MD, Li VC. Water permeability of engineered ce- mentitious composites [J]. Cement and Concrete Composites, 2009, 31(10): 744-753.
9Lepech M D, Li V C, Robertson R E, et al. Design of Green Engineered Cementitious Composites for Improved Sustainability[J]. ACI Materials Journal,2008, 105(6):567-575.
10Birehall JD, Howard AJ, Kendall K. Flexural strength and porosity of cements [J].Nature,1981,289:388-90.

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5邹有武.含有残余奥氏体的高强度高延性钢板[J].汽车工艺,1991(4):40-43.
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Journal of Southeast University(English Edition)

2012年第3期

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基于当地材料制备高延性水泥基复合材料的研究(英文) 被引量：11

参考文献11

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