Study on the Applicability of Elastic Recovery (Resilience) Experiment for Asphalt‐Rubber

Yao, Zechen; Yang, Renfeng; Kang, Jian; Zhang, Zhigang

doi:10.1155/2022/2286794

Advances in Civil Engineering

2022

DOI: 10.1155/2022/2286794

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Study on the Applicability of Elastic Recovery (Resilience) Experiment for Asphalt‐Rubber

Zechen Yao

Renfeng Yang

Jian Kang³

et al.

Abstract: In this paper, the applicability of the elastic recovery (resilience) experiment for asphalt-rubber (AR) binders has been quantitatively assessed. The mechanical model, based on the viscoelastic constitutive relation and particle inclusion theory, was developed. The interfacial detachment between crumb rubber (CR) particles and asphalt caused by stress concentration was analyzed with Weibull statistical equations. Based on the road roughness excitation, the vehicle-road coupling vibration model was established… Show more

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Post-fire impact behaviour of rubberized alkali-activated slag concrete

Soliman

Diab

2023

Can. J. Civ. Eng.

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Rubberized concrete is eco-friendly concrete with improved impact resistance. However, impact loads may also be combined with fire due to blasting, explosions, and earthquake. Hence, this study investigates the post-fire impact behaviour for rubberized alkali-activated slag (AAS) concrete. Static and dynamic properties of AAS mixtures, incorporating 5%, 10%, and 15% crumb rubber, were evaluated under ambient and after exposure to elevated temperatures (200, 400, and 600 °C). Results reveal that AAS properties' degradations were similar to ordinary Portland cement (OPC) at ambient temperature. At elevated temperatures, the differences in hydration products’ nature between AAS and OPC alternated the performance. The formed low Ca/Si ratio calcium silicate hydrated in the AAS exhibited higher stability at elevated temperatures. AAS with 10% rubber content showed an optimum impact performance. Above 400 °C, degradation of the binder microstructure and voids due to rubber particle decomposition adversely affected the impact performance of AAS. The addition of 0.5% steel tire wire showed a high potential sustainable solution to maintain adequate performance.

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Post-fire impact behaviour of rubberized alkali-activated slag concrete

Soliman

Diab

2023

Can. J. Civ. Eng.

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Study on the Applicability of Elastic Recovery (Resilience) Experiment for Asphalt‐Rubber

Cited by 1 publication

References 15 publications

Post-fire impact behaviour of rubberized alkali-activated slag concrete

Post-fire impact behaviour of rubberized alkali-activated slag concrete

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