Self-monitoring Application of Asphalt Concrete Containing Graphite and Carbon Fibers 被引量：5

Self-monitoring Application of Asphalt Concrete Containing Graphite and Carbon Fibers

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摘要 The self-monitoring application of asphalt concrete containing graphite and carbon fibers using indirect tensile test and wheel rolling test were introduced. The experiment results indicate that this kind of pitch-based composite is effective for strain/stress self-monitoring. In the indirect tensile test, for a completely conductive asphalt concrete specimen, the piezoresistivity was very weak and slightly positive, which meant the resistivity increase with the increment of tensile strain at all stress/strain amplitudes, with the gage factor as high as 6. The strain self-sensing ability was superior in the case of higher graphite content. However, when the conductive concrete was embedded into common asphalt concrete specimen as a partial structure function, the piezoresistivity was positive at all stress/strain amplitudes and with the gage factor of 13, which was much higher than that of completely conductive specimen. Thus, the strain self-sensing ability was superior when conductive asphalt concrete was taken in as a partial structure function. In the wheel-rolling test, the piezoresistivity was highly positive. At any stress amplitude, the piezoresistivity was strong, with the gage factor as high as 100, which was higher for a stress amplitude of 0.7 MPa than that of 0.5 MPa. The self-monitoring application of asphalt concrete containing graphite and carbon fibers using indirect tensile test and wheel rolling test were introduced. The experiment results indicate that this kind of pitch-based composite is effective for strain/stress self-monitoring. In the indirect tensile test, for a completely conductive asphalt concrete specimen, the piezoresistivity was very weak and slightly positive, which meant the resistivity increase with the increment of tensile strain at all stress/strain amplitudes, with the gage factor as high as 6. The strain self-sensing ability was superior in the case of higher graphite content. However, when the conductive concrete was embedded into common asphalt concrete specimen as a partial structure function, the piezoresistivity was positive at all stress/strain amplitudes and with the gage factor of 13, which was much higher than that of completely conductive specimen. Thus, the strain self-sensing ability was superior when conductive asphalt concrete was taken in as a partial structure function. In the wheel-rolling test, the piezoresistivity was highly positive. At any stress amplitude, the piezoresistivity was strong, with the gage factor as high as 100, which was higher for a stress amplitude of 0.7 MPa than that of 0.5 MPa.

作者 LIU Xiaoming WU Shaopeng LI Ning GAO Bo

机构地区 School of Civil Engineering and Architecture Key Laboratory of Silicate Materials Science and Engineering of Ministry of Education

出处《Journal of Wuhan University of Technology(Materials Science)》 SCIE EI CAS 2008年第2期268-271,共4页 武汉理工大学学报（材料科学英文版）

基金 the Outstanding Youth Foundation of Hubei Province(No.2004ABB019) Program for New Century Excellent Talents in University,China(No.NCET-05-0665)

关键词 asphalt concrete GRAPHITE carbon fibers SELF-MONITORING PIEZORESISTIVITY asphalt concrete graphite carbon fibers self-monitoring piezoresistivity

分类号 TU528 [建筑科学—建筑技术科学]

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参考文献13

1吴少鹏,刘小明,叶群山,李宁.Self-monitoring electrically conductive asphalt-based composite containing carbon fillers[J].中国有色金属学会会刊：英文版,2006,16(B02):512-516. 被引量：5
2S. Wen,D. D. L. Chung.Pitch-matrix composites for electrical, electromagnetic and strain-sensing applications[J].Journal of Materials Science.2005(15)
3Wu Shao-peng,Mo Lian-tong,Shui Zhong-he,Xuan Dong-xing,Xue Yong-jie,Yang Wen-feng.An improvement in electrical properties of asphalt concrete[J].Journal of Wuhan University of Technology - Mater Sci Ed.2002(4)
4S Wang,D D L Chung.Self-monitoring of Strain and Damage by a Carbon-carbon Composite[].Carbon.1997
5S H Wen,D D L Chung.Effects of Carbon Black on the Thermal,Mechanical and Electrical Properties of Pitch-matrix Composites[].Carbon.2004
6S P Wu,L T Mo,Z H Shui,et al.Improvement of Electrical Properties of Asphalt Concrete[].J Wuhan Univ Tech(Mate Sci Ed).2002
7S H Wen,D D L Chung.Pitch-matrix Composites for Electrical, Electromagnetic and Strain-sensing Applications[].Journal of Materials Science.2005
8S P Wu,L T Mo,X M Liu,et al.The Conductive Mechanism of Graphite Modified Pitch-based Concrete[].Progress in Materials Science.2005
9S P Wu,L T Mo,Z H Shui.Piezoresistivity of Graphite Modified Asphalt-based Composites[].Key Engineering Materials.2003
10S Werkmeister,F Wellner,M Oeser.Study on the Fatigue Behaviour of Pitch Mixes Using the Dynamic Indirect Tensile Test within the Scope of Analytical Design[].Proc th Int Confon Asphalt Pavements.2006

二级参考文献1

1磨炼同.Percolation Model of Graphite-modified Asphalt Concrete[J].Journal of Wuhan University of Technology(Materials Science),2005,20(1):111-113. 被引量：2

共引文献4

1刘小明,吴少鹏,李宁.石墨对沥青混合料的性能影响研究[J].武汉理工大学学报（交通科学与工程版）,2010,34(3):545-549. 被引量：8
2王海成,金娇,刘帅,高玉超,李锐,冯明珠,熊剑平,LIU Pengfei.环境友好型绿色道路研究进展与展望[J].中南大学学报（自然科学版）,2021,52(7):2137-2169. 被引量：50
3胡春华,赵青,李鹏飞,朱玉林,冯晨雨.铜渣和碳纤维沥青混合料导电性能研究[J].化工新型材料,2023,51(10):272-276.
4王壮,冯振刚,姚冬冬,崔奇,沈若廷,李新军.导电沥青混凝土研究进展[J].吉林大学学报（工学版）,2024,54(1):1-21.

同被引文献54

1磨炼同.Percolation Model of Graphite-modified Asphalt Concrete[J].Journal of Wuhan University of Technology(Materials Science),2005,20(1):111-113. 被引量：2
2吴少鹏,磨炼同,水中和.石墨改性沥青混凝土的导电机制[J].自然科学进展,2005,15(4):446-452. 被引量：16
3吴少鹏,刘小明,磨炼同,从培良,杨朋.自诊断沥青混凝土及其应用前景[J].华中科技大学学报（城市科学版）,2005,22(3):1-4. 被引量：11
4汤浩,陈欣方,罗云霞.复合型导电高分子材料导电机理研究及电阻率计算[J].高分子材料科学与工程,1996,12(2):1-7. 被引量：54
5吴少鹏,刘小明,叶群山,李宁.Self-monitoring electrically conductive asphalt-based composite containing carbon fillers[J].中国有色金属学会会刊：英文版,2006,16(B02):512-516. 被引量：5
6LIU Xiao-ming, WU Shao-peng, LI Ning. Properties evaluation of asphalt-based composites with graphite and mine powder[J]. Construction & Building Materials, 2008, 22(3): 121-126.
7WU Shao-peng, MO Liarl-tong, SHUI Zhong-he, et al. Investigation of the conductivity of asphalt concrete containing conductive fillers[J]. Carbon, 2005, 43(7): 1358-1363.
8Chung D D L. Self-monitoring structural materials[J]. Materials Science and Engineering, 1998, 22: 57-78.
9Wen S H, Chung D D L. Pitch-matrix composites for electrical,electromagnetic and strain-sensing applications[J]. Journal of Materials Science, 2005, 40: 3897-3903.
10LIU Xiao-ming, WU Shao-peng, LINing, et al. Study on asphalt concrete containing graphite and carbon fiber for self-monitoring of strain using indirect tensile test[C]//Li A, Sih G C, Nied H F. Proceedings of International Conference on Health Monitoring of Structure, Materials and Environment. 2007:1193-1198.

引证文献5

1刘小明,吴少鹏,杨小礼.导电沥青混凝土的机敏特性[J].中南大学学报（自然科学版）,2009,40(5):1465-1470. 被引量：2
2刘小明,吴少鹏,李宁.石墨对沥青混合料的性能影响研究[J].武汉理工大学学报（交通科学与工程版）,2010,34(3):545-549. 被引量：8
3孙长军,黄少旭,唐宁.结构自诊断沥青混凝土的施工工艺研究[J].建材世界,2013,34(1):53-56.
4杨群,李旭,王屏.Resistivity measurement of conductive asphalt concrete based on two-electrode method[J].Journal of Central South University,2013,20(9):2599-2604. 被引量：3
5王壮,冯振刚,姚冬冬,崔奇,沈若廷,李新军.导电沥青混凝土研究进展[J].吉林大学学报（工学版）,2024,54(1):1-21.

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1姚占勇,韩杰,商庆森,葛智,张晓萌,崔衡.碳纤维石墨导电沥青砂浆压敏性能研究[J].山东大学学报（工学版）,2013,43(1):80-85. 被引量：10
2孙长军,吴少鹏,唐宁,Kim Jenkins,潘攀,李文涛.结构自诊断沥青混凝土路用性能评价研究[J].交通科技,2013,23(2):130-132.
3杨怡,宋固全,陈煜国.石墨导电复合材料有效电导率模型研究[J].化工新型材料,2015,43(5):206-208. 被引量：3
4蒋建国,张学磊,刘小明,邓云东,董立明.导电沥青混凝土路用性能影响因素的灰关联分析[J].铁道科学与工程学报,2015,12(4):784-789. 被引量：5
5黄刚,何兆益,周超,黄涛.膨胀石墨抑制沥青烟机理与抑烟沥青混合料动态性能[J].中国公路学报,2015,28(10):1-10. 被引量：22
6王军,庄大新,朱湘.石墨等体积替代矿粉对沥青混合料性能影响研究[J].重庆科技学院学报（自然科学版）,2015,17(5):111-114.
7孙文州,LI Xu,杨群,ZHANG Hongwei.Resistivity-temperature Characteristics of Conductive Asphalt Concrete[J].Journal of Wuhan University of Technology(Materials Science),2016,31(2):367-371. 被引量：1
8赵若红,范道波,徐安,罗宝.离子导电砂浆电学性能影响因素研究[J].建筑材料学报,2017,20(4):511-516. 被引量：2
9雷杰,李淑明,兰天.自监测导电沥青混合料的研究与应用简介[J].石油沥青,2019,33(6):1-6.
10李永琴.导电沥青混凝土的桥面铺装开裂预警技术研究[J].公路,2021,66(2):40-44. 被引量：6

1韩宝国,欧进萍.Influence of Water Content on Conductivity and Piezoresistivity of Cement-based Material with both Carbon Fiber and Carbon Black[J].Journal of Wuhan University of Technology(Materials Science),2010,25(1):147-151. 被引量：3
2张梅,刘保县,万街华,张坤,刘锋涛.新型材料CFRP在锚杆中的应用[J].四川建材,2011,37(3):78-79. 被引量：2
3GARCIA A,SCHLANGEN E,VAN DE VEN M F C.How to Make Capsules Containing Rejuvenators for Their Use in Asphalt Concrete[J].武汉理工大学学报,2010,32(17):18-21. 被引量：7
4Xing-yi ZHU,Zhi-yi HUANG,Zhong-xuan YANG,Wei-qiu CHEN.Micromechanics-based analysis for predicting asphalt concrete modulus[J].Journal of Zhejiang University-Science A(Applied Physics & Engineering),2010,11(6):415-424.
5玩火[J].科技新时代,2010(1):101-101.
6范晓明.Piezoresistivity of Carbon Fiber Graphite Cement-based Composites with CCCW[J].Journal of Wuhan University of Technology(Materials Science),2011,26(2):340-344. 被引量：2
7LI W T WU S P ZHU Z H LIU Z F.Investigation on Fatigue Model of Asphalt Concrete Containing Conductive Fillers[J].武汉理工大学学报,2010,32(17):62-66.
8BingCHEN,KeruWU,WuYAO.Piezoresistivity in Carbon Fiber Reinforced Cement Based Composites[J].Journal of Materials Science & Technology,2004,20(6):746-750. 被引量：5
9JIANG H,WU S P,QIU J,WEI W.Self Healing Asphalt Concrete-state of the Art[J].武汉理工大学学报,2010,32(17):67-70.
10张军.试述沥青路面施工技术问题[J].中国水运（下半月）,2012,12(9):211-212.

Journal of Wuhan University of Technology(Materials Science)

2008年第2期

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