Process performance of in-situ bio-methanation for co-digestion of sewage sludge and lactic acid, aiming to utilize waste poly-lactic acid as methane.

IF 9.7 1区环境科学与生态学 Q1 AGRICULTURAL ENGINEERING Bioresource Technology Pub Date : 2025-02-01 Epub Date: 2024-12-04 DOI:10.1016/j.biortech.2024.131945

Shinya Akimoto, Jun Tsubota, Shinya Tagawa, Tatsuaki Hirase, Irini Angelidaki, Taira Hidaka, Taku Fujiwara

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Abstract

This study examined hydrogen conversion efficiency and operational stability in pilot-scale in-situ bio-methanation during the co-digestion of sewage sludge and lactic acid (partially derived from waste poly-lactic acid). Parallel laboratory-scale experiments were also conducted. In the pilot, hydrogen conversion efficiency decreased from 98.9 % to 84.4 % as the hydrogen feed rate increased from 240 to 1,200 mL/L_R/d. Conversely, laboratory experiments maintained efficiencies above 95 % at a feed rate of 3,600 mL/L_R/d, suggesting that hydrogen gas-liquid transfer limited hydrogen conversion efficiency in the pilot. Lactic acid degradation was observed both with and without hydrogen injection in the pilot. Methane yields from the acid were 310 ± 30 and 300 ± 30 mL/g (chemical oxygen demand (COD))-added, close to the theoretical methane yield (350 mL/gCOD). These results demonstrate the importance of hydrogen gas-liquid transfer when scaling up bio-methanation processes. Moreover, they showed the potential of waste poly-lactic acid as a methane source.

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原位生物甲烷化污泥与乳酸共消化的工艺性能，目的是利用废聚乳酸作为甲烷。

本研究考察了污水污泥和乳酸（部分来自废聚乳酸）共消化过程中试规模原位生物甲烷化过程中的氢转化效率和运行稳定性。平行实验室规模的实验也进行了。在中试中，随着加氢速率从240 ~ 1200 mL/LR/d增加，氢气转化率从98.9 %下降到84.4 %。相反，在实验室实验中，当进料速率为3,600 mL/LR/d时，效率保持在95% %以上，这表明在中试中，氢气-液体传递限制了氢气转化效率。在中试中，观察了加氢和不加氢对乳酸的降解。该酸的甲烷产率分别为310 ± 30和300 ± 30 mL/g（化学需氧量），接近理论产率（350 mL/gCOD）。这些结果证明了氢气-液体转移在扩大生物甲烷化过程中的重要性。此外，他们还展示了废聚乳酸作为甲烷源的潜力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Bioresource Technology 工程技术-能源与燃料

CiteScore

20.80

自引率

19.30%

发文量

2013

审稿时长

12 days

期刊介绍： Bioresource Technology publishes original articles, review articles, case studies, and short communications covering the fundamentals, applications, and management of bioresource technology. The journal seeks to advance and disseminate knowledge across various areas related to biomass, biological waste treatment, bioenergy, biotransformations, bioresource systems analysis, and associated conversion or production technologies. Topics include: • Biofuels: liquid and gaseous biofuels production, modeling and economics • Bioprocesses and bioproducts: biocatalysis and fermentations • Biomass and feedstocks utilization: bioconversion of agro-industrial residues • Environmental protection: biological waste treatment • Thermochemical conversion of biomass: combustion, pyrolysis, gasification, catalysis.