This article deals with the influence of the partial substitution of bitumen by a mixture of sulphur and tyre and plastic bottle powders on the characterization of asphalt concrete. The approach adopted was to subject a control asphalt concrete to level 2 formulation tests as well as those modified at 10%, 20%, 30% and 40% by substituting bitumen with a mixture of tyre powder, plastic bottle powder and sulphur at 40%, 28% and 32% respectively. The results of the PCG, Duriez and rutting tests carried out on the control and modified bituminous concretes (manufactured using the wet process) revealed three (03) major findings, in particular with regard to workability, resistance to simple compression and rutting. The experimental results show an increasing trend in the essential parameters. At 40% substitution, there was a 22.73% increase in compactness, reflecting a significant improvement in the material’s workability. With regard to simple compressive strength, the increase is 34.02% at 40% substitution, highlighting the limitation of crack formation and propagation under heavy precipitation. With regard to rutting, the 16% drop in susceptibility at 40% substitution reflects a significant improvement in the behaviour of the material under dynamic mechanical stresses in heavy precipitation. The improvement in these behaviours results from the insertion of the plastic bottle powder into the interstices of the granular skeleton, thus reducing its cellular structure, and also from the interactions between the sulphur with the tyre powder and the sulphur with the plastic bottle powder, i.e. cross-linking or vulcanisation.
References
[1]
Dongmo-Engeland, J.B. (2005) Characterization of Rutting Deformations in Bituminous Pavements. National Institute of Applied Sciences of Lyon, Lyon, 266 p.
[2]
Kouidri, D. and Mebarka, T. (2017) Influence of Plastic Waste on the Performance of Dune Sand Asphalt Concrete. Université Kasdi Merbah Ouargla, Ouargla, 104 p.
[3]
Boukhari, A., Kébaiili, N. and Bouchebra, M. (2017) Asphalt Concrete Modified with Plastic Waste “Study to Determine the Modification Interval”. 2nd National Seminar on Roads and Airfields in Arid Zones (SANARAZA 2015), Université Kasdi Merbah Ouargla, Ouargla, 27 p.
[4]
Nicholls, J.C. (2009) Review of Shell Thiopave Sulfur-Extended Asphalt Modifier. TRL Report TRL672. National Academy of Sciences, USA, 10 p.
[5]
Trang, N.T., Hung, T.N., Khang, P.H., Cậy, B.X. and Kien, B.N. (2021) Research on the Effects of Sulfur on Characteristics of Sulfur Bituminous Binder (SBB) and Hot Mix Asphalt-Sulfur (HMAS). Transport and Communications Science Journal, 72, 33-45. https://doi.org/10.47869/tcsj.72.1.5
[6]
Luttringer, A.D. (1926) The Encyclopedia of Hard Rubber. A.-D. Cillard, Rue des vinaigriers-Paris X, Paris, 212 p.
[7]
Cheheb, Z. (2012) Measurement of the Thermal Properties of Rubber-Based Compounds under Processing Conditions. University of Nantes, Nantes, 232 p.
[8]
Kawanou, H., Tchehouali, D., Sanya, A. and Vianou, K. (2014) Effects of Incorporating Plastic Bag Waste Melt on Bitumen Consistency and Asphalt Concrete Stability. Afrique Science Journal, 10, 39-52.
[9]
Said, L. (2013) Course at the University of Montreal in Canada: Asphalt Mixes. 38 p.
[10]
Saoula, S. (2008) Improvement of the Stability of Modified Bituminous Binders within EVA. International Journal of Applied Engineering Research, 7, 575-584.
[11]
Guide for the Manufacture of Asphalt Mixes with Rubber Powder from Used Tyres in Spain 2014. José Bermejo Munoz, Juan Gallego Medina and Leticia Saiz Rodrguez, Madridk.
[12]
Ratsifaherandahy Flemond, D., Mamiharijaona, R., Rajaonah, R., Ramorason, J. and Randriamalala Tiana, R. (2022) Improving the Mechanical Performance of Semi-Grained Asphalt Concrete with Pure Bitumen and Waste Plastics. American Journal of Innovative Research and Applied Sciences, 15, 123-130.
[13]
VINCI: Direction Technique de EUROVIA (2002) Technical Opinion on a Non-Rutting Bituminous Concrete: REXOVIA. Pierre Anjolras, Canada, 4 p.
[14]
COLAS: Comité Français pour les Techniques Routières (2002) Technical Opinion on Thin Bituminous Concrete 0/10 or 0/14: LE RUFLEX M. Frédéric Gardès, Paris, 12 p.
[15]
SCREG Technical and Development Department (2006) Energy-Efficient Asphalt Mixes. Environmental Surfacings: ECOFLEX LT. Thomas Pruvost, Lyon, 2 p.
[16]
COLAS (2003) Technical Note 6 on a Very High Performance Asphalt Mix: MULTICOL. Guillaume Goes, Boulogne-Billancourt, 6 p
[17]
Zadjaoui, A., Karam, F. and Bendimerad, A. (2015) Control of High Modulus Bituminous Concrete Paving Works: Case of Western Algeria.78 p.
[18]
Gentles, M.J., Moss, J.B., Herzog, H.L. and Hershberg, E.B. (1958) The Dienol-Benzene Rearrangement.1 Some Chemistry of 1,4-Androstadiene-3,17-Dione. Journal of the American Chemical Society, 80, 3702-3705. https://doi.org/10.1021/ja01547a058
[19]
Yamashita, S., Nishimura, J., Furukawa, M. and Yoshino, T. (1981) C3 Cyclopolymerization. Journal of Polymer Science: Polymer Chemistry Edition, 8, 77-93.
[20]
Mohamed Brahim, H., Daas, D. and Kebaili, N. (2014) Experimental Study of Asphalt Concrete Modified with Rubber Powder-Influence of Modification Mode. Revue ElWahat pour les Recherches et les Etudes, 7, 33-43.
[21]
Kebaili, N. (2017) Rubber Asphalt: Recycling of Rubber Power in Road Construction. Université Kasdi Merbah Ouargla, Ouargla, 152 p.
[22]
Plieninger, H. and Keilich, G. (1956) Die Dienol-Benzol-Umlagerung. Angewandte Chemie, 68, 618. https://doi.org/10.1002/ange.19560681914
[23]
Murillo, R., Aylon, E., Navarro, M.V., Callen, M.S., Aranda, A. and Mastral, A.M. (2006) The Application of Thermal Processes to Valorise Waste Tyre. Fuel Processing Technology, 87, 143-147. https://doi.org/10.1016/j.fuproc.2005.07.005
[24]
Nouali, M. (2021) Valorisation of Waste Plastic Bags for More Efficient Road Mixes. Academic Journal of Civil Engineering, 39, 251-258.
[25]
Zhang, Y., Wang, S., Lee, Y. and Li, Y. (2018) Study on the Mechanical Properties of Asphalt Concrete with Waste Tire Rubber Powder. Construction and Building Materials Journal, 191, 946-953.
