Ferran de Miguel Mercader scite author profile

Hydrodeoxygenation (HDO) of pyrolysis oil fractions was studied to better understand the HDO of whole pyrolysis oil and to assess the possibility to use individual upgrading routes for these fractions. By mixing pyrolysis oil and water in a 2 : 1 weight ratio, two fractions were obtained: an oil fraction (OFWA) containing 32 wt% of the organics from the whole oil and an aqueous fraction water addition (AFWA) with the remaining organics. These fractions (and also the whole pyrolysis oil as the reference) were treated under HDO conditions at different temperatures (220, 270 and 310 C), a constant total pressure of 190 bar, and using 5 wt% Ru/C catalyst. An oil product phase was obtained from all the feedstocks; even from AFWA, 29 wt% oil yield was obtained. Quality parameters (such as coking tendency and H/C) for the resulting HDO oils differed considerably, with the quality of the oil from AFWA being the highest. These HDO oils were evaluated by co-processing with an excess of fossil feeds in catalytic cracking and hydrodesulfurisation (HDS) lab-scale units. All co-processing experiments were successfully conducted without operational problems. Despite the quality differences of the (pure) HDO oils, the product yields upon catalytic cracking of their blends with Long Residue were similar. During co-processing of HDO oils and straight run gas oil in a HDS unit, competition between HDS and HDO reactions was observed without permanent catalyst deactivation. The resulting molecular weight distribution of the co-processed HDO/fossil oil was similar to when hydrotreating only fossil oil and independent of the origin of the HDO oil.

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Competition between hydrotreating and polymerization reactions during pyrolysis oil hydrodeoxygenation

Mercader

Koehorst

Heeres³

et al. 2011

AIChE Journal

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Insights into Preventing Fluidized Bed Material Agglomeration in Fast Pyrolysis of Acid-Leached Pine Wood

et al. 2019

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Acid leaching of lignocellulosic biomass prior to fast pyrolysis can increase the bio-oil yield and improve bio-oil quality. However, fast pyrolysis of acid-leached biomass in fluidized bed reactors can lead to bed material agglomeration. A series of experiments were conducted to investigate how pyrolysis conditions and torrefaction pretreatment affected fast pyrolysis of acid-leached pine wood to gain insights into understanding and preventing this issue. Melting of the acid-leached wood during fast pyrolysis resulted in the formation of bed material agglomerates, which eventually caused defluidization of the reactor. Three approaches to preventing this issue were investigated in this study. Lowering the pyrolysis temperature to 360 °C limited the conversion of the lignin and prevented bed agglomeration. Using a high sand feeding rate to continually refresh the bed material prevented melted biomass material from accumulating and causing agglomeration. Torrefaction pretreatment of the acid-leached wood resulted in structural changes that altered the pyrolysis behavior of the lignin and also prevented bed agglomeration. Each of these approaches had a different effect on the yield of the bio-oil product but had a minimal impact on its quality.

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Pyrolysis oil upgrading by high pressure thermal treatment

Mercader

Groeneveld

Kersten

et al. 2010

Fuel

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