中试搅拌槽厌氧池中高固相牛粪厌氧消化的简化模型

IF 1.2 4区 农林科学 Q3 AGRICULTURAL ENGINEERING Journal of the ASABE Pub Date : 2023-01-01 DOI:10.13031/ja.15203
I. D. Kariyama, Weixiang Li, Shaoqi Yu, Long Chen, R. Qi, Hao Zhang, Xiaxia Li, Xin Deng, Jiansen Lin, Binxin Wu
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引用次数: 0

摘要

HSAD是一种具有成本效益的高固体肥料管理方法。低接种比批量消化HSAD是不合适的。每天混合一次就足以维持稳定的消化过程。采用适当的生物降解因子的化学计量学方法对其进行了较好的预测。简化的生物动力学可以预测稳态条件下的甲烷产量。摘要厌氧消化(AD)被认为是管理奶牛粪便最有效的方法之一。为了有效和经济地处理商业奶牛场产生的大量粪便,应鼓励高固体厌氧消化(HSAD)。本文在一个有效容积为1.63 m3的中试搅拌沼气池中,在中温条件下,对高挥发性固体(VS)含量的乳粪肥进行了间歇式和半连续式厌氧消化实验。饲养过程中进行3个间歇混合处理(50、100和150 rpm),每天混合1次,持续混合时间为5分钟,其中包括一个非混合实验,在30天的水力滞留时间下运行。目的是确定提高HSAD效率和经济性的最佳混合强度,并应用简化模型来模拟消化过程。改进了简化的动力学模型,以准确预测甲烷的生长、产量和生产速率。修正的Gompertz生长模型较好地预测了间歇式实验中甲烷的生长。一级动力学模型预测的生物降解系数、比甲烷产率和比甲烷产率与批量实验结果一致。改进了化学计量学方法和Karim模型,准确模拟了混合强度对甲烷产率和比产率的影响。成功地建立了三个线性方程来预测甲烷产量。优化混合强度和有机载荷率是提高甲烷产量的关键。本研究有助于提高HSAD效率的研究。关键词:牛粪,高固体厌氧消化,甲烷产率,混合强度
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Simplified Modeling of High-Solids Anaerobic Digestion of Dairy Manure in a Pilot-Scale Stirred Tank Anaerobic Digester
Highlights HSAD is a cost-effective approach for managing high-solids manure. Batch digestion of HSAD at a low inoculum ratio is unsuitable. Mixing once a day was enough to maintain a stable digestion process. The stoichiometric method with an appropriate biodegradability factor provided perfect prediction. Simplified biokinetics can predict methane productivity at steady-state conditions. Abstract. Anaerobic digestion (AD) is considered one of the most effective methods of managing dairy manure. To effectively and economically treat the huge volumes of manure produced by commercial dairy farms, high-solids anaerobic digestion (HSAD) is to be encouraged. In this manuscript, batch and semi-continuous anaerobic digestion experiments of dairy manure with a high volatile solid (VS) content were conducted in a pilot-scale stirred digester with an effective volume of 1.63 m3, operated under mesophilic temperature conditions. Three intermittent mixing treatments (50, 100, and 150 rpm) were mixed once a day during feeding with a constant mixing duration of 5 minutes, including a non-mixed experiment, operating at a 30-day hydraulic retention time. The objectives were to determine an optimum mixing intensity to enhance HSAD efficiency and economy and to apply simplified models to model the digestion process. The simplified kinetic models were modified to accurately predict methane growth, yield, and production rates. The modified Gompertz growth model predicted the methane growth at the batch experiment perfectly. The first-order kinetic model predictions of the biodegradability factor, the specific methane yield, and the specific methane production rate were consistent with the batch experimental results. The stoichiometric method and the Karim model were modified to accurately model the effect of mixing intensity on the methane yield and the specific methane production rate. Three linear equations were successfully developed to predict the methane production rate. Optimized mixing intensity and organic loading rate are critical for high methane production rates. This study contributes to the ongoing research to improve the efficiency of HSAD. Keywords: Dairy manure, High-solids anaerobic digestion, Methane productivity, Mixing intensity.
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