Suppression of Coke Formation during Bitumen Pyrolysis

Mild pyrolysis (400 °C) of bitumen was investigated to establish ways in which coke formation can be suppressed. Bitumen was diluted to various degrees with solvents that had different hydrogen transfer properties, namely, hydrogen donation, hydrogen shuttling, and poor hydrogen transfer properties....

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Veröffentlicht in:	Energy & fuels 2013-06, Vol.27 (6), p.3061-3070
Hauptverfasser:	Zachariah, Ashley, Wang, Lin, Yang, Shaofeng, Prasad, Vinay, de Klerk, Arno
Format:	Artikel
Sprache:	eng
Schlagworte:	Availability Bitumens Coke Formations Hydrocarbons Liquids Pyrolysis Solvents
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container_title	Energy & fuels
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creator	Zachariah, Ashley Wang, Lin Yang, Shaofeng Prasad, Vinay de Klerk, Arno
description	Mild pyrolysis (400 °C) of bitumen was investigated to establish ways in which coke formation can be suppressed. Bitumen was diluted to various degrees with solvents that had different hydrogen transfer properties, namely, hydrogen donation, hydrogen shuttling, and poor hydrogen transfer properties. Additionally, the concentration of light products generated during bitumen pyrolysis was manipulated by pressure and batch/semibatch operation. Coke formation was suppressed by light material, whether added as a solvent or generated in situ during pyrolysis. As anticipated, hydrogen transfer was important, but coke formation was reduced by 35% at 10% concentration of even a poor hydrogen transfer solvent. Hydrogen availability and the H:C ratio of the reaction mixture were found to be particularly influential in determining whether coke formed. The results showed that light gases produced during pyrolysis were not irreversible reaction products, but continued to participate in the reaction network to moderate the pyrolysis process and suppress coke formation. Applied to industrial operation, evidence was provided to indicate that liquid yield can be increased and coke formation can be suppressed during visbreaking by cofeeding light gases, typically C4 and lighter hydrocarbons.
doi_str_mv	10.1021/ef400314m
format	Article
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subjects	Availability Bitumens Coke Formations Hydrocarbons Liquids Pyrolysis Solvents
title	Suppression of Coke Formation during Bitumen Pyrolysis
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