Optimization of the methane production in batch anaerobic digestion of maize straw by adjustment of total solid and substrate-to-inoculum ratio based on kinetics
作者机构:Guangzhou Institute of Energy ConversionChinese Academy of SciencesGuangzhou 510640China Guangdong Provincial Key Laboratory of New and Renewable Energy Research and DevelopmentGuangzhou 510640China College of EngineeringNortheast Agricultural UniversityHarbin 150030China
出 版 物:《International Journal of Agricultural and Biological Engineering》 (国际农业与生物工程学报(英文))
年 卷 期:2024年第17卷第1期
页 面:225-231页
核心收录:
学科分类:07[理学] 070304[理学-物理化学(含∶化学物理)] 0828[工学-农业工程] 0703[理学-化学]
基 金:the Key R&D Project of Heilongjiang Province(Grant No.GY2021ZB0253/GA21D009) the Technological Project of Heilongjiang Province“the open competition mechanism to select the best candidates”(Grant No.2022ZXJ05C01) Guangzhou Science and Technology Plan Project(Grant No.2023B03J1229).
主 题:maize straw dry anaerobic digestion methane production microbial characteristics kinetic model
摘 要:Anaerobic digestion(AD)operating under conditions of organic overload stress typically exacerbates the potential for process instability,thereby resulting in significant economic and ecological ramifications.In this investigation,an augmented substrate-to-inoculum ratio(S/I)along with varying total solid content(TS)levels was employed to replicate diverse organic loadings,utilizing maize straw and cattle manure.The findings reveal that a moderate augmentation in S/I and TS proves advantageous in augmenting methane yield,while an excessive substrate loading diminishes methane yield,hampers the kinetics of methane production,and even induces severe process instability.Kinetic study also displayed the variation of the model parameters for the first-order model,the modified Gompertze model,and the transfer function model.Both the modified Gompertze model and transfer function model exhibited the same environmental stress trend.Thus,both the increase in particulate content and the increase in S/I had a substantial effect on the substrate conversion rate to methane.Microbial analysis demonstrates the dominant influence of Firmicutes and Methanosarcina under different organic loading stresses.From both a kinetic and a microbiological point of view,this work provides novel insights into the fundamental processes that regulate anaerobic digestion(AD)under varying loading stress.Furthermore,it has significant implications for improving the operating efficiency of AD,which is a significant benefit.