利用厌氧混合培养基从合成气和热解废水中回收能源

IF 4.3 3区 生物学 Q1 BIOTECHNOLOGY & APPLIED MICROBIOLOGY Bioresources and Bioprocessing Pub Date : 2024-07-27 DOI:10.1186/s40643-024-00791-3
Alberto Robazza, Anke Neumann
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引用次数: 0

摘要

对快速热解产生的含水冷凝物进行厌氧消化,是一种从废物中提高碳和能源回收率的有前途的技术。合成气是另一种热解产物,可作为辅助底物来提高工艺效率。然而,人们对厌氧培养物协同发酵热解合成气和水冷凝物以及底物毒性的影响了解有限。这项研究调查了嗜中性和嗜热性厌氧混合培养物在半批次瓶式发酵中共同发酵污水污泥或聚乙烯塑料热解产生的合成气和水冷凝物的能力。该研究确定了羧养反应和甲烷生成反应的抑制浓度,检查了特定成分的去除情况,并评估了能量回收潜力。结果表明,合成气和水冷凝物成分(如酚和 N-杂环)的共同发酵取得了成功。然而,水冷凝物的特性和负荷影响了工艺性能和产品的形成。毒性可能是多种毒物协同作用的结果,取决于 PAC 的成分。在 37 °C 时,浓度为 15.6 gCOD/gVSS 和 7.8 gCOD/gVSS 的污水污泥衍生水冷凝物可分别抑制 50%的羧养活性和甲烷生成活性。在 55 °C 条件下,3.9 至 6.8 gCOD/gVSS 的负荷对这两种反应的抑制率均为 50%。聚乙烯塑料冷凝物的毒性较高,在 37 °C 时,2.8 gCOD/gVSS 和 0.3 gCOD/gVSS 会使羧营养率和产甲烷率降低 50%。在 55 °C,0.3 gCOD/gVSS 会抑制 50% 的 CO 吸收率和甲烷生成率。增加 PAC 负荷会降低甲烷产量,促进短链羧酸盐的形成。污水污泥冷凝物中的难降解成分阻碍了电子摩尔的回收,而塑料冷凝物尽管毒性较强,但电子摩尔的回收率却很高。即使面临基质毒性和成分变化带来的挑战,合成气和水性冷凝物的成功转化仍凸显了该技术在推进人为废物流碳和能源回收方面的潜力。
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Energy recovery from syngas and pyrolysis wastewaters with anaerobic mixed cultures

The anaerobic digestion of aqueous condensate from fast pyrolysis is a promising technology for enhancing carbon and energy recovery from waste. Syngas, another pyrolysis product, could be integrated as a co-substrate to improve process efficiency. However, limited knowledge exists on the co-fermentation of pyrolysis syngas and aqueous condensate by anaerobic cultures and the effects of substrate toxicity. This work investigates the ability of mesophilic and thermophilic anaerobic mixed cultures to co-ferment syngas and the aqueous condensate from either sewage sludge or polyethylene plastics pyrolysis in semi-batch bottle fermentations. It identifies inhibitory concentrations for carboxydotrophic and methanogenic reactions, examines specific component removal and assesses energy recovery potential. The results show successful co-fermentation of syngas and aqueous condensate components like phenols and N-heterocycles. However, the characteristics and load of the aqueous condensates affected process performance and product formation. The toxicity, likely resulting from the synergistic effect of multiple toxicants, depended on the PACs’ composition. At 37 °C, concentrations of 15.6 gCOD/gVSS and 7.8 gCOD/gVSS of sewage sludge-derived aqueous condensate inhibited by 50% carboxydotrophic and methanogenic activity, respectively. At 55 °C, loads between 3.9 and 6.8 gCOD/gVSS inhibited by 50% both reactions. Polyethylene plastics condensate showed higher toxicity, with 2.8 gCOD/gVSS and 0.3 gCOD/gVSS at 37 °C decreasing carboxydotrophic and methanogenic rates by 50%. At 55 °C, 0.3 gCOD/gVSS inhibited by 50% CO uptake rates and methanogenesis. Increasing PAC loads reduced methane production and promoted short-chain carboxylates formation. The recalcitrant components in sewage sludge condensate hindered e-mol recovery, while plastics condensate showed high e-mol recoveries despite the stronger toxicity. Even with challenges posed by substrate toxicity and composition variations, the successful conversion of syngas and aqueous condensates highlights the potential of this technology in advancing carbon and energy recovery from anthropogenic waste streams.

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来源期刊
Bioresources and Bioprocessing
Bioresources and Bioprocessing BIOTECHNOLOGY & APPLIED MICROBIOLOGY-
CiteScore
7.20
自引率
8.70%
发文量
118
审稿时长
13 weeks
期刊介绍: Bioresources and Bioprocessing (BIOB) is a peer-reviewed open access journal published under the brand SpringerOpen. BIOB aims at providing an international academic platform for exchanging views on and promoting research to support bioresource development, processing and utilization in a sustainable manner. As an application-oriented research journal, BIOB covers not only the application and management of bioresource technology but also the design and development of bioprocesses that will lead to new and sustainable production processes. BIOB publishes original and review articles on most topics relating to bioresource and bioprocess engineering, including: -Biochemical and microbiological engineering -Biocatalysis and biotransformation -Biosynthesis and metabolic engineering -Bioprocess and biosystems engineering -Bioenergy and biorefinery -Cell culture and biomedical engineering -Food, agricultural and marine biotechnology -Bioseparation and biopurification engineering -Bioremediation and environmental biotechnology
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