Use of Reclaimed Asphalt in Porous Asphalt Mixtures: Laboratory and Field Evaluations
Publication: Journal of Materials in Civil Engineering
Volume 27, Issue 7
Abstract
Maintenance and reconstruction of road pavements involve the production of huge amount of discarded material, such as reclaimed asphalt (RA), every year. As a consequence, issues related to RA stockpiles and disposals are dramatically increasing. At the same time, the growing importance of environmental and economic matters has led researchers and engineers to promote reusing milled materials rather than using valuable and nonrenewable natural resources (bitumen and aggregates). Road pavement maintenance and construction usually involve the use of porous asphalt (PA) mixtures, in particular in the case of motorways and highways. In fact, PA mixtures are widely employed as pavement surface layer thanks to their ability in reducing traffic noise and enhancing safety in wet conditions. In this sense, the reuse of RA into PA should be strongly encouraged. Unfortunately, technical specifications adopted in many countries do not allow any recycled materials in porous asphalt surface layers yet. Thus, reliable techniques allowing the use of RA in new PA mixtures are needed. In this research study, the use of coarse RA from old PA as aggregate in new PA mixtures was evaluated. Because a previous laboratory study demonstrated that the use of 15% of RA aggregates in PA mixtures seems possible (or even recommendable) as long as an accurate mix design with adequate binder contents is performed, new laboratory and field evaluations on recycled PA mixtures with15% of RA aggregates were carried out. On one hand, cyclic coaxial shear tests (CASTs) were performed under both dry and water-submerged conditions in order to evaluate the simultaneous effect of traffic and water exposure. On the other hand, a comprehensive laboratory experimental program for assessing acceptability, durability, fracture resistance, and water sensitivity was carried out on materials taken from the field during the construction of a full-scale trial section. Moreover, drainage properties of surface layers were measured along such a trial section. Overall test results demonstrated that including 15% of selected coarse recycled aggregates into porous asphalt mixtures does not compromise performances and durability of both asphalt-plant and laboratory produced mixtures. It was demonstrated that recycled mixture with 5.25% of total binder content and prepared by accurate mix design can perform as well as (or even better than) standard PA mixture in terms of workability, acceptability, abrasion resistance, repeated loading resistance, fracture propagation resistance, moisture sensitivity, and water drainability.
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Acknowledgments
This research was partially sponsored by Pavimental SpA. This support is greatly acknowledged. Data analysis and opinions are those of the authors and do not necessarily reflect those of the sponsoring agency.
References
Alvarez, A. E., Martin, A. E., and Estakhri, C. (2011). “A review of mix design and evaluation research for permeable friction course mixtures.” Constr. Build. Mater., 25(3), 1159–1166.
Autostrade, SpA. (2013). Technical specifications for road pavements, Autostrade per l’Italia, Rome.
Biligiri, K. P., Said, S., and Hakim, H. (2012). “Asphalt mixtures’ crack propagation assessment using semi-circular bending tests.” Int. J. Pavement Res. Technol., 5(4), 209–217.
British Standard Institution (BSI). (1997). “Method for the determination of the fatigue characteristics of bituminous mixtures using indirect tensile fatigue.” BS DD ABF, London, U.K.
Canestrari, F., Ferrotti, G., Cardone, F., and Stimilli, A. (2014). “Innovative testing protocol for the evaluation of binder-reclaimed aggregate bond strength.” Proc., 93rd Annual Meeting of the Transportation Research Board, Transportation Research Board, Washington, DC.
Celauro, C., Celauro, B., and Boscaino, G. (2010). “Production of innovative, recycled and high-performance asphalt for road pavements.” Resour Conserv Recycl., 54(6), 337–347.
Copeland, A. (2011). “Reclaimed asphalt pavement in asphalt mixtures: State of the practice.”, Federal Highway Administration, U.S. Dept. of Transportation, Washington, DC.
De La Roche, C., et al. (2013). “Hot recycling of bituminous mixtures. Advances in interlaboratory testing and evaluation of bituminous materials.”, Springer, Heidelberg, 361–428.
European Committee for Standardization (CEN). (2006). “Bituminous mixtures—Test methods for hot mix asphalt—Part 23: Determination of the indirect tensile strength of bituminous specimens.” EN 12697-23, Brussels, Belgium.
European Committee for Standardization (CEN). (2007a). “Bitumen and bituminous binders—Determination of kinematic viscosity.” EN 12595, Brussels, Belgium.
European Committee for Standardization (CEN). (2007b). “Bitumen and bituminous binders—Determination of needle penetration.” EN 1426, Brussels, Belgium.
European Committee for Standardization (CEN). (2007c). “Bitumen and bituminous binders—Determination of the resistance to hardening under influence of heat and air. RTFOT method.” EN 12607-1, Brussels, Belgium.
European Committee for Standardization (CEN). (2007d). “Bitumen and bituminous binders—Determination of the softening point. Ring and Ball method.” EN 1427, Brussels, Belgium.
European Committee for Standardization (CEN). (2008a). “Bituminous mixtures—Test methods for hot mix asphalt—Part 12: Determination of the water sensitivity of bituminous specimens.” EN 12697-12, Brussels, Belgium.
European Committee for Standardization (CEN). (2008b). “Bituminous mixtures—Test methods for hot mix asphalt—Part 17: Particle loss of porous asphalt specimen.” EN 12697-17, Brussels, Belgium.
European Committee for Standardization (CEN). (2010a). “Bitumen and bituminous binders—Determination of the elastic recovery of modified bitumen.” EN 13398, Brussels, Belgium.
European Committee for Standardization (CEN). (2010b). “Bituminous mixtures—Test methods for hot mix asphalt—Part 44: Crack propagation by semi-circular bending test.” EN 12697-44, Brussels, Belgium.
Fang, F. T., Chong, Y. C., Nyunt, T. T., and Loi, S. S. (2013). “Development of environmentally sustainable pavement mix.” Int. J. Pavement Res. Technol., 6(4), 440–446.
Frigio, F., Pasquini, E., Ferrotti, G., and Canestrari, F. (2013). “Improved durability of recycled porous asphalt.” Constr. Build. Mater., 48, 755–763.
Goh, S. W., and You, Z. (2012). “Mechanical properties of porous asphalt pavement materials with warm mix asphalt and RAP.” J. Transp. Eng., 90–97.
Gubler, R., Partl, M. N., Canestrari, F., and Grilli, A. (2005). “Influence of water and temperature on mechanical properties of selected asphalt pavements.” Mater. Struct., 38(279), 523–532.
Hagos, E. T., Molenaar, A. A. A., Van de Ven, M. F. C., and Voskuilen, J. L. M. (2007). “Durability related investigation into porous asphalt.” Proc., Int. Conf. on Advanced Characterisation of Pavement and Soil Engineering Materials, Taylor and Francis/Balkema, Leiden, The Netherlands.
Karlsson, R., and Isacsson, U. (2006). “Material-related aspects of asphalt recycling—State-of-the-art.” J. Mater. Civ. Eng., 81–92.
Khalid, H. A., and Monney, O. K. (2009). “Moisture damage potential of cold asphalt.” Int. J. Pavement Eng., 10(5), 311–318.
Kim, H., Arraigada, M., Raab, C., and Partl, M. N. (2011). “Numerical and experimental analysis for the interlayer behavior of double-layered asphalt pavement specimens.” J. Mater. Civ. Eng., 12–20.
Kim, S., and Coree, B. J. (2005). “Evaluation of hot mix asphalt moisture sensitivity using the Nottingham asphalt test equipment.”, Center for Transportation Research and Education, Dept. of Civil, Construction, and Environmental Engineering, Iowa State Univ., Ames, IA.
Li, X., and Marasteanu, M. O. (2004). “Evaluation of the low temperature fracture resistance of asphalt mixtures using the semi circular bend test.” J. Assoc. Asphalt Paving Technol., 73, 401–426.
Li, X. J., and Marasteanu, M. O. (2010). “Using semi-circular bending test to evaluate low temperature fracture resistance for asphalt concrete.” Exp. Mech., 50(7), 867–876.
Mahmoud, A. F. F., and Bahia, H. U. (2004). “Using the gyratory compactor to measure mechanical stability of asphalt mixtures.”, Dept. of Civil and Environmental Engineering, Univ. of Wisconsin, Madison, WI.
Mobasher, B., Mamlouk, M. S., and Lin, H. M. (1997). “Evaluation of crack propagation properties of asphalt mixtures.” J. Transp. Eng., 405–413.
Molenaar, A. A. A., Mohajeri, M., and van de Ven, M. F. C. (2011). “Design of recycled asphalt mixtures.” Proc., AAPA’s 14th Int. Flexible Pavement Conf., Australian Asphalt Pavement Association, Kew, VIC, Australia.
Partl, M. N., Canestrari, F., Grilli, A., and Gubler, R. (2008). “Characterization of water sensitivity of asphalt mixtures with coaxial shear test.” Road Mater. Pavement, 9(2), 247–270.
Partl, M. N., Pasquini, E., Canestrari, F., and Virgili, A. (2010). “Analysis of water and thermal sensitivity of open graded asphalt rubber mixtures.” Constr. Build. Mater., 24(3), 283–291.
Pasetto, M., and Baldo, N. (2006). “Electric arc furnace steel slags in ‘high performance’ asphalt mixes: A laboratory characterisation.” Fall Extraction and Processing Div.: Sohn Int. Symp., Wiley, Hoboken, NJ.
Pasetto, M., and Baldo, N. (2008). “Comparative performance analysis of bituminous mixtures with EAF steel slags: A laboratory evaluation.” Proc., Global Symp. on Recycling, Waste Treatment and Clean Technology, Wiley, Hoboken, NJ.
Poulikakos, L., Takahashi, S., and Partl, M. N. (2007). “Coaxial shear test and wheel tracking tests for determining porous asphalt mechanical properties.” Road Mater. Pavement, 8(3), 579–594.
Poulikakos, L. D., and Partl, M. N. (2009). “Evaluation of moisture susceptibility of porous asphalt concrete using water submersion fatigue tests.” Constr. Build. Mater., 23(12), 3475–3484.
Poulikakos, L. D., and Partl, M. N. (2012). “A multi-scale fundamental investigation of moisture induced deterioration of porous asphalt concrete.” Constr. Build. Mater., 36, 1025–1035.
Sokolov, K., Gubler, R., and Partl, M. N. (2005). “Extended numerical modeling and application of the coaxial shear test for asphalt pavements.” Mater. Struct., 38(279), 515–522.
Sung, C. Y., and Kim, Y. I. (2012). “Void ratio and durability properties of porous polymer concrete using recycled aggregate with binder contents for permeability pavement.” J. Appl. Polym. Sci., 126(S2), E338–E348.
Virgili, A., Partl, M. N., Grilli, A., and Santagata, F. A. (2008). “Damage model for environmental conditioned fatigue test with CAST.” Fatigue Fract. Eng. Mater. Struct., 31(11), 967–979.
Xiao, F., and Amirkhanian, S. N. (2009). “Laboratory investigation of moisture damage in rubberized asphalt mixtures containing reclaimed asphalt pavement.” Int. J. Pavement Eng., 10(5), 319–328.
Xiao, F., Amirkhanian, S. N., and Juang, C. H. (2007). “Rutting resistance of rubberized asphalt concrete pavements containing reclaimed asphalt pavement mixtures.” J. Mater. Civ. Eng., 475–483.
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Published In
Journal of Materials in Civil Engineering
Volume 27 • Issue 7 • July 2015
Copyright
© 2014 American Society of Civil Engineers.
History
Received: Dec 6, 2013
Accepted: Aug 20, 2014
Published online: Sep 18, 2014
Discussion open until: Feb 18, 2015
Published in print: Jul 1, 2015
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