木质纤维素生物质的化学预处理、厌氧消化和生物甲烷化

作者

  • Erick Auma Omondi Department of Civil and Construction Engineering, University of Nairobi
  • Arnold Aluda Kegode Department of Civil and Structural Engineering, Moi University
Article ID: 90
69 Views, 30 PDF Downloads

DOI:

https://doi.org/10.18686/cncest.v1i2.90

关键词:

预处理;木质纤维素生物质;化学预处理;厌氧消化

摘要

由于当前气候变化的影响,我们需要推广和使用可再生能源以避免化石燃料带来的日益严重的环境和健康问题。木质纤维素生物质(lignocellulosic biomass, LCB)来源丰富和原料特性多,是一种前景广阔的可再生可持续能源。厌氧消化(anaerobic digestion, AD)涉及一个生化过程,通过甲烷菌和硫酸盐还原菌等微生物的作用,可将LCB通过水解和生物甲烷化过程转化为沼气。低浓度沼气在水解过程中会释放出各种还原糖,这些还原糖对生产生物乙醇和沼气等生物燃料、有机酸、酚类和醛类至关重要。由此产生的沼气可以补充能源需求,同时实现经济、环境和健康效益。通过适当的预处理,破坏复杂的木质纤维素结构,使纤维素和半纤维素脱离木质素的束缚,从而进行酶糖化和发酵,可以提高低浓生物质转化为生物能源的AD过程。确定AD的最佳预处理技术对于低浓度木质纤维素能源生产过程的成功至关重要。本研究评估了化学预处理在改善LCB消化以生产生物能源方面的应用,该研究回顾了LCB特性、AD过程以及各种化学预处理技术(如酸、碱、有机溶剂、臭氧分解和离子液体)的作用。这项研究的结果使人们了解了不同LCB化学预处理技术的作用方法和优点,同时强调了采取不同策略的主要缺点。

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使用从LCB中提取的离子液体的闭环生物精炼厂。

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2023-11-20

文章引用

Omondi, E. A., & Kegode, A. A. (2023). 木质纤维素生物质的化学预处理、厌氧消化和生物甲烷化. 清洁能源科学与技术, 1(2), 90. https://doi.org/10.18686/cncest.v1i2.90

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