THE COLLOIDAL STRUCTURE OF CRUDE OILS AND SUSPENSIONS OF ASPHALTENES AND RESINS

A better understanding of colloidal macrostructure of the heavy petrol eum products and their complex fractions is of great importance in the context of industrial problems that arise during the crude oil produc tion, refining and transport. Much effort has been devoted to the chem ical structure studies, but there is a need for more precise data rega rding parameters that characterize those complex systems. For instance , the molecular weight of heavy molecules, the composition and size of aggregates formed during the industrial processing and their evolutio n upon the variation of temperature, pressure and with the addition of solvent have not been well known. In this paper we present new result s obtained using several powerful techniques. Scattering methods (usin g X-rays and neutrons) are applied to study both the fractionated prod ucts (asphaltene and resin solutions in more or less good solvents) an d the real systems (Safaniya vacuum residue). The lamellar structural model for asphaltenes and resins is confirmed and the molecular weight of these species determined using a polydisperse size distribution. D iscussion is presented concerning the specificity of X-ray and neutron scattering : X-ray experiments are more sensitive to the aromatic-ric h regions, whereas the neutron scattering data provide information abo ut all the particle volume. Viscosimetry measurements provide informat ion on the molecular shape of asphaltene and confirm the disk-like mod el. Critical micellar concentration has been obtained using Vapour Pre ssure Osmometry (VPO) for asphaltene suspensions in toluene and in pyr idine. The resin molecules are smaller than asphaltenes, and appear to be a good solvent for asphaltenes. One of the major conclusions of th is work is the wide-spread presence of density heterogeneities in dilu ted solutions of asphaltenes and resins as well as in the pure product (Safaniya vacuum residue). This was deduced from the scattering exper iments and cryo-scanning electron microscopy data. The heating effects were studied: a temperature increase leads to the decrease of molecul ar weight, but heterogeneities remain present. The structure of vacuum residue exhibits large density fluctuations which are thermally stabl e. These dense regions remain connected into a network up to 393 degre es K and determine the yield value of the rheological behaviour.