Impact of hydrothermal pretreatment at different temperatures on biomethane yield in anaerobic digestion of rice husk

IF 3.5 4区 工程技术 Q3 ENERGY & FUELS
Subodh Kumar, Tinku Casper D’ Silva, Ram Chandra, Anushree Malik, Virendra Kumar Vijay, Ashish Misra
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Abstract

The inadequate conversion of rice husk (RH) into biogas due to its recalcitrant lignocellulosic structure and high silica content necessitates the requirement of pretreatment prior to anaerobic digestion (AD) of RH. This study evaluated the impact of hydrothermal pretreatment on the solubilization of complex lignocellulosic matrix of RH and its subsequent influence on biogas and biomethane yield. The RH was pretreated at six different temperature levels between 200 and 250 °C, at an interval of 10 °C with 20% total solids (TS) loading and retention time of 10 min. The solubilization of RH at different pretreatment temperatures was evaluated by characterizing the liquid and solid fractions of the pretreated RH. The AD of untreated and pretreated RH revealed that the highest biogas and biomethane yields of 355 ± 34 mL/g VSinput and 153 ± 20 mL/g VSinput were observed for RH pretreated at 230 °C, 4.5 and 5.7 times higher than untreated RH. This increase in biogas and biomethane yield for RH230 was confirmed by observing enhanced volatile solid (VS) reduction (38.72%) and biodegradability (39.40%) compared to VS reduction (8.87%) and biodegradability (7.02%) for untreated RH. Further, correlation matrix analysis revealed a strong relation between pretreatment temperature and its severity on the fate of utilizing RH as an AD substrate and obtaining maximal biogas yield. Conclusively, pretreatment up to 230 °C could be recommended to enhance biogas and biomethane yield from RH effectively. Further investigation in pilot-scale reactors is recommended to validate these findings.

Abstract Image

不同温度下的水热预处理对稻壳厌氧消化生物甲烷产量的影响
由于稻壳(RH)具有难降解的木质纤维素结构和较高的二氧化硅含量,因此在将其转化为沼气之前需要对其进行预处理。本研究评估了水热预处理对 RH 复杂木质纤维素基质增溶的影响,以及随后对沼气和生物甲烷产量的影响。在 200 至 250 °C 之间的六个不同温度水平下对 RH 进行预处理,间隔时间为 10 °C,总固体(TS)含量为 20%,停留时间为 10 分钟。通过对预处理后 RH 的液态和固态馏分进行表征,评估了不同预处理温度下 RH 的增溶情况。对未经处理和预处理的 RH 进行的 AD 分析表明,在 230 °C 下预处理的 RH 的沼气和生物甲烷产量最高,分别为 355 ± 34 mL/g VSinput 和 153 ± 20 mL/g VSinput,分别是未经处理 RH 的 4.5 倍和 5.7 倍。与未经处理的 RH 的挥发性固体(VS)减少率(8.87%)和生物降解率(7.02%)相比,RH230 的沼气和生物甲烷产量增加了 38.72%,生物降解率增加了 39.40%。此外,相关矩阵分析表明,预处理温度及其严重程度与将 RH 用作厌氧消化(AD)基质并获得最大沼气产量之间存在密切关系。因此,建议将预处理温度提高到 230 °C,以有效提高 RH 的沼气和生物甲烷产量。建议在中试规模的反应器中开展进一步研究,以验证这些发现。
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来源期刊
Biomass Conversion and Biorefinery
Biomass Conversion and Biorefinery Energy-Renewable Energy, Sustainability and the Environment
CiteScore
7.00
自引率
15.00%
发文量
1358
期刊介绍: Biomass Conversion and Biorefinery presents articles and information on research, development and applications in thermo-chemical conversion; physico-chemical conversion and bio-chemical conversion, including all necessary steps for the provision and preparation of the biomass as well as all possible downstream processing steps for the environmentally sound and economically viable provision of energy and chemical products.
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