Abstract: The construction industry has been under increasing pressure to adopt sustainable practices due to its significant contribution to global energy consumption and carbon emissions. Among its key materials, concrete—despite its robustness and versatility—poses environmental challenges, particularly due to the energy-intensive production of cement. This paper investigates sustainable energy solutions in concrete production and usage, focusing on thermal efficiency, material innovation, and economic feasibility. Using experimental data on lightweight thermal concrete systems incorporating insulation and alternative aggregates, the study evaluates their performance in real building environments. Thermal conductivity tests, cost analysis, and durability metrics reveal that incorporating materials such as perlite, pumice, and expanded clay significantly enhances energy conservation without compromising structural integrity. Moreover, when compared with traditional concrete, these solutions offer measurable reductions in operational energy consumption and lifecycle costs. The research further discusses implementation challenges, long-term sustainability impacts, and policy recommendations for broader adoption. Findings affirm that energy-optimized concrete is not only technically viable but also economically advantageous, supporting the transition toward greener construction practices.
Keywords: construction industry, sustainable energy solutions, material innovation, and economic feasibility.
Title: Sustainable Energy Solution of Concrete & Its Economic Feasibility
Author: SADEQ Y I BUMEJDAD
International Journal of Civil and Structural Engineering Research
ISSN 2348-7607 (Online)
Vol. 13, Issue 1, April 2025 - September 2025
Page No: 10-20
Research Publish Journals
Website: www.researchpublish.com
Published Date: 11-April-2025
