The Role of Agriculture Waste in Achieving High Efficacy in Residential Sustainable Buildings in Egypt | ||||
International Journal of Industry and Sustainable Development | ||||
Volume 5, Issue 2, 2024, Page 83-94 PDF (1.41 MB) | ||||
Document Type: Original Article | ||||
DOI: 10.21608/ijisd.2024.298012.1063 | ||||
View on SCiNiTO | ||||
Authors | ||||
Abd El-Rahman El-Lawindy1; Hend Hamdi Abdelkader2; Ahmed Assim ABDULLAH3; Magdi Khalil4; Sohier Mohammed Abobakr 5 | ||||
1Department of Architecture, Faculty of Engineering, Horus University, New Damietta-Egypt | ||||
2Department of Architecture Design, Seoul National University of Science and Technology, Seoul-South Korea. | ||||
3Building Builمding and Construction Techniques, Engineering Department | ||||
4Researcher Dr. Eng. Magdi Khalil Construction Research Institute - National Water Research Center (NWRC) | ||||
5Chemical Engineering Department, Higher Institute of Engineering and Technology, New Damietta | ||||
Abstract | ||||
The enhancement of energy efficiency stands as a paramount strategy in addressing the challenges arising from escalated energy costs. In residential construction, improving energy efficiency primarily involves implementing thermal insulation to create a favorable internal environment while minimizing energy consumption and carbon emissions. An empirical study investigated the thermal conductivity coefficient of various clay bricks infused with cellulose fibers derived from sugarcane bagasse. These fibers were incorporated into the bricks at different concentrations (5%, 10%, 15%, and 20%). The study measured physical properties such as heat capacities, density, and thermal conductivity coefficients. Using the Design Builder program, simulations assessed thermal loads on walls before and after insulation. Our models demonstrate significant reductions in CO₂ emissions: Model A (5% cellulose fiber content) achieved a noteworthy reduction, with CO₂ emissions decreasing to 196,727.5 kg—a remarkable 44.6% improvement compared to the baseline. Model B (10% cellulose fibers) realized a 49.5% reduction in CO₂ emissions relative to the baseline. Model C (15% cellulose fibers) exhibited a 52.1% reduction. Model D (20% cellulose fibers) notably achieved an impressive 63.3% reduction in CO₂ emissions compared to the baseline. The results demonstrated that introducing heat-insulating material (cellulose fibers) reduced the heat transfer coefficient by 44.7%, leading to a significant 39.1% decrease in electricity consumption for heating, a 1.3% reduction in cooling, and an impressive 63.3% decline in CO₂ emissions. These findings strongly support the widespread adoption of thermal insulation in residential buildings to achieve energy savings, cost reduction, ad environmental conservation. | ||||
Keywords | ||||
Clay Bricks; Cellulose Fibers; Energy Consumption; Carbon Emission; Thermal Insulation | ||||
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