Transforming municipal solid waste management through material and substance flow analysis: Conversion pathways for sustainable energy production
[Display omitted] •Present research addresses the critical issues of MSW management in New Delhi.•Material flow analysis and substance flow analysis has been discussed to evaluate MSW practices.•Analysis of six scenarios, including conventional methods and advanced thermochemical technologies has be...
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Veröffentlicht in: | Energy conversion and management 2024-12, Vol.322, p.119164, Article 119164 |
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Sprache: | eng |
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•Present research addresses the critical issues of MSW management in New Delhi.•Material flow analysis and substance flow analysis has been discussed to evaluate MSW practices.•Analysis of six scenarios, including conventional methods and advanced thermochemical technologies has been presented.•Findings support the transition to a circular economy through enhanced waste-to-energy efficiency.
Municipal solid waste (MSW) management poses a significant challenge due to escalating waste generation and their environmental impacts. This study presents a comprehensive analysis of MSW management in India, specifically New Delhi through material and substance flow analysis, focusing on conversion pathways for sustainable energy production. We investigated conventional methods, including composting, recycling, and incineration, alongside advanced single stage and two-stage thermochemical technologies. This research evaluates a series of scenarios, including a baseline case and alternative pathways that exclude incineration, and compare the effectiveness of different MSW management routes in terms of resource recovery and burden on landfill. Six different scenarios were analyzed; the most effective waste-to-energy route is Scenario 6, enhanced integrated thermochemical conversion with recycling, which produced 6,427 tpd of product from 11,300 tpd MSW. Although Scenario 5, with a recycling facility that includes integrated thermochemical conversion, recovers 6,454 tpd of product, is less practicable in the long term. The two scenarios are remarkable compared to the baseline scenario, from which only 3,690 tpd of product is produced. These integrated processes thus reduce the pressure on landfills and are an entrance into a circular economy. The results potentially indicate resource recovery rates up to 57% from current rate of only 32%. The findings highlight the potential of integrated thermochemical processes in improving waste-to-energy efficiency and reducing greenhouse gas emissions. This research contributes to the development of more effective waste management solutions and provides actionable insights, supporting the transition towards a circular economy. |
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ISSN: | 0196-8904 |
DOI: | 10.1016/j.enconman.2024.119164 |