1,463
Views
7
CrossRef citations to date
0
Altmetric
Research Article

Parametric analysis and field validations of oxidative ageing in asphalt pavements using multiphysics modelling approaches

ORCID Icon, ORCID Icon, ORCID Icon &
Article: 2020267 | Received 20 Apr 2021, Accepted 13 Dec 2021, Published online: 09 Jan 2022

References

  • Alavi, M., Hajj, E. Y., and Sebaaly, P. E., 2017. A comprehensive model for predicting thermal cracking events in asphalt pavements. International Journal of Pavement Engineering, 18 (9), 871–885.
  • Alavi, M. Z., Pouranian, M. R., and Hajj, E. Y., 2014. Prediction of asphalt pavement temperature profile with finite control volume method. Transportation Research Record: Journal of the Transportation Research Board, 2456 (1), 96–106.
  • Alawi, M. H., and Helal, M. M., 2014. A mathematical model for the distribution of heat through pavement layers in Makkah roads. Journal of King Saud University-Engineering Sciences, 26 (1), 41–48.
  • Bobes-Jesus, V., et al., 2013. Asphalt solar collectors: a literature review. Applied Energy, 102, 962–970.
  • Caro, S., et al., 2010. Probabilistic modeling of the effect of air voids on the mechanical performance of asphalt mixtures subjected to moisture diffusion. Asphalt Paving Technology-Proceedings Association of Asphalt Technologists, 79, 221.
  • Castelblanco Torres, A., 2006. Probabilistic analysis of air void structure and its relationship to permeability and moisture damage of hot mix asphalt. Texas A&M University.
  • Chen, J., Wang, H., and Li, L., 2015. Determination of effective thermal conductivity of asphalt concrete with random aggregate microstructure. Journal of Materials in Civil Engineering, 27 (12), 04015045.
  • Chen, J., Wang, H., and Zhu, H., 2017. Analytical approach for evaluating temperature field of thermal modified asphalt pavement and urban heat island effect. Applied Thermal Engineering, 113, 739–748.
  • Gao, Y., et al., 2021. Influence of anti-ageing compounds on rheological properties of bitumen. 128559.
  • Glover, C. J., et al., 2009. Evaluation of binder aging and its influence in aging of hot mix asphalt concrete: literature review and experimental design. Texas Transportation Institute.
  • Glover, C. J., et al., 2014. Evaluation of binder aging and its influence in aging of hot mix asphalt concrete: technical report, Texas. Dept. of Transportation. Research and Technology Implementation Office.
  • Gu, F., et al., 2021. Effects of additional antistrip additives on durability and moisture susceptibility of granite-based open-graded friction course. Journal of Materials in Civil Engineering, 33 (9), 04021245.
  • Gui, J., et al., 2007. Impact of pavement thermophysical properties on surface temperatures. Journal of Materials in Civil Engineering, 19 (8), 683–690.
  • Hall, M. R., et al., 2012. Influence of the thermophysical properties of pavement materials on the evolution of temperature depth profiles in different climatic regions. Journal of Materials in Civil Engineering, 24 (1), 32–47.
  • Han, R., 2011. Improvement to a transport model of asphalt binder oxidation in pavements: Pavement temperature modeling, oxygen diffusivity in asphalt binders and mastics, and pavement air void characterization. Texas A&M University.
  • Han, R., Jin, X., and Glover, C. J., 2011. Modeling pavement temperature for use in binder oxidation models and pavement performance prediction. Journal of Materials in Civil Engineering, 23 (4), 351–359.
  • Hassn, A., et al., 2016. Effect of air voids content on thermal properties of asphalt mixtures. Construction and Building Materials, 115, 327–335.
  • Jiang, J., et al., 2020. Distribution of mortar film thickness and its relationship to mixture cracking resistance. International Journal of Pavement Engineering, 1–10, Ahead of print.
  • Jin, X., et al., 2011. Fast-rate–constant-rate oxidation kinetics model for asphalt binders. Industrial & Engineering Chemistry Research, 50 (23), 13373–13379.
  • Jin, X., Cui, Y., and Glover, C., 2013. Modeling asphalt oxidation in pavement with field validation. Petroleum Science and Technology, 31 (13), 1398–1405.
  • Li, R., et al., 2019. Soil thermal conductivity and its influencing factors at the Tanggula permafrost region on the Qinghai–Tibet Plateau. Agricultural and Forest Meteorology, 264, 235–246.
  • Li, H., Luo, X., and Zhang, Y., 2021. A kinetics-based model of fatigue crack growth rate in bituminous material. International Journal of Fatigue, 148, 106185.
  • Liu, M., et al., 1996. The kinetics of carbonyl formation in asphalt. AIChE Journal, 42 (4), 1069–1076.
  • Liu, F., Zhou, Z., and Zhang, X., 2021. Linking chemical to rheological properties of asphalt binder with oxidative aging effect. Road Materials and Pavement Design, 22 (9), 2014–2028.
  • Lu, Y., Wright, P., and Zhou, Y., 2009. Effect of temperature and temperature gradient on asphalt pavement response. Road & Transport Research: A Journal of Australian and New Zealand Research and Practice, 18 (1), 19.
  • Luca, J., and Mrawira, D., 2005. New measurement of thermal properties of superpave asphalt concrete. Journal of Materials in Civil Engineering, 17 (1), 72–79.
  • Lunsford, K. M., 1994. The effect of temperature and pressure on laboratory oxidized asphalt films with comparison to field aging. Texas A&M University. Libraries.
  • Luo, X., et al., 2018. Kinetics-based aging evaluation of in-service recycled asphalt pavement. Journal of Cleaner Production, 200, 934–944.
  • Luo, X., Gu, F., and Lytton, R. L., 2015. Prediction of field aging gradient in asphalt pavements. Transportation Research Record: Journal of the Transportation Research Board, 2507 (1), 19–28.
  • Luo, X., Gu, F., and Lytton, R. L., 2019. Kinetics-based aging prediction of asphalt mixtures using field deflection data. International Journal of Pavement Engineering, 20 (3), 287–297.
  • Mallick, R. B., Chen, B.-L., and Bhowmick, S., 2009. Harvesting energy from asphalt pavements and reducing the heat island effect. International Journal of Sustainable Engineering, 2 (3), 214–228.
  • Omairey, E. L., et al., 2019. Impact of anti-ageing compounds on oxidation ageing kinetics of bitumen by infrared spectroscopy analysis. Construction and Building Materials, 223, 755–764.
  • Omairey, E. L., et al., 2020. Rheological and fatigue characterisation of bitumen modified by anti-ageing compounds. Construction and Building Materials, 265, 120307.
  • Omairey, E, 2021. Multiphysics modelling and mitigation of ageing in asphalt pavements. Aston University.
  • Omairey, E. L., Gu, F., and Zhang, Y., 2021. An equation-based multiphysics modelling framework for oxidative ageing of asphalt pavements. Journal of Cleaner Production, 280, 124401.
  • Omairey, E., and Zhang, Y., 2021. Effect of climate region on field oxidative ageing of asphalt pavements using Multiphysics modelling approach. In: International symposium on frontiers of road and airport Engineering, Delft, Netherlands.
  • Pan, P., et al., 2017. Effect of freezing-thawing and ageing on thermal characteristics and mechanical properties of conductive asphalt concrete. Construction and Building Materials, 140, 239–247.
  • Prapaitrakul, N., et al., 2009. A transport model of asphalt binder oxidation in pavements. Road Materials and Pavement Design, 10 (sup1), 95–113.
  • Qin, Y, 2016. Pavement surface maximum temperature increases linearly with solar absorption and reciprocal thermal inertial. International Journal of Heat and Mass Transfer, 97, 391–399.
  • Rochlani, M., et al., 2020. Influence of source and ageing on the Rheological properties and fatigue and rutting resistance of bitumen using a DSR. In: Proceedings of the 9th international conference on maintenance and rehabilitation of pavements—Mairepav9, Springer.
  • Rose, A. A., 2016. Pavement air void property determination and incorporation of pavement air void properties in pavement oxidation modeling with an emphasis on X-Ray CT image analysis.
  • Soenen, H., et al., 2020a. Rheological parameters of durability of binders extracted from road pavements. Research and Innovation, 974, 1–10.
  • Soenen, H., et al., 2020b. Evaluation of the properties of bituminous binders recovered from various sites in Europe ISBM 2020.
  • Soenen, H., et al., 2021. Durability paramterts evaluated on binders recovered from various field sites in Europe. In: 7th e&E congress, Madrid, Spain, Eurasphalt and Eurobitume.
  • Solaimanian, M., and Bolzan, P., 1993. Analysis of the integrated model of climatic effects on pavements, Strategic Highway Research Program. National Research Council.
  • Solaimanian, M., and Kennedy, T. W., 1993. Predicting maximum pavement surface temperature using maximum air temperature and hourly solar radiation. Transportation Research Record, 1417, 1–11.
  • Wang, H., et al., 2010. Numerical simulation on the thermal response of heat-conducting asphalt pavements. Physica Scripta, T139, 014041.
  • Wang, P. Y., et al., 2014. Evolution and locational variation of asphalt binder aging in long-life hot-mix asphalt pavements. Construction and Building Materials, 68, 172–182.
  • Wang, Y., Sun, L., and Qin, Y., 2015. Aging mechanism of SBS modified asphalt based on chemical reaction kinetics. Construction and Building Materials, 91, 47–56.
  • Wen, Y., and Wang, Y., 2018. Determination of oxygen diffusion coefficients of compacted asphalt mixtures. Construction and Building Materials, 160, 385–398.
  • Yavuzturk, C., Ksaibati, K., and Chiasson, A., 2005. Assessment of temperature fluctuations in asphalt pavements due to thermal environmental conditions using a two-dimensional, transient finite-difference approach. Journal of Materials in Civil Engineering, 17 (4), 465–475.
  • Yin, F., et al., 2017. Characterization of non-uniform field aging in asphalt pavements. Construction and Building Materials, 153, 607–615.
  • Zhang, Y., et al., 2014. Crack initiation in asphalt mixtures under external compressive loads. Construction and Building Materials, 72, 94–103.
  • Zhang, Y., et al., 2017. Viscoelasticplastic–fracture modeling of asphalt mixtures under monotonic and repeated loads. Transportation Research Record: Journal of the Transportation Research Board, 2631 (1), 20–29.
  • Zhang, Y., et al., 2018a. Modeling stress-dependent anisotropic elastoplastic unbound granular base in flexible pavements. Transportation Research Record: Journal of the Transportation Research Board, 2672 (52), 46–56.
  • Zhang, Y., et al., 2018b. Impacts of air-void structures on the rutting tests of asphalt concrete based on discretized emulation. Construction and Building Materials, 166, 334–344.
  • Zhang, Y., et al., 2019. Prediction of dynamic shear modulus of fine aggregate matrix using discrete element method and modified hirsch model. Mechanics of Materials, 138, 103148.
  • Zhang, Y., Birgisson, B., and Lytton, R. L., 2016. Weak form equation–based finite-element modeling of viscoelastic asphalt mixtures. Journal of Materials in Civil Engineering, 28 (2), 04015115.
  • Zhao, Y., Tong, L., and Zhu, Y., 2019. Investigation on the properties and distribution of air voids in porous asphalt with relevance to the Pb (II) removal performance. Advances in Materials Science and Engineering, 2019 (13), 1–13.