木质纤维素同步发酵、糖化和渗透蒸发或真空蒸发生产丁醇。

Butanol production from lignocellulose by simultaneous fermentation, saccharification, and pervaporation or vacuum evaporation.

机构信息

Perception and Intelligent Control, Department of Electrical and Electronics Engineering and Computer Science, Universidad Nacional de Colombia - Sede Manizales, Cra. 27 No. 64-60, Manizales, Colombia.

出版信息

Bioresour Technol. 2016 Oct;218:174-82. doi: 10.1016/j.biortech.2016.06.091. Epub 2016 Jun 25.

DOI:10.1016/j.biortech.2016.06.091

PMID:27367813

Abstract

Techno-economic study of acetone, butanol and ethanol (ABE) fermentation from lignocellulose was performed. Simultaneous saccharification, fermentation and vacuum evaporation (SFS-V) or pervaporation (SFS-P) were proposed. A kinetic model of metabolic pathways for ABE fermentation with the effect of phenolics and furans in the growth was proposed based on published laboratory results. The processes were optimized in Matlab®. The end ABE purification was carried out by heat-integrated distillation. The objective function of the minimization was the total annualized cost (TAC). Fuel consumption of SFS-P using poly[1-(trimethylsilyl)-1-propyne] membrane was between 13.8 and 19.6% lower than SFS-V. Recovery of furans and phenolics for the hybrid reactors was difficult for its high boiling point. TAC of SFS-P was increased 1.9 times with supplementation of phenolics and furans to 3g/l each one for its high toxicity. Therefore, an additional detoxification method or an efficient pretreatment process will be necessary.

摘要

对木质纤维素生产丙酮、丁醇和乙醇（ABE）的工艺经济性进行了研究。提出了同步糖化发酵-真空蒸发（SFS-V）或渗透蒸发（SFS-P）。根据已发表的实验室结果，提出了一种考虑木质素降解产物中酚类和呋喃类化合物对生长影响的 ABE 发酵代谢途径动力学模型。利用 Matlab®对过程进行了优化。通过热集成精馏对最终 ABE 进行纯化。最小化的目标函数是总年度化成本（TAC）。使用聚[1-（三甲基甲硅烷基）-1-丙炔]膜的 SFS-P 的燃料消耗比 SFS-V 低 13.8%至 19.6%。由于沸点较高，混合式反应器中糠醛和酚类物质的回收较为困难。由于其高毒性，当补充各 3g/L 的酚类和糠醛时，SFS-P 的 TAC 增加了 1.9 倍，因此需要额外的解毒方法或有效的预处理工艺。

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木质纤维素同步发酵、糖化和渗透蒸发或真空蒸发生产丁醇。

Butanol production from lignocellulose by simultaneous fermentation, saccharification, and pervaporation or vacuum evaporation.

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