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The statistical impact of experimental result scatter of asphalt mixtures on their numerical modelling

Abstract

The paper presents selected test results of asphalt mixture conducted in low temperatures. The obtained parameters are highly diverse. It concerns ultimate breaking loads, stiffness parameters related to Young's modulus but also the fracture course. Statistical analysis upon the results makes it possible to relevantly estimate the material-defining parameter values. Such a random approach leads to the mean values of breaking and fracture-triggering loads, dealing with their dispersion too. The estimated parameters allow to form appropriate numerical models of asphalt mixture specimens. This type of analysis supports the laboratory tests. The paper presents the authors' simplified model considering non-uniform material features. The results reflect the scatter of real laboratory test outcomes. In order to do so an algorithm to calibrate the numerical model parameters was created.

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Category:
Articles
Type:
artykuły w czasopismach
Published in:
MATEC Web of Conferences no. 262, pages 1 - 6,
ISSN: 2261-236X
Language:
English
Publication year:
2019
Bibliographic description:
Szydłowski C., Górski J., Stienss M., Smakosz Ł.: The statistical impact of experimental result scatter of asphalt mixtures on their numerical modelling// MATEC Web of Conferences -Vol. 262, (2019), s.1-6
DOI:
Digital Object Identifier (open in new tab) 10.1051/matecconf/201926205014
Bibliography: test
  1. T. L. Anderson, Fracture mechanics fundamentals and applications (Taylor & Francis, 2005). open in new tab
  2. Y. R. Kim, Modelling of asphalt concrete (ASCE Press Mc GrawHil, 2009).
  3. L. Wang, Mechanics of asphalt Microstructure and micromechanics (ASCE Press Mc GrawHil, 2011).
  4. J. Wimmer, B. Stier, J.W. Simon and S. Reese, FINITE ELEM ANAL DES 110, pp. 43-57 (2016). open in new tab
  5. H. Wang, J. Wang, J. Chen, ENG FRACT MECH 132, pp. 104-119 (2014). open in new tab
  6. T. You, R. K. A. Al-Rub, M. K. Darabi, E. A. Masad and D. N. Little, CONSTR BUILD MATER 28, pp. 531-548 (2012). open in new tab
  7. K. H. Moon, A. C. Falchetto and J. W. Hu, CONSTR BUILD MATER 53, pp. 568-583 (2014). open in new tab
  8. E. Mahmoud, S. Saadeh, H. Hakimelahi and J. Harvey, ROAD MATER PAVEMENT 15(1), pp. 153-166 (2013). open in new tab
  9. A. Yin, X. Yang, S. Yang and W. Jiang, ENG FRACT MECH 78, pp. 2414-2428 (2011). open in new tab
  10. T. Schüler, R. Jänicke and H. Steeb, CONSTR BUILD MATER 109, pp. 96-108 (2016). open in new tab
  11. X. Li and M. O. Marasteanu, INT J FRACTURE 136, pp. 285-308 (2005). open in new tab
  12. P. Mackiewicz, J, MATER CIVIL ENG 25(1), pp. 140-147 (2013). open in new tab
  13. M. Galouei, A. Fakhimi, COMPUT GEOTECH 65, pp. 126-135 (2015). open in new tab
  14. T. Kanit, S. Forest, I. Galliet, V. Mounoury, D. Jeulin, INT J SOLIDS STRUCT 40, pp. 3647-3679 (2003). open in new tab
  15. M. Ostoja-Starzewski, PROBABILIST ENG MECH 21, pp. 112-132 (2006). open in new tab
  16. T. Pellinen, E. Huuskonen-Snicker, P. Eskelinen, P. O. Martinez, Journal of traffic and transportation engineering 2(1), pp. 30-39 (2015). open in new tab
  17. R. Velasquez, A. Zofka, M. Mugerel, M. O. Marasteanu, INT J PAVEMENT ENG 12:5, pp. 461-474 (2009). open in new tab
  18. A. Zofka, M. Marasteanu, M. Turos, ROAD MATER PAVEMENT 9:1, pp. 269-285 (2008). open in new tab
  19. C. Szydłowski, J. Judycki, Highway Engineering 10, pp. 348-353 (2015) (in Polish).
  20. S.-J. Lee, G. Zi, S. Mun, J. S. Kong, J.-H. Choi, ENG FRACT MECH 141, pp. 212-229 (2015). open in new tab
  21. A. Yin, X. Yang, H. Gao, H. Zhu, ENG FRACT MECH 92, pp. 40-55 (2012). open in new tab
  22. X. F. Wang, Z. J. Yang, J. R. Yates, A. P. Jivkov, C. Zhang, CONSTR BUILD MATER 75 pp. 35-45 (2015). open in new tab
  23. X. Wang, Z. Yang, A. P. Jivkov, CONSTR BUILD MATER 80, pp. 262-272 (2015). open in new tab
  24. WT:2-2010. Technical Guidelines, Asphalt Pavements on State Roads, Asphalt Mixes. General Directorate for National Roads and Motorways, 2010. Warsaw, Poland. (in Polish). open in new tab
  25. ABAQUS. ABAQUS analysis user's manual, Habbit, Karlsson & Sorenson Inc. 2010. open in new tab
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