FCC coprocessing oil sands heavy gas oil and canola oil. 2. Gasoline hydrocarbon type analysis

FCC coprocessing oil sands heavy gas oil and canola oil. 2. Gasoline hydrocarbon type analysis

This study set out to gain a deeper understanding of a fluid catalytic cracking (FCC) coprocessing approach using canola oil mixed with bitumen-derived heavy gas oil (HGO), for the production of partially-renewable gasoline, with respect to its composition and quality. The FCC coprocessing approach...

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Main Authors: Siauw H. Ng, Nicole E. Heshka, Cecile Lay, Edward Little, Ying Zheng, Qiang Wei, Fuchen Ding
Format: Article
Language:English
Published: KeAi Communications Co., Ltd. 2018-07-01
Series:Green Energy & Environment
Online Access:http://www.sciencedirect.com/science/article/pii/S2468025717301930
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spelling doaj-1b8f8fb7050d4622b043b6f3f5bef69a2021-02-02T01:10:14ZengKeAi Communications Co., Ltd.Green Energy & Environment2468-02572018-07-0133286301FCC coprocessing oil sands heavy gas oil and canola oil. 2. Gasoline hydrocarbon type analysisSiauw H. Ng0Nicole E. Heshka1Cecile Lay2Edward Little3Ying Zheng4Qiang Wei5Fuchen Ding6Natural Resources Canada, CanmetENERGY, 1 Oil Patch Drive, Devon, Alberta, T9G 1A8, Canada; Corresponding authors.Natural Resources Canada, CanmetENERGY, 1 Oil Patch Drive, Devon, Alberta, T9G 1A8, Canada; Corresponding authors.Natural Resources Canada, CanmetENERGY, 1 Oil Patch Drive, Devon, Alberta, T9G 1A8, CanadaNatural Resources Canada, Geological Survey of Canada, 3303–33rd St NW, Calgary, Alberta, T2L 2A7, CanadaDepartment of Chemical Engineering, University of New Brunswick, P.O. Box 4400, Fredericton, New Brunswick, E3B 5A3, CanadaState Key Laboratory of Heavy Oil Processing, China University of Petroleum, Beijing, 102200, ChinaBeijing Institute of Petrochemical Technology, Daxing, Beijing, 102600, ChinaThis study set out to gain a deeper understanding of a fluid catalytic cracking (FCC) coprocessing approach using canola oil mixed with bitumen-derived heavy gas oil (HGO), for the production of partially-renewable gasoline, with respect to its composition and quality. The FCC coprocessing approach may provide an alternative solution to reducing the carbon footprint and to meet government regulatory demands for renewable transportation fuels. In this study, a mixture of 15 v% canola oil in HGO was catalytically cracked with a commercial equilibrium catalyst under typical FCC conditions. Cracking experiments were performed using a bench-scale Advanced Cracking Evaluation (ACE) unit at a fixed weight hourly space velocity of 8 h−1, 490–530 °C, and catalyst/oil ratios of 4–12 g/g. The total liquid product samples were injected via an automatic sampler and a prefractionator (to remove +254 °C) into a gas chromatographic system containing a series of columns, traps, and valves designed to separate each of the hydrocarbon types. The analyzer gives detailed hydrocarbon types of −200 °C gasoline, classified into paraffins, iso-paraffins, olefins, naphthenes, and aromatics by carbon number up to C11 (C10 for aromatics). For a feed cracked at a given temperature, the gasoline aromatics show the highest selectivity in terms of weight percent conversion, followed by saturated iso-paraffins, saturated naphthenes, unsaturated iso-paraffins, unsaturated naphthenes, unsaturated normal paraffins, and saturated normal paraffins. As conversion increases, both aromatics and saturated iso-paraffins increase monotonically at the expense of other components. Hydrocarbon type analysis and octane numbers with variation in feed type, process severity (temperature and catalyst/oil ratio), and conversion are also presented and discussed. Keywords: Oil sands heavy gas oil (HGO), Canola oil, Advanced Cracking Evaluation (ACE) unit, PIONA analysishttp://www.sciencedirect.com/science/article/pii/S2468025717301930
collection DOAJ
language English
format Article
sources DOAJ
author Siauw H. Ng
Nicole E. Heshka
Cecile Lay
Edward Little
Ying Zheng
Qiang Wei
Fuchen Ding
spellingShingle Siauw H. Ng
Nicole E. Heshka
Cecile Lay
Edward Little
Ying Zheng
Qiang Wei
Fuchen Ding
FCC coprocessing oil sands heavy gas oil and canola oil. 2. Gasoline hydrocarbon type analysis
Green Energy & Environment
author_facet Siauw H. Ng
Nicole E. Heshka
Cecile Lay
Edward Little
Ying Zheng
Qiang Wei
Fuchen Ding
author_sort Siauw H. Ng
title FCC coprocessing oil sands heavy gas oil and canola oil. 2. Gasoline hydrocarbon type analysis
title_short FCC coprocessing oil sands heavy gas oil and canola oil. 2. Gasoline hydrocarbon type analysis
title_full FCC coprocessing oil sands heavy gas oil and canola oil. 2. Gasoline hydrocarbon type analysis
title_fullStr FCC coprocessing oil sands heavy gas oil and canola oil. 2. Gasoline hydrocarbon type analysis
title_full_unstemmed FCC coprocessing oil sands heavy gas oil and canola oil. 2. Gasoline hydrocarbon type analysis
title_sort fcc coprocessing oil sands heavy gas oil and canola oil. 2. gasoline hydrocarbon type analysis
publisher KeAi Communications Co., Ltd.
series Green Energy & Environment
issn 2468-0257
publishDate 2018-07-01
description This study set out to gain a deeper understanding of a fluid catalytic cracking (FCC) coprocessing approach using canola oil mixed with bitumen-derived heavy gas oil (HGO), for the production of partially-renewable gasoline, with respect to its composition and quality. The FCC coprocessing approach may provide an alternative solution to reducing the carbon footprint and to meet government regulatory demands for renewable transportation fuels. In this study, a mixture of 15 v% canola oil in HGO was catalytically cracked with a commercial equilibrium catalyst under typical FCC conditions. Cracking experiments were performed using a bench-scale Advanced Cracking Evaluation (ACE) unit at a fixed weight hourly space velocity of 8 h−1, 490–530 °C, and catalyst/oil ratios of 4–12 g/g. The total liquid product samples were injected via an automatic sampler and a prefractionator (to remove +254 °C) into a gas chromatographic system containing a series of columns, traps, and valves designed to separate each of the hydrocarbon types. The analyzer gives detailed hydrocarbon types of −200 °C gasoline, classified into paraffins, iso-paraffins, olefins, naphthenes, and aromatics by carbon number up to C11 (C10 for aromatics). For a feed cracked at a given temperature, the gasoline aromatics show the highest selectivity in terms of weight percent conversion, followed by saturated iso-paraffins, saturated naphthenes, unsaturated iso-paraffins, unsaturated naphthenes, unsaturated normal paraffins, and saturated normal paraffins. As conversion increases, both aromatics and saturated iso-paraffins increase monotonically at the expense of other components. Hydrocarbon type analysis and octane numbers with variation in feed type, process severity (temperature and catalyst/oil ratio), and conversion are also presented and discussed. Keywords: Oil sands heavy gas oil (HGO), Canola oil, Advanced Cracking Evaluation (ACE) unit, PIONA analysis
url http://www.sciencedirect.com/science/article/pii/S2468025717301930
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