高碳共底物对间歇反应器厌氧共消化稳定性和性能的影响

IF 0.8 Q4 ENGINEERING, ENVIRONMENTAL

Proceedings of the Institution of Civil Engineers-Waste and Resource Management Pub Date : 2022-02-28 DOI:10.1680/jwarm.21.00033

Mohammad Kuroshkarim, M. Rasouli, M. Pazoki

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引用次数: 0

摘要

研究了木屑、小球藻和牛粪的厌氧共消化。在混合物中加入锯末以增加可用碳的量。本研究旨在确定将纤维素材料作为碳的丰富来源纳入主要基质的影响。利用共消化在进水中产生C/N梯度，研究了底物组成与沼气产量之间的关系。在这项研究中，19个容量为500毫升的反应器被填充到350毫升的水平，并在37.5摄氏度的中温环境下运行。消化饲料总固形物(TS)为3.8%，反应器停留时间为30 d。采用Design Expert 13软件和混合设计进行试验设计。在反应器中添加锯末(7% ~ 10%)可将反应器中混合物的碳/氮(C/N)比提高到最佳值(22)，并使沼气产量增加25% ~ 35%。在8.3%锯末、33.3%藻类和58.3%牛粪的混合物中，每天平均产气量最大为231 ml。在TS有机负荷较低时加入锯末，可以防止反应器酸化，增加稳定性，提高沼气产量。·添加高碳共底物改善了藻类与动物粪便厌氧共消化过程。·将RSM上的混合设计方法成功应用于AD工艺响应预测。·在反应器中加入木屑提高了C/N比、反应器的稳定性和沼气产量。·最大沼气产量提高近35%。

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The effect of high carbon co-substrates on the stability and performance of anaerobic co-digestion in the batch reactor

In this study, the anaerobic co-digestion of a mixture of sawdust, chlorella microalgae and cow manure was examined. Sawdust was added to the mixture to increase the amount of carbon available. This study has been designed to determine the impact of incorporating cellulosic material as a rich source of carbon into main substrates. Using co-digestion to create a C/N gradient in the influent, a relationship between substrate composition and biogas production was investigated. During this study, 19 reactors of 500 ml capacity were filled to a level of 350 ml and operated at a mesophilic temperature of 37.5 Celsius degree. Total solids (TS) in the digester feed were 3.8% and retention time in the reactors was 30 days. Design Expert 13 software and mixture design was used to design the experiments. Adding sawdust to the reactors (7%-10%) improved the carbon/nitrogen (C/N) ratio of the mixture in the reactors to an optimal value (22) and produced 25%-35% more biogas. The maximum average amount of gas produced per day from a mixture of 8.3% sawdust, 33.3% algae and 58.3% cow manure was 231 ml. Adding sawdust when the TS is low in organic load prevents the reactors from acidifying, increases the stability and improves biogas output. Highlights · Adding high carbon co-substrate improved the anaerobic co-digestion process of algae and animal waste. · Mixture design method on RSM was successfully applied to predict the responses for AD process. · Adding sawdust to the reactors improved the C/N ratio, stability of the reactors, and biogas production. · The maximum biogas production was increased by nearly 35%.

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来源期刊

Proceedings of the Institution of Civil Engineers-Waste and Resource Management ENGINEERING, ENVIRONMENTAL-

CiteScore

1.70

自引率

14.30%

发文量

期刊介绍： Waste and Resource Management publishes original research and practice papers on all civil engineering and construction related aspects of the resource management cycle, from the minimization of waste, through the re-use and recycling, to the management and disposal of residual wastes. Associated legislation, standards, socio-economic considerations and links with sustainable consumption and production are included. The range of subjects covered encompasses, but is not restricted to, strategies for reducing construction waste through better design, improved recovery and re-use, more efficient resource management, the performance of materials recovered from wastes, and, the procurement, planning, design, construction, operation and logistics of waste and resource management facilities.