集成真空汽提和吸附用于高效回收（生物基）2-丁醇

Integrated Vacuum Stripping and Adsorption for the Efficient Recovery of (Biobased) 2-Butanol.

作者信息

Pereira Joana P C, Overbeek Wouter, Gudiño-Reyes Noelia, Andrés-García Eduardo, Kapteijn Freek, van der Wielen Luuk A M, Straathof Adrie J J

机构信息

Department of Biotechnology and Catalysis Engineering, Chemical Engineering Department, Delft University of Technology, van der Maasweg 9, 2629 HZ Delft, The Netherlands.

出版信息

Ind Eng Chem Res. 2019 Jan 9;58(1):296-305. doi: 10.1021/acs.iecr.8b03043. Epub 2018 Dec 12.

DOI:10.1021/acs.iecr.8b03043

PMID:30774191

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6369677/

Abstract

Biobased 2-butanol offers high potential as biofuel, but its toxicity toward microbial hosts calls for efficient techniques to alleviate product inhibition in fermentation processes. Aiming at the selective recovery of 2-butanol, the feasibility of a process combining vacuum stripping followed by vapor adsorption has been assessed using mimicked fermentation media. The experimental vacuum stripping of model solutions and corn stover hydrolysate closely aligned with mass transfer model predictions. However, the presence of lignocellulosic impurities affected 2-butanol recovery yields resulting from vapor condensation, which decreased from 96 wt % in model solutions to 40 wt % using hydrolysate. For the selective recovery of 2-butanol from a vapor mixture enriched in water and carbon dioxide, silicalite materials were the most efficient, particularly at low alcohol partial pressures. Integrating vacuum stripping with vapor adsorption using HiSiv3000 proved useful to effectively concentrate 2-butanol above its azeotropic composition (>68 wt %), facilitating further product purification.

摘要

生物基2-丁醇作为生物燃料具有很高的潜力，但其对微生物宿主的毒性要求采用高效技术来减轻发酵过程中的产物抑制。为了选择性回收2-丁醇，使用模拟发酵培养基评估了真空汽提后气相吸附相结合工艺的可行性。模型溶液和玉米秸秆水解液的实验真空汽提与传质模型预测结果密切吻合。然而，木质纤维素杂质的存在影响了由蒸汽冷凝导致的2-丁醇回收率，其从模型溶液中的96 wt%降至使用水解液时的40 wt%。对于从富含水和二氧化碳的蒸汽混合物中选择性回收2-丁醇，硅沸石材料最为有效，尤其是在低醇分压下。事实证明，将真空汽提与使用HiSiv3000的气相吸附相结合有助于有效地将2-丁醇浓缩至其共沸组成以上（>68 wt%），便于进一步的产物纯化。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/791a/6369677/2d7c0401265c/ie-2018-030436_0001.jpg

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集成真空汽提和吸附用于高效回收（生物基）2-丁醇

Integrated Vacuum Stripping and Adsorption for the Efficient Recovery of (Biobased) 2-Butanol.

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