|Table of Contents|

Applicability of determination indexes for fatigue failure of modified asphalt(PDF)

《交通运输工程学报》[ISSN:1671-1637/CN:61-1369/U]

Issue:
2020年04期
Page:
91-106
Research Field:
道路与铁道工程
Publishing date:

Info

Title:
Applicability of determination indexes for fatigue failure of modified asphalt
Author(s):
WANG Lin1 GUO Nai-sheng1 WEN Yan-kai1 HOU Yi-lie2 YU Chun-hui1 YOU Zhan-ping3
1. Institute of Road and Bridge Engineering, Dalian Maritime University, Dalian 116026, Liaoning, China; 2. School of Traffic and Transportation, Dalian University of Science and Technology, Dalian 116041, Liaoning, China; 3. Department of Civil and Environmental Engineering, Michigan Technological University, Houghton 49931, Michigan, USA
Keywords:
asphalt pavement dynamic shear rheometer rock asphalt composite modified asphalt fatigue failure load control mode normalized dynamic modulus cumulative dissipative energy ratio
PACS:
U416.217
DOI:
10.19818/j.cnki.1671-1637.2020.04.007
Abstract:
The malvern dynamic shear rheometer was used to conduct the time sweep fatigue tests on the 90# original binder, SBS modified asphalt, rock asphalt modified asphalt, crumb rubber modified asphalt, rock asphalt/SBS composite modified asphalt and rock asphalt/crumb rubber composite modified asphalt(RA/CRCMA)under the stress-controlled and strain-controlled modes. The corresponding fatigue life of modified asphalt was determined according to five fatigue failure definitions. The suitability of fatigue failure determination indexes of modified asphalt was evaluated by using the statistical analysis method. The fatigue performances of modified asphalts were compared and analyzed by using the recommended indexes. Research result shows that the index determined based on the normalized dynamic modulus is not affected by the load control mode and asphalt type. The indexes determined based on the phase angle and cumulative dissipative energy ratio are significantly affected by the asphalt type and load-controlled mode, and are not universal. The index determined based on the dissipated energy change rate is only suitable for the fatigue life judgment of stress-controlled mode. The index determined based on the reduced dissipated energy change rate is less affected by the asphalt type. It exhibits a preferable fatigue life evaluation effect on all asphalts in this study. The correlation coefficients of the indexes determined by the normalized dynamic modulus and the reduced dissipated energy change rate under the stress-controlled and strain-controlled modes are up to 0.94, and the mean absolute error is less than 20%, showing a good correlation and equivalent fatigue life ranking results. Due to the simple calculation and distinct definition, they are recommended to be used as the determination standard for testing the asphalt fatigue failure in time sweep fatigue test. According to the sequence of fatigue life of asphalts tested by the recommended indexes in this study, the RA/CRCMA with 18% crumb rubber and 5% rock asphalt shows the optimal fatigue resistance under the stress-controlled and strain-controlled modes. 9 tabs, 19 figs, 31 refs.

References:

[1] 吴少鹏,江承建,林俊涛,等.老化沥青胶结料的疲劳特性研究[J].武汉理工大学学报(交通科学与工程版),2013,37(3):451-455.
WU Shao-peng, JIANG Cheng-jian, LIN Jun-tao, et al. Study on fatigue characteristics of aged asphalt binder[J]. Journal of Wuhan University of Technology(Transportation Science and Engineering), 2013, 37(3): 451-455.(in Chinese)
[2] WU Shao-peng, MO Lian-tong, CONG Pei-liang, et al. Flammability and rheological behavior of mixed flame retardant modified asphalt binders[J]. Fuel, 2008, 87(1): 120-124.
[3] KIM Y R, LITTLE D N, SONG I. Effect of mineral fillers on fatigue resistance and fundamental material characteristics: mechanism evaluation[J]. Transportation Research Record, 2003(1832): 1-8.
[4] CHEN Zi-xuan, WANG Tao, PEI Jian-zhong, et al. Low temperature and fatigue characteristics of treated crumb rubber modified asphalt after a long term aging procedure[J]. Journal of Cleaner Production, 2019, 234: 1262-1274.
[5] 田 霜.基于黏弹特性的沥青损伤演化规律分析[D].哈尔滨:哈尔滨工业大学,2017.
TIAN Shuang. Analysis of asphalt damage evolution based on viscoelastic characteristics[D]. Harbin: Harbin Institute of Technology, 2017.(in Chinese)
[6] LIAO M C, CHEN J S, TSOU K W. Fatigue characteristics of bitumen-filler mastics and asphalt mixtures[J]. Journal of Materials in Civil Engineering, 2012, 24(7): 916-923.
[7] BENEDETTO H D, ROCHE C D L, BAAJ H, et al. Fatigue of bituminous mixtures[J]. Materials and Structures, 2004, 37(6): 202-216.
[8] 郑健龙,马 健,吕松涛,等.老化沥青混合料粘弹性疲劳损伤模型研究[J].工程力学,2010,27(3):116-122.
ZHENG Jian-long, MA Jian, LYU Song-tao, et al. Research on viscoelastic fatigue damage model of aging asphalt mixtures[J]. Engineering Mechanics, 2010, 27(3): 116-122.(in Chinese)
[9] BAHIA H U, HANSON D I, ZENG M, et al. Characterization of modified asphalt binders in superpave mix design[R]. Washington DC: Transportation Research Board, 2001.
[10] RAITHBY K B, SRERLING A B. Some effect of loading history on the performance of rolled asphalt[R]. Crowthorne: Transport and Road Research Laboratory, 1972.
[11] WANG Yang, WANG Chao, BAHIA H. Comparison of the fatigue failure behavior for asphalt binder using both cyclic and monotonic loading modes[J]. Construction and Building Materials, 2017, 151: 767-774.
[12] 单丽岩,谭忆秋,许亚男,等.应力、应变控制模式下沥青疲劳损伤演化规律[J].中国公路学报,2016,29(1):16-21.
SHAN Li-yan, TAN Yi-qiu, XU Ya-nan, et al. Fatigue damage evolution rules of asphalt under controlled-stress mode and controlled-stain modes[J]. China Journal of Highway and Transport, 2016, 29(1): 16-21.(in Chinese)
[13] CARPENTER S H, SHEN S. Dissipated energy approach to study hot-mix asphalt healing in fatigue[J]. Transportation Research Record, 2006(1970): 178-185.
[14] 刘全涛.沥青胶浆的疲劳性能研究[D].武汉: 武汉理工大学,2008.
LIU Quan-tao.Evaluation of the fatigue properties of bituminous binders[D]. Wuhan: Wuhan University of Technology, 2008.(in Chinese)
[15] BHASIN A, BRANCOV T F C, MASAD E, et al. Quantitative comparison of energy methods to characterize fatigue in asphalt materials[J]. Journal of Materials in Civil Engineering, 2009, 21(2): 83-92.
[16] MASAD E, BRANCOV T F C, LITTLE D N, et al. A unified method for the analysis of controlled-strain and controlled-stress fatigue testing[J]. International Journal of Pavement Engineering, 2008, 9(4): 233-246.
[17] YU J M, TSAI B W, ZHANG X N, et al. Development of asphalt pavement fatigue cracking prediction model based on loading mode transfer function[J]. Road Materials and Pavement Design, 2012, 13(3): 501-517.
[18] KHIAVI A K, AMERRI M. Investigating the fatigue endurance limit of hma mixture using RDEC approach[J]. Construction and Building Materials, 2014, 55: 97-102.
[19] ZHOU F, MOGAWER W, LI H, et al. Evaluation of fatigue tests for characterizing asphalt binders[J]. Journal of Materials in Civil Engineering, 2013, 25(5): 610-617.
[20] 陈浩浩,吴少鹏,刘全涛,等.沥青的疲劳性能评价方法研究[J].武汉理工大学学报,2015,37(12):47-52.
CHEN Hao-hao, WU Shao-peng, LIU Quan-tao, et al. Study on evaluation methods for fatigue property of asphalt[J]. Journal of Wuhan University of Technology, 2015, 37(12): 47-52.(in Chinese)
[21] SHEN S, CARPENTER S H. Application of dissipated energy concept in fatigue endurance limit testing[J]. Transportation Research Record, 2005(1929): 165-173.
[22] 孙大权,林添坂,曹林辉.基于动态剪切流变试验的沥青疲劳寿命分析方法[J].建筑材料学报,2015,18(2):346-350.
SUN Da-quan, LIN Tian-ban, CAO Lin-hui. Evaluation method for fatigue life of asphalt based on dynamic shear rheometer test[J]. Journal of Building Materials, 2015, 18(2): 346-350.(in Chinese)
[23] MARTONO W, BAHIA H U, D'ANGELO J. Effect of testing geometry on measuring fatigue of asphalt binders and mastics[J]. Journal of Materials in Civil Engineering, 2007, 19(9): 746-752.
[24] 王 明,林发金,刘黎萍.基于简化能量耗散率的岩沥青改性沥青疲劳性能[J].建筑材料学报,2015,18(6):1024-1027,1032.
WANG Ming, LIN Fa-jin, LIU Li-ping. Fatigue performance of rock asphalt modified asphalts based on reduced dissipated energy ratio[J]. Journal of Building Materials, 2015, 18(6): 1024-1027, 1032.(in Chinese)
[25] 白琦峰,钱振东,赵延庆.基于流变学的沥青抗疲劳性能评价方法[J].北京工业大学学报,2012,38(10):1536-1542.
BAI Qi-feng, QIAN Zhen-dong, ZHAO Yan-qing. Asphalt fatigue resistance evaluation method based on the rheology[J]. Journal of Beijing University of Technology, 2012, 38(10): 1536-1542.(in Chinese)
[26] 孟勇军,张肖宁.基于累计耗散能量比的改性沥青疲劳性能[J].华南理工大学学报(自然科学版),2012,40(2):99-103.
MENG Yong-jun, ZHANG Xiao-ning. Fatigue performances of modified asphalts based on cumulative dissipated energy ratio[J]. Journal of South China University of Technology(Natural Science Edition), 2012, 40(2): 99-103.(in Chinese)
[27] SAFAEI F, LEE J S, DO NASCIMENTO L A H, et al. Implications of warm-mix asphalt on long-term oxidative aging and fatigue performance of asphalt binders and mixtures[J]. Road Materials and Pavement Design, 2014, 15(S1): 45-61.
[28] MICAELO R, PEREIRA A, QUARESMA L, et al. Fatigue resistance of asphalt binders:assessment of the analysis methods in strain-controlled tests[J]. Construction and Building Materials, 2015, 98: 703-712.
[29] WANG Chao, ZHANG Han, CASTORENA C, et al. Identifying fatigue failure in asphalt binder time sweep tests[J]. Construction and Building Materials, 2016, 121: 535-546.
[30] 单丽岩,谭忆秋,李晓琳.沥青疲劳特性的研究[J].武汉理工大学学报(交通科学与工程版),2011,35(1):190-194.
SHAN Li-yan, TAN Yi-qiu, LI Xiao-lin. Fatigue characteristic of asphalt[J]. Journal of Wuhan University of Technology(Transportation Science and Engineering), 2011, 35(1): 190-194.(in Chinese)
[31] 李 薇,郭乃胜,教浡宗,等.岩沥青复合改性沥青流变性能[J].大连海事大学学报,2018,44(3):79-87.
LI Wei, GUO Nai-sheng, JIAO Bo-zong, et al. Rheological properties of rock asphalt composite modified asphalt[J]. Journal of Dalian Maritime University, 2018, 44(3): 79-87.(in Chinese)

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Last Update: 2020-08-20