使用渗透蒸发法在木质纤维素加工后高效脱水和回收离子液体。

Efficient dehydration and recovery of ionic liquid after lignocellulosic processing using pervaporation.

作者信息

Sun Jian, Shi Jian, Murthy Konda N V S N, Campos Dan, Liu Dajiang, Nemser Stuart, Shamshina Julia, Dutta Tanmoy, Berton Paula, Gurau Gabriela, Rogers Robin D, Simmons Blake A, Singh Seema

机构信息

Deconstruction Division, Joint BioEnergy Institute, Emeryville, CA 94608 USA.

Biological and Engineering Sciences Center, Sandia National Laboratories, Livermore, CA 94551 USA.

出版信息

Biotechnol Biofuels. 2017 Jun 15;10:154. doi: 10.1186/s13068-017-0842-9. eCollection 2017.

DOI:10.1186/s13068-017-0842-9

PMID:28638441

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5472906/

Abstract

BACKGROUND

Biomass pretreatment using certain ionic liquids (ILs) is very efficient, generally producing a substrate that is amenable to saccharification with fermentable sugar yields approaching theoretical limits. Although promising, several challenges must be addressed before an IL pretreatment technology can become commercially viable. One of the most significant challenges is the affordable and scalable recovery and recycle of the IL itself. Pervaporation (PV) is a highly selective and scalable membrane separation process for quantitatively recovering volatile solutes or solvents directly from non-volatile solvents that could prove more versatile for IL dehydration.

RESULTS

We evaluated a commercially available PV system for IL dehydration and recycling as part of an integrated IL pretreatment process using 1-ethyl-3-methylimidazolium acetate ([CCIm][OAc]) that has been proven to be very effective as a biomass pretreatment solvent. Separation factors as high as 1500 were observed. We demonstrate that >99.9 wt% [CCIm][OAc] can be recovered from aqueous solution (≤20 wt% IL) and recycled five times. A preliminary technoeconomic analysis validated the promising role of PV in improving overall biorefinery process economics, especially in the case where other IL recovery technologies might lead to significant losses.

CONCLUSIONS

These findings establish the foundation for further development of PV as an effective method of recovering and recycling ILs using a commercially viable process technology.

摘要

背景

使用某些离子液体（ILs）进行生物质预处理非常有效，通常会产生一种适合糖化的底物，可发酵糖产量接近理论极限。尽管前景广阔，但在IL预处理技术实现商业可行性之前，必须解决几个挑战。最重大的挑战之一是IL本身的经济实惠且可扩展的回收和循环利用。渗透汽化（PV）是一种高度选择性且可扩展的膜分离过程，用于直接从非挥发性溶剂中定量回收挥发性溶质或溶剂，这可能被证明对IL脱水更具通用性。

结果

作为使用1-乙基-3-甲基咪唑醋酸盐（[CCIm][OAc]）的集成IL预处理过程的一部分，我们评估了一种用于IL脱水和循环利用的商用PV系统，[CCIm][OAc]已被证明是一种非常有效的生物质预处理溶剂。观察到分离因子高达1500。我们证明可以从水溶液（≤20 wt% IL）中回收>99.9 wt%的[CCIm][OAc]并循环使用五次。初步的技术经济分析验证了PV在改善整体生物炼制过程经济性方面的前景作用，特别是在其他IL回收技术可能导致重大损失的情况下。

结论

这些发现为进一步开发PV奠定了基础，使其成为一种使用商业可行的工艺技术回收和循环利用ILs的有效方法。

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使用渗透蒸发法在木质纤维素加工后高效脱水和回收离子液体。

Efficient dehydration and recovery of ionic liquid after lignocellulosic processing using pervaporation.

作者信息

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSIONS

背景

结果

结论

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