Your search keyword '"David Blanco Fernández"' showing total 2 results

1. The Design and Development of Recycled Concretes in a Circular Economy Using Mixed Construction and Demolition Waste

Author

Marcos Díaz González, Pablo Plaza Caballero, David Blanco Fernández, Manuel Miguel Jordán Vidal, Isabel Fuencisla Sáez del Bosque, and César Medina Martínez

Subjects

recycled concrete, recycled mixed sand, recycled mixed gravel, mechanical properties, strength, watertightness, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

This research study analysed the effect of adding fine—fMRA (0.25% and 50%)—and coarse—cMRA (0%, 25% and 50%)—mixed recycled aggregate both individually and simultaneously in the development of sustainable recycled concretes that require a lower consumption of natural resources. For this purpose, we first conducted a physical and mechanical characterisation of the new recycled raw materials and then analysed the effect of its addition on fresh and hardened new concretes. The results highlight that the addition of fMRA and/or cMRA does not cause a loss of workability in the new concrete but does increase the amount of entrained air. Regarding compressive strength, we observed that fMRA and/or cMRA cause a maximum increase of +12.4% compared with conventional concrete. Tensile strength increases with the addition of fMRA (between 8.7% and 5.5%) and decreases with the use of either cMRA or fMRA + cMRA (between 4.6% and 7%). The addition of fMRA mitigates the adverse effect that using cMRA has on tensile strength. Regarding watertightness, all designed concretes have a structure that is impermeable to water. Lastly, the results show the feasibility of using these concretes to design elements with a characteristic strength of 25 MPa and that the optimal percentage of fMRA replacement is 25%.

Published

2021

2. The Design and Development of Recycled Concretes in a Circular Economy Using Mixed Construction and Demolition Waste

Author

David Blanco Fernández, Isabel F. Sáez del Bosque, Manuel Miguel Jordán Vidal, César Medina Martínez, Pablo Plaza Caballero, and Marcos Díaz González

Subjects

Characteristic strength, Technology, recycled concrete, Materials science, Design elements and principles, mechanical properties, Raw material, watertightness, Article, Ultimate tensile strength, General Materials Science, Microscopy, QC120-168.85, Aggregate (composite), QH201-278.5, recycled mixed gravel, Engineering (General). Civil engineering (General), Pulp and paper industry, TK1-9971, recycled mixed sand, Compressive strength, Descriptive and experimental mechanics, Demolition waste, Electrical engineering. Electronics. Nuclear engineering, TA1-2040, strength

Abstract

This research study analysed the effect of adding fine—fMRA (0.25% and 50%)—and coarse—cMRA (0%, 25% and 50%)—mixed recycled aggregate both individually and simultaneously in the development of sustainable recycled concretes that require a lower consumption of natural resources. For this purpose, we first conducted a physical and mechanical characterisation of the new recycled raw materials and then analysed the effect of its addition on fresh and hardened new concretes. The results highlight that the addition of fMRA and/or cMRA does not cause a loss of workability in the new concrete but does increase the amount of entrained air. Regarding compressive strength, we observed that fMRA and/or cMRA cause a maximum increase of +12.4% compared with conventional concrete. Tensile strength increases with the addition of fMRA (between 8.7% and 5.5%) and decreases with the use of either cMRA or fMRA + cMRA (between 4.6% and 7%). The addition of fMRA mitigates the adverse effect that using cMRA has on tensile strength. Regarding watertightness, all designed concretes have a structure that is impermeable to water. Lastly, the results show the feasibility of using these concretes to design elements with a characteristic strength of 25 MPa and that the optimal percentage of fMRA replacement is 25%.

Published

2021