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http://hdl.handle.net/10553/129323
Título: | Sustainable Pavement Construction in Sensitive Environments: Low-Energy Asphalt with Local Waste Materials and Geomaterials | Autores/as: | Franesqui García, Miguel Ángel Yepes Temiño, Jorge Valencia Díaz, Samuel |
Clasificación UNESCO: | 3305 Tecnología de la construcción 331304 Material de construcción |
Palabras clave: | Construction Waste Eco-Efficiency Analysis Low-Energy Asphalt Porous Volcanic Aggregate Reclaimed Rubber, et al. |
Fecha de publicación: | 2024 | Proyectos: | Convenio Interadministrativo de Cooperación Entre la Administración Pública de la Comunidad Autónoma de Canarias A Través de la Consejería de Obras Públicas, Transportes y Vivienda y la Universidad de las Palmas de Gran Canaria Para la Elaboración de la “Guía de Recomendaciones Técnicas Para el Diseño y Ejecución de Firmes en la Red de Carreteras de Canarias” | Publicación seriada: | Buildings | Resumen: | Low-energy asphalt techniques, such as warm mix asphalt (WMA), combined with the rational consumption of geomaterials and waste recycling would promote more sustainable and energy-efficient asphalt pavements. In volcanic environments, a significant proportion of aggregate production is discarded due to its extreme porosity, and used tires generate a main environmental issue as well. While recycled rubber powder from tire waste can enhance the mechanical behavior of asphalt, it also raises its viscosity. Therefore, joining rubberized asphalt containing local waste geomaterials with WMA technologies is crucial to reduce the manufacturing temperatures and emissions and to produce more eco-efficient pavements. For this purpose, the most relevant technological characteristics of rubberized warm mix asphalt with residual aggregates from highly vesiculated volcanic rocks are tested in the laboratory and contrasted with conventional mixtures. The outcomes demonstrate not only the feasibility of the production of such mixtures in line with the current specifications, but also show a significant improvement in the resistance to moisture and to plastic deformations, and an improvement in the stiffness modulus. The eco-efficiency indicators conclude that the energy consumption and emissions are reduced by 9%, enabling the reuse of waste materials by more than 95%. | URI: | http://hdl.handle.net/10553/129323 | ISSN: | 2075-5309 | DOI: | 10.3390/buildings14020530 | Fuente: | Buildings [EISSN 2075-5309], v. 14 (2), (Febrero 2024) |
Colección: | Artículos |
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