Abstract
Pyrolysis is considered the most promising way to convert biomass to fuels. Upgrading biomass pyrolysis oil is essential to produce high quality hydrocarbon fuels. Upgrading technologies have been developed for decades, and this review focuses on the hydrodeoxygenation (HDO). In order to declare the need for upgrading, properties of pyrolysis oil are firstly analyzed, and potential analysis methods including some novel methods are proposed. The high oxygen content of bio-oil leads to its undesirable properties, such as chemical instability and a strong tendency to re-polymerize. Acidity, low heating value, high viscosity and water content are not conductive to making bio-oils useful as fuels. Therefore, fast pyrolysis oils should be refined before producing deoxygenated products. After the analysis of pyrolysis oil, the HDO process is reviewed in detail. The HDO of model compounds including phenolics monomers, dimers, furans, carboxylic acids and carbohydrates is summarized to obtain sufficient information in understanding HDO reaction networks and mechanisms. Meanwhile, investigations of model compounds also make sense for screening and designing HDO catalysts. Then, we review the HDO of actual pyrolysis oil with different methods including two-stage treatment, co-feeding solvents and in-situ hydrogenation. The relative merits of each method are also expounded. Finally, HDO catalysts are reviewed in order of time. After the summarization of petroleum derived sulfured catalysts and noble metal catalysts, transitional metal carbide, nitride and phosphide materials are summarized as the new trend for their low cost and high stability. After major progress is reviewed, main problems are summarized and possible solutions are raised.
Highlights
Rapid economic development remarkably increases the energy demand, especially in transportation fuels
20.7 bar hydrogen pressure, got complete conversion and yielded two main be caused by its intramolecular hydrogen bonds that could hinder the attack of the catalyst
The hydrogenation technology applied for pyrolysis oil has been developed for decades, some problems still exist that clog the development of this technology
Summary
Rapid economic development remarkably increases the energy demand, especially in transportation fuels. Bio-oil generally contains 50–65 wt % organic components, involving acids, aldehydes, ketones, furans, phenolics, guaiacols, syringols and sugars; 15–30 wt % moisture; and 20 wt % colloidal fraction [4]. Oxygens contained in these compounds cause undesirable properties such as low energy density, instability, high viscosity and corrosion. Hydrotreating is an effective way to upgrade bio-oil, which removes oxygen through HDO, generally at 400–773 K and high H2 partial pressure. With the rapid development of catalysts and upgrading technology, we hope this review can provide useful information and inspire ideas in producing high quality bio-oil
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