水热液化
生命周期评估
城市固体废物
废物管理
环境科学
温室气体
生物炭
能量回收
生物量(生态学)
原材料
化石燃料
生物能源
环境影响评价
生物燃料
燃烧
环境工程
工程类
绿色废弃物
液化
持续性
碳足迹
全球变暖
资源回收
蔗渣
可再生能源
焚化
废物转化为能源
危险废物
作者
Seshasayee Mahadevan Subramanya,Phillip E. Savage,Rui Shi
标识
DOI:10.1021/acssuschemeng.5c02136
摘要
We developed a gate-to-grave life cycle assessment (LCA) and techno-economic analysis (TEA) framework to elucidate the sustainability implications of hydrothermal liquefaction (HTL) as a valorization technology for municipal solid waste (MSW). This thermochemical treatment method can convert biomass components into bio-oil and biochar and synthetic plastics components into oil and/or monomers. Component additivity models for oil production from the HTL of MSW were integrated with LCA and TEA modeling to perform dynamic cost and life cycle environmental impact assessments. Characterization factors from the US EPA TRACI database were used for impact assessment. Displacement credits were applied for coproduced biochar, terephthalic acid, and bisphenol A. Uncertainties were characterized through Monte Carlo simulation, and global sensitivity analyses identified the key drivers for economic and environmental impacts. Model results showed that simulated municipal waste in the New York City metropolitan area can be processed via HTL (at 425 °C) with a global warming impact of −600 ± 350 kg CO 2 -eq per ton feedstock processed using displacement allocation and produce a gasoline–diesel blend with a minimum fuel selling price of 1.48 ± 0.51 $/gallon. The results indicate that HTL has a potential greenhouse gas saving of 330 kg of CO 2 per ton MSW processed when compared to current MSW waste management practice, i.e., mechanical recycling (25%), composting (10%), combustion (13%), and landfilling (52%). On the other hand, with an energy recovery of 22.6% and energy rate of return (EROI) of 1.21, this pathway falls short of the general recommendation for advanced fuel technologies like HTL, which require an EROI of 2–3, indicating a need for further process optimization. Using higher feedstock–water ratios and lower process temperatures to reach higher process yields could increase the net EROI
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