A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
Sustainable Construction Materials from Industrial By-products
The development of sustainable construction materials is crucial for addressing environmental concerns and advancing eco-conscious building practices. In this study, we investigate the potential of sulfur-containing concrete formulations, aiming to enhance durability, reduce environmental impact, and meet the growing demand for eco-friendly building materials. The creation of sustainable concrete blends integrating sulfur, fine aggregates, and industrial waste materials. Through a process of heating, mixing, molding, and testing, the mechanical strength of the resulting fume treatment plant (FTP) and direct reduction of iron (DRI) with lime (L) samples is assessed, revealing heightened compressive strength compared to traditional concrete. Chemical analysis corroborates low chloride and sulfate content, fortifying the concrete’s resilience against environmental stressors. These findings underscore the potential of sulfur-infused concrete for diverse construction needs, offering both durability and sustainability benefits. With applications spanning infrastructure, urban development, and marine projects, this innovative material aligns with the industry’s shift toward eco-friendly building practices and addresses growing environmental concerns.
Sustainable Construction Materials from Industrial By-products
The development of sustainable construction materials is crucial for addressing environmental concerns and advancing eco-conscious building practices. In this study, we investigate the potential of sulfur-containing concrete formulations, aiming to enhance durability, reduce environmental impact, and meet the growing demand for eco-friendly building materials. The creation of sustainable concrete blends integrating sulfur, fine aggregates, and industrial waste materials. Through a process of heating, mixing, molding, and testing, the mechanical strength of the resulting fume treatment plant (FTP) and direct reduction of iron (DRI) with lime (L) samples is assessed, revealing heightened compressive strength compared to traditional concrete. Chemical analysis corroborates low chloride and sulfate content, fortifying the concrete’s resilience against environmental stressors. These findings underscore the potential of sulfur-infused concrete for diverse construction needs, offering both durability and sustainability benefits. With applications spanning infrastructure, urban development, and marine projects, this innovative material aligns with the industry’s shift toward eco-friendly building practices and addresses growing environmental concerns.
Sustainable Construction Materials from Industrial By-products
Green Energy,Technology
Chen, Lin (editor) / Dagher, Sawsan (author) / Alabdouli, Khalefah (author) / AlHosani, Ahmead (author) / Hnan, Yousif (author) / Aljneibi, Khalid (author) / Binsafwan, Mohamed (author) / Akhozheya, Boshra (author) / El Gamal, Maisa (author)
2024-09-21
10 pages
Article/Chapter (Book)
Electronic Resource
English
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