E. A. Omondi, P. Ndiba, Gloria Koech Chepkoech, Arnold Aluda Kegode
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Moreover, efficient operation of the process requires an understanding of the relationship between the biogas production and the process parameters. Kinetic models can be useful tools for describing the biogas production process in batch reactors. While the first order kinetics models assume that the rate of biogas production is proportional to the concentration of the remaining substrates, other models such as the modified Gompertz and the Logistic models incorporate the lag phase, a key feature of the anaerobic digestion process. This study aimed to establish the optimum proportion of RSW in co-digestion with WH under mesophilic conditions, and apply kinetics models to describe the biogas production. The study conducted batch co-digestion of WH with 0, 10, 20 and 30% RSW proportions at mesophilic temperature of 32ºC. Co-digestion of WH with 30% RSW proportion improved biogas yield by 113% from 19.15 to 40.85 CH4 ml/(gVS) at 50 days of co-digestion. It also exhibited the most stable daily biogas production and the largest biogas yield. The biomethanation data were fitted with the first order kinetics, modified Gompertz and the Logistic models. Biogas production for co-digestion of WH with 30% RSW proportion was best described by the modified Gompertz model with a biogas yield potential, Mo, of 43.2 ml (gVS)-1d-1; maximum biogas production rate, Rm, of 1.50 ml (gVS)-1d-1; and duration of lag, λ, of 3.89 d.","PeriodicalId":44938,"journal":{"name":"International Journal of Renewable Energy Development-IJRED","volume":" ","pages":""},"PeriodicalIF":2.4000,"publicationDate":"2023-05-04","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Modeling anaerobic co-digestion of water hyacinth with ruminal slaughterhouse waste for first order, modified gompertz and logistic kinetic models\",\"authors\":\"E. A. Omondi, P. 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引用次数: 0
摘要
水葫芦(Eichhornia crassipes)是一种具有大量生物量的入侵水生杂草,是东非维多利亚湖等淡水水体的社会经济和环境问题。控制和清除沼气的努力可以通过生产沼气作为能源加以补充。水葫芦(WH)与瘤胃屠宰场废物(RSW)共消化有可能通过整理工艺参数(如C/N和C/P比、钾浓度和缓冲能力)提高水葫芦的沼气产量。了解RSW作为次要衬底的最佳比例对工艺和操作都很重要。此外,该工艺的有效运行需要了解沼气产量与工艺参数之间的关系。动力学模型是描述间歇式反应器中沼气生产过程的有效工具。虽然一级动力学模型假设沼气的产生速率与剩余底物的浓度成正比,但其他模型,如改进的Gompertz和Logistic模型,纳入了滞后期,这是厌氧消化过程的一个关键特征。本研究旨在确定中温条件下水杨酸与水杨酸共消化的最佳比例,并应用动力学模型描述其产气过程。在32℃的中温条件下,分别以0、10、20、30%的RSW比例分批共消化白藜芦醇。在共消化50 d时,以30% RSW比例共消化WH使沼气产量从19.15提高到40.85 CH4 ml/(gVS),提高了113%。日产气量稳定,产气量最大。采用一级动力学模型、修正的Gompertz模型和Logistic模型拟合生物甲烷化数据。改进的Gompertz模型最能描述以30%的RSW比例共消化WH的产气量,其产气量Mo为43.2 ml (gVS)-1d-1;最大沼气产率Rm为1.50 ml (gVS)-1d-1;延迟时间λ为3.89 d。
Modeling anaerobic co-digestion of water hyacinth with ruminal slaughterhouse waste for first order, modified gompertz and logistic kinetic models
Water hyacinth (Eichhornia crassipes), an invasive aquatic weed with large biomass production is of socio-economic and environmental concern in fresh water bodies such as the Lake Victoria in East Africa. Efforts towards its control and removal can be complemented by biogas production for use as energy source. The co-digestion of water hyacinth (WH) with ruminal slaughterhouse waste (RSW) has the potential to improve biogas production from WH through collation of processes parameters such as the C/N and C/P ratios, potassium concentration and buffering capacity. Knowledge of optimum proportion of the RSW as the minor substrate is of both process and operational importance. Moreover, efficient operation of the process requires an understanding of the relationship between the biogas production and the process parameters. Kinetic models can be useful tools for describing the biogas production process in batch reactors. While the first order kinetics models assume that the rate of biogas production is proportional to the concentration of the remaining substrates, other models such as the modified Gompertz and the Logistic models incorporate the lag phase, a key feature of the anaerobic digestion process. This study aimed to establish the optimum proportion of RSW in co-digestion with WH under mesophilic conditions, and apply kinetics models to describe the biogas production. The study conducted batch co-digestion of WH with 0, 10, 20 and 30% RSW proportions at mesophilic temperature of 32ºC. Co-digestion of WH with 30% RSW proportion improved biogas yield by 113% from 19.15 to 40.85 CH4 ml/(gVS) at 50 days of co-digestion. It also exhibited the most stable daily biogas production and the largest biogas yield. The biomethanation data were fitted with the first order kinetics, modified Gompertz and the Logistic models. Biogas production for co-digestion of WH with 30% RSW proportion was best described by the modified Gompertz model with a biogas yield potential, Mo, of 43.2 ml (gVS)-1d-1; maximum biogas production rate, Rm, of 1.50 ml (gVS)-1d-1; and duration of lag, λ, of 3.89 d.