通过直接热化学液化生产的生物原油经加氢处理生产的生物喷气燃料的潜在产量和减排量。

Potential yields and emission reductions of biojet fuels produced via hydrotreatment of biocrudes produced through direct thermochemical liquefaction.

作者信息

van Dyk Susan, Su Jianping, Ebadian Mahmood, O'Connor Don, Lakeman Michael, Saddler Jack John

机构信息

1Forest Products Biotechnology/Bioenergy Group, The University of British Columbia, Vancouver, BC V6T 1Z4 Canada.

2IEA Bioenergy, Task 39, Paris, France.

出版信息

Biotechnol Biofuels. 2019 Dec 5;12:281. doi: 10.1186/s13068-019-1625-2. eCollection 2019.

DOI:10.1186/s13068-019-1625-2

PMID:31827609

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6894131/

Abstract

BACKGROUND

The hydrotreatment of oleochemical/lipid feedstocks is currently the only technology that provides significant volumes (millions of litres per year) of "conventional" biojet/sustainable aviation fuels (SAF). However, if biojet fuels are to be produced in sustainably sourced volumes (billions of litres per year) at a price comparable with fossil jet fuel, biomass-derived "advanced" biojet fuels will be needed. Three direct thermochemical liquefaction technologies, fast pyrolysis, catalytic fast pyrolysis and hydrothermal liquefaction were assessed for their potential to produce "biocrudes" which were subsequently upgraded to drop-in biofuels by either dedicated hydrotreatment or co-processed hydrotreatment.

RESULTS

A significant biojet fraction (between 20.8 and 36.6% of total upgraded fuel volume) was produced by all of the processes. When the fractions were assessed against general ASTM D7566 specifications they showed significant compliance, despite a lack of optimization in any of the process steps. When the life cycle analysis GHGenius model was used to assess the carbon intensity of the various products, significant emission reductions (up to 74%) could be achieved.

CONCLUSIONS

It was apparent that the production of biojet fuels based on direct thermochemical liquefaction of biocrudes, followed by hydrotreating, has considerable potential.

摘要

背景

目前，对油脂化学原料/脂质原料进行加氢处理是唯一一种能够大量生产（每年数百万升）“传统”生物喷气燃料/可持续航空燃料（SAF）的技术。然而，如果要以与化石喷气燃料相当的价格可持续地生产大量（每年数十亿升）生物喷气燃料，就需要生物质衍生的“先进”生物喷气燃料。对三种直接热化学液化技术，即快速热解、催化快速热解和水热液化进行了评估，以确定它们生产“生物原油”的潜力，随后通过专门的加氢处理或共处理加氢处理将生物原油升级为可直接替代的生物燃料。

结果

所有工艺均产生了显著的生物喷气燃料馏分（占总升级燃料体积的20.8%至36.6%）。当根据一般的ASTM D7566规格对这些馏分进行评估时，尽管任何工艺步骤都缺乏优化，但它们显示出显著的合规性。当使用生命周期分析GHGenius模型评估各种产品的碳强度时，可以实现显著的减排（高达74%）。

结论

显然，基于生物原油直接热化学液化然后进行加氢处理来生产生物喷气燃料具有相当大的潜力。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3275/6894131/b5d201ba5a53/13068_2019_1625_Fig1_HTML.jpg

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通过直接热化学液化生产的生物原油经加氢处理生产的生物喷气燃料的潜在产量和减排量。

Potential yields and emission reductions of biojet fuels produced via hydrotreatment of biocrudes produced through direct thermochemical liquefaction.

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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