Your search keyword '"Chougan M"' showing total 2 results

1. Potential of Reusing 3D Printed Concrete (3DPC) Fine Recycled Aggregates as a Strategy towards Decreasing Cement Content in 3DPC.

Author

Skibicki S, Federowicz K, Hoffmann M, Chougan M, Sibera D, Cendrowski K, Techman M, Pacheco JN, Liard M, and Sikora P

Abstract

This paper explores the new potential strategy of using fine recycled aggregates (fRA) derived from waste 3D printed concrete (3DPC) as a substitute for cement in additive manufacturing. This study hypothesizes that fRA can optimize mixture design, reduce cement content, and contribute to sustainable construction practices. Experimental programs were conducted to evaluate the fresh and hardened properties, printability window, and buildability of 3DPC mixes containing fRA. Mixes with replacement rates of cement with fRA by 10 vol%, 20 vol%, 30 vol%, 40 vol%, and 50 vol% were produced. A comprehensive experimental protocol consisting of rheological studies (static and dynamic yield stress), dynamic elastic modulus determination (first 24 h of hydration), flexural and compressive strengths (2 d and 28 d), and an open porosity test was performed. The obtained results were verified by printing tests. In addition, an economic and environmental life cycle assessment (LCA) of the mixes was performed. The results indicate that up to 50 vol% cement replacement with fRA is feasible, albeit with some technical drawbacks. While fRA incorporation enhances sustainability by reducing CO 2 emissions and material costs, it adversely affects the printability window, green strength, setting time, and mechanical properties, particularly in the initial curing stages. Therefore, with higher replacement rates (above 20 vol%), potential optimization efforts are needed to mitigate drawbacks such as reduced green strength and buildability. Notably, replacement rates of up to 20 vol% can be successfully used without compromising the overall material properties or altering the mixture design. The LCA analysis shows that reducing the cement content and increasing the fRA addition results in a significant reduction in mix cost (up to 24%) and a substantial decrease in equivalent CO 2 emissions (up to 48%). In conclusion, this study underscores the potential of fRA as a sustainable alternative to cement in 3D printed concrete., Competing Interests: Author Maxime Liard was employed by the company Sika Technology AG. The remaining authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Published

2024

2. New Materials and Technologies for Durability and Conservation of Building Heritage.

Author

Coppola L, Bellezze T, Belli A, Bianco A, Blasi E, Cappello M, Caputo D, Chougan M, Coffetti D, Coppola B, Corinaldesi V, D'Amore A, Daniele V, Di Maio L, Di Palma L, Donnini J, Ferrara G, Filippi S, Gastaldi M, Generosi N, Giosuè C, Incarnato L, Lamastra F, Liguori B, Macera L, Maqbool Q, Mascolo MC, Mavilia L, Mazzoli A, Medici F, Mobili A, Montesperelli G, Pia G, Redaelli E, Ruello ML, Scarfato P, Taglieri G, Tittarelli F, Tulliani JM, and Valenza A

Abstract

The increase in concrete structures' durability is a milestone to improve the sustainability of buildings and infrastructures. In order to ensure a prolonged service life, it is necessary to detect the deterioration of materials by means of monitoring systems aimed at evaluating not only the penetration of aggressive substances into concrete but also the corrosion of carbon-steel reinforcement. Therefore, proper data collection makes it possible to plan suitable restoration works which can be carried out with traditional or innovative techniques and materials. This work focuses on building heritage and it highlights the most recent findings for the conservation and restoration of reinforced concrete structures and masonry buildings.

Published

2023