An integrated model for asphaltene deposition in wellbores/pipelines above bubble pressures

Asphaltene has been recognized as the cholesterol of petroleum for decades due to its precipitation and deposition in oil production, transportation and processing facilities, causing tremendous losses to the oil industry each year. This work presents a numerical model to predict asphaltene depositi...

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Bibliographic Details
Published in:Journal of petroleum science & engineering 2018-10, Vol.169, p.353-373
Main Authors: Guan, Q., Goharzadeh, A., Chai, J.C., Vargas, F.M., Biswal, S.L., Chapman, W.G., Zhang, M., Yap, Y.F.
Format: Article
Language:English
Subjects:
Asphaltene deposition
Evolving deposit layer
Integrated transport and thermodynamic models
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Summary:Asphaltene has been recognized as the cholesterol of petroleum for decades due to its precipitation and deposition in oil production, transportation and processing facilities, causing tremendous losses to the oil industry each year. This work presents a numerical model to predict asphaltene deposition in wellbores/pipelines. A Thermodynamic Module is developed to model asphaltene precipitation, based on the sequential stability-testing-and-phase-split-calculation method using Peng-Robinson equation of state with Peneloux volume correction. A Transport Module is developed to model fluid transport, asphaltene particle transport and asphaltene deposition, according to basic conservation laws. Using a thermodynamic properties look-up table, these two modules are linked to each other to account for the effects of a finite deposit layer thickness on the coupled flow fields and deposition process. In this article, verification and validation of the Thermodynamic Module are first carried out. Then, the integrated model is utilized to study asphaltene deposition problems in an actual oilfield where the asphaltene deposit layer profile is reasonably accurately predicted. This case shows that the presented model has great potential as a predicting tool to assist reservoir engineers in assessing asphaltene deposition risks in wellbores/pipelines. •a model for asphaltene deposition with precipitation, fluid transport, particle transport and deposition.•a numerical modeling framework coupling the thermodynamic and transport modules.•account for effect of finite deposit layer thickness on flow and eventually the deposition process itself.•demonstrated for oil field asphaltene deposition problems with different operating conditions.
ISSN:0920-4105
1873-4715
DOI:10.1016/j.petrol.2018.05.042