December 4, 2024
Mohsen Nowrouzi

Mohsen Nowrouzi

Academic Rank: Associate professor
Address: Persian Gulf University
Degree: Ph.D in Environment - Environmental pollution
Phone: 09177827960
Faculty: Faculty of Nano and Biotechnology

Research

Title Trickling filter systems for sustainable water supply: An evaluation of eco-environmental burdens and greenhouse gas emissions
Type Article
Keywords
Energy footprint Exergy analysis ,Greenhouse gas emissions ,Life cycle assessment ,Life cycle cost Trickling filter
Journal ENVIRONMENTAL RESEARCH
DOI https://doi.org/10.1016/j.envres.2023.117011
Researchers Hajar Abyar (First researcher) , Mohsen Nowrouzi (Second researcher)

Abstract

Despite the global water crisis, the significant potential of trickling filter systems as a crucial auxiliary option for sustainable water supply has received insufficient attention. Therefore, this study presents the first-ever evaluation of the environmental impacts of trickling filter application in wastewater treatment, focusing on ecoenvironmental burdens. Additionally, the study explores greenhouse gas emissions, energy, and exergy footprints, providing novel insights into the environmental implications of using trickling filters for wastewater treatment. The study’s findings indicate that the consumption of heat and electricity in trickling filters has significant environmental impacts, particularly on land use (93.24%), freshwater/marine eutrophication (~81.98%), and human health (45.36%). The majority of the energy required for trickling filter operation is supplied by fossil fuels (96.02%), resulting in increased greenhouse gas emissions (65.58%). The exergy of trickling filters is highly efficient, accounting for over 95% of the system’s energy. Mathematical modeling reveals that anaerobic digestion and secondary clarifier have the highest energy consumption, with contributions of 94.65% and 2.63%, respectively. Construction expenses account for almost 88% of the total cost, with anaerobic digestion (42.15%) and trickling filters (35.39%) being the most costly components. The cost of treating 1 m3 of wastewater is estimated at 0.52 $/m3. Sensitivity analysis demonstrates that electricity (14.66%) and heat (18.65%) significantly impact terrestrial ecotoxicity and land use, respectively. This study presents a framework for future investigations in this field.