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Airfield flexible pavement using waste foundry sand and water-based VAE copolymer binder – studies on mechanical, thermal and weathering effect

Airfield runways, taxiways, and aprons were primarily comprised of asphalt bituminous flexible pavement. Although, asphalt bituminous pavement possesses critical aspects such as abrasion, spalling, thermal degradation as well as UV radiation effects. In this aspect, the asphalt bitumen has been comp...

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Published in:Innovative infrastructure solutions : the official journal of the Soil-Structure Interaction Group in Egypt (SSIGE) 2024-08, Vol.9 (8), Article 305
Main Authors: Srinivasan, Deepasree, Ramachandran, Sasikumar, Murugesan, Arun, Muthukaruppan, Alagar, Ismail, Abdul Aleem Mohamed
Format: Article
Language:English
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Summary:Airfield runways, taxiways, and aprons were primarily comprised of asphalt bituminous flexible pavement. Although, asphalt bituminous pavement possesses critical aspects such as abrasion, spalling, thermal degradation as well as UV radiation effects. In this aspect, the asphalt bitumen has been completely replaced by water-based polymeric binder vinyl acetate ethylene (VAE) copolymer emulsion to get better properties over the above concern. In addition, disposal of spent foundry sand (SFS) causes environmental contamination such as land and soil pollution via the leaching of metallic oxides, alternatively, it can be used as a raw material in the field of construction. Compared to conventional filler material, the spent foundry sand possesses higher surface area and thus improves the performance of the pavement by enhancing the binding of the fillers. The top layer of the polymeric pavement has been tested for mechanical, thermal, ultraviolet irradiation and microstructural properties in laboratory scale. The spent foundry sand was mixed with varying weight percentages, i.e., 10, 15, 20 and 25 wt % of VAE emulsion (SC10-SC25) and compressed, then allowed to polymerize at room temperature for 48 h. Out of various mixes, SC-25 exhibits better performance by enhancing the compressive stress triple times over the conventional asphalt bitumen pavement and it showed good resistance towards moisture adsorption (water contact angle 118º). VAE possesses UV protection with zero transmittance rates due to the presence of an aliphatic compound in it. The abrasion resistance in terms of weight loss was found to be 1.08%. The outcome of the research paves an avenue for alternate binders as well as utilizing spent foundry sand as filler for the effective laying of flexible pavement over conventional materials.
ISSN:2364-4176
2364-4184
DOI:10.1007/s41062-024-01618-y