Characterisation of crude oil components, asphaltene aggregation and emulsion stability by means of near infrared spectroscopy and multivariate analysis
Doctoral thesis
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http://hdl.handle.net/11250/229118Utgivelsesdato
2002Metadata
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Sammendrag
Effective separation of water-in-crude oil emulsions is a central challenge for the oil industry on the Norwegian Continental Shelf, especially with the future increase in subsea and even down-hole processing of well-fluids. The mechanisms and properties governing emulsion stability are far from fully understood, but the indigenous surface-active crude oil components are believed to play a major role.
In this work a thorough physico-chemical characterisation of a set of crude oils originating from a variety of production fields has been performed. Crude oil properties responsible for emulsion stability were identified by use of multivariate analysis techniques like partial least squares regression (PLS) and principal component analysis (PCA). Interfacial elasticity along with both asphaltene content and asphaltene aggregation state were found to be main contributors to emulsion stability. Information on a crude oils ability to form elastic crude oilwater interfaces was found to be especially crucial when discussing emulsion stability. However, measured values of interfacial elasticity were highly dependent on asphaltene aggregation state.
Several experimental techniques was utilised, and partly developed, for the crude oil characterisation. A high pressure liquid chromatography (HPLC) scheme was developed for SARA-fractionation of crude oils, and an oscillating pendant drop tensiometer was used for characterisation of interfacial rheological properties. For emulsion stability a cell for determining the stability as a function of applied electric fields was used. In addition, near infrared spectroscopy (NIR) was used throughout the work both for chemical and physical characterisation of crude oils and model systems.
High-pressure NIR was used to study the aggregation of asphaltenes by pressure depletion. A new technique for detection of asphaltene aggregation onset pressures based on NIR combined with PCA was developed. It was also found that asphaltene aggregation is reversible, but highly time-dependent. Finally, the size of asphaltene aggregates in model systems was estimated by fitting NIR spectra to Rayleigh scattering theory.