Catalytic upgrading evaluation under steam injection conditions with spectroscopy 1H-NMR

Catalytic upgrading evaluation under steam injection conditions with spectroscopy 1H-NMR

Steam injection has mainly been applied due to its physical recovery mechanisms. However, a chemical process could arise and is called aquathermolysis. These reactions could be favored by the addition of a catalyst, which acts on cracking reactions of some heavy compounds. Therefore, an experimental...

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Bibliographic Details
Published in:Petroleum science and technology Vol. 40; no. 13; pp. 1622 - 1639
Main Authors: León, Paola A., Bottía, Hernando, Molina V., Daniel, Martínez Vertel, Jaime José, Muñoz, Samuel F., León, Adan-Yovani
Format: Journal Article
Language:English
Published: Abingdon Taylor & Francis 19-04-2022
Taylor & Francis Ltd
Subjects:
aquathermolysis
Aromaticity
Catalysts
Chains
Chemical reactions
enhanced oil recovery
Evaluation
heavy oil
Iron
Magnetic properties
Microreactors
Molybdenum
Naphtha
NMR
Nuclear magnetic resonance
steam
upgrading
Viscosity
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Summary:Steam injection has mainly been applied due to its physical recovery mechanisms. However, a chemical process could arise and is called aquathermolysis. These reactions could be favored by the addition of a catalyst, which acts on cracking reactions of some heavy compounds. Therefore, an experimental evaluation of catalytic aquathermolysis of heavy oil was carried out in a microreactor batch. The experiments were performed at three different reaction times (24 h-62 h) and temperatures between 240 °C-300 °C. Iron naphthenate, molybdenum naphthenate, and nickel naphthenate were the catalysts used. Oil upgrading was measured by changes in the physical property, and the identification of reactive molecules by nuclear magnetic resonance 1H-NMR technique to obtain average molecular parameters. The average number of carbons in alkyl chains was determined to simplify the samples' compositional analysis, as well as the number of substituted rings and the aromaticity factor. The experimental results showed an increase in the viscosity reduction efficiency as Mo < Ni < Fe. In addition, the catalysts increased the API° gravity and decreased the viscosity by 10° and 79%, respectively. Furthermore, naphtha and kerosene production increased the conversion of the 300 °C + fraction up to 8%. Finally, upgraded oils showed a smaller difference in alkyl chains length.
ISSN:1091-6466
1532-2459
DOI:10.1080/10916466.2022.2025834