Key process of ethanol hydrogen donor promoting the conversion of organic matter in sludge to bio-oil

•Ethanol acts as both a solvent and hydrogen donor, promoting organics dissociation into bio-oil.•Higher temperatures increase bio-oil carbon content and calorific value, up to 30.11 MJ/kg.•Approximately 74.14 % of sludge energy transferred to bio-oil, achieving significant energy recovery.•1 ton sl...

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Published in:Water research (Oxford) 2025-01, Vol.268 (Pt B), p.122753, Article 122753
Main Authors: Dai, Quxiu, Zeng, Linglong, Cen, Qihong, Du, Wang, Ning, Ping, Li, Kai, Guo, Zhiying, Ao, Ran, Xie, Longgui, Ren, Nanqi, Ma, Liping, Yang, Jie, Tian, Guocai, Sun, Xin
Format: Article
Language:English
Subjects:
Bio-oil
Biofuels
Energy
Ethanol
Ethanol - chemistry
Hydrogen - chemistry
Hydrogen donation
Plant Oils
Polyphenols
Sewage - chemistry
Sewage sludge
Waste Disposal, Fluid - methods
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Summary:•Ethanol acts as both a solvent and hydrogen donor, promoting organics dissociation into bio-oil.•Higher temperatures increase bio-oil carbon content and calorific value, up to 30.11 MJ/kg.•Approximately 74.14 % of sludge energy transferred to bio-oil, achieving significant energy recovery.•1 ton sludge producing 240.5 kg of oil and reducing 43.583 kg carbon emissions. To develop clean energy utilization of sewage sludge, this study investigated the conversion behavior of organics and energy in supercritical sludge-ethanol system. The influence of liquefied parameters on products distribution, hydrogen supply process of ethanol for sludge liquefaction, migration of organics, and energy transformation were investigated. Results indicated that ethanol acted as both a solvent and a hydrogen donor. It providing H⋅ to promote organics dissociation for bio-oil production through radical reactions. Formation of new products in bio-oil such as C20H38O2 and C20H38O2 may be caused by H⋅ generated from OH and CH in ethanol. The increase in dodecanes and hexadecanes in bio-oil may be formed by recombination of smaller radicals such as HO·, H·, CH3⋅, CH3CH2⋅ from dissociation of ethanol and organics. Additionally, energy migration process indicated that higher temperatures increased carbon content in bio-oil from 40.88 to 48.92 %, decreased oxygen content from 48.6 to 39.56 %, and raised the calorific value of bio-oil from 29.63 to 30.11 MJ/kg. Besides, approximately 74.14 % of sludge energy transferred to bio-oil, while about 71.94 % of oxygen moved to bio-char, reducing the calorific value of bio-char to 0.03 MJ/kg. Notably, about 240.5 kg of bio-oil can be produced from 1t of sludge, reducing net carbon emissions by 43.583 kg, and presenting a sustainable alternative to fossil fuels. This study innovatively investigated the dual role of ethanol for sludge liquefaction, providing an efficient and sustainable method for energy recovery from sludge.
ISSN:0043-1354
1879-2448
1879-2448
DOI:10.1016/j.watres.2024.122753