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Healing by magnetic induction of a novel cold pavement with asphalt emulsion and industrial by-products

Abstract: This research evaluated the feasibility of magnetic induction self-healing of a novel cold porous asphalt mixture made from asphalt emulsion and an industrial by-product. The study consisted of three phases: first, the feasibility of magnetic induction healing was determined using a break-heal-break cycle. Secondly, the consequences of the repeated healing process were determined both in the bitumen, through penetration, ring and ball and dynamic shear rheometer tests and in the mixture, through flexural, interconnected voids and permeability tests. Thirdly, the impact of varying the healing cycles on the particle loss performance was evaluated using the cantabro test. The results were as follows: firstly, the use of magnetic induction is feasible and achieves 91% healing in the novel cold porous asphalt mixture. Secondly, regarding the consequences of repeating the healing process: at the rheological level, the viscosity and stiffness of the binder increases while at the mixture level, it is posible to repeat the healing process, since although the healing capacity decreases due to the increased hardness of the binder, the flexural strength also increases with increasing stiffness. Regarding the internal structure and permeability test, repeating the process leads to a reduction in the percentage of interconnected voids, which negatively affects the permeability of the mixture. Thirdly, the healing process by magnetic induction improves the performance against particle loss

 Authorship: DeLaFuente-Navarro C., Lastra-González P., Indacoechea-Vega I., Castro-Fresno D.,

 Fuente: Developments in the Built Environment, 2024, 18, 100417

 Publisher: Elsevier

 Publication date: 01/04/2024

 No. of pages: 11

 Publication type: Article

 DOI: 10.1016/j.dibe.2024.100417

 ISSN: 2666-1659

 Spanish project: PDC2021-120824-100

 Publication Url: https://doi.org/10.1016/j.dibe.2024.100417