The stability of water-in-oil emulsions formed during oil slicks or petroleum production operations is ensured by natural surfactant molecules (principally asphaltenes) that are present in the crude oil. These persistent emulsions may be broken by adding a suitable demulsifier at the proper concentration to attain a so-called optimum formulation at which the stability of the emulsion is minimum. In this report, the concentration of asphaltenes is varied by diluting the crude oil with a solvent such as cyclohexane, toluene, or mixtures of them. The experimental evidence shows that there exists some critical asphaltene concentration at which the interfacial zone seems to be saturated. Beyond this threshold, which is typically around 1000 ppm of asphaltenes, the demulsifier concentration necessary to attain the emulsionʼs quickest breaking is constant. Below it, e.g. when the crude is highly diluted with a solvent, the optimum demulsifier concentration is found to be proportional to the asphaltene concentration. The map of emulsion stability versus asphaltene and demulsifier concentrations exhibits a typical pattern for different demulsifiers and diluents, which contributes to improving the interpretation of the demulsifying action.
Water-in-oil emulsions formed during oil slicks or petroleum production are known to be stabilized by
surfactant molecules that naturally occur in the crude oil, e.g., asphaltenes, which are quite lipophilic in nature.
Demulsifier substances combine with naturally occurring surfactants to attain a so-called optimum formulation
at which the stability of the emulsion is minimum. The attainment of this formulation is related to the
hydrophilicity and concentration of the added demulsifier, and a general phenomenology of the demulsification
process is outlined.
This paper encompasses classic trends as well as recent advances in the understanding of
emulsion inversion phenomena. The generalized formulation issue is first discussed from
hydrophilic−lipophilic balance to the most recent concepts. The so-called standard inversion
line on the formulation−composition map exhibits several branches, referred to as transitional
and catastrophic inversions, that bound normal and abnormal emulsion regions. Dynamic
inversion is also discussed with its hysteresis zones, where both types of emulsions may be
attained, depending upon the system's previous history of the formulation−composition map.
Recent findings are reported concerning the effect of variables with practical relevance (i.e.,
stirring energy, viscosity of phases, surfactant concentration, and partitioning) on the standard
and dynamic inversion patterns. State-of-the-art emulsion inversion modeling is briefly discussed.
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