|dc.description.abstract||Inorganic scale may precipitate in oilfield systems, down hole in the reservoir, in the production flow tubing, and in surface facilities, as a consequence of thermodynamic changes that affect the flowing brines. These changes may be induced by temperature or pressure changes, or by mixing of incompatible brines. While much work has been performed to study the effect of thermodynamic changes such as pressure decrease or temperature increase on scale precipitation, it is only recently that a body of work has been developed on the impact that the dynamics of brine mixing in the reservoir has on scale precipitation in situ. Much of this work has been conducted using finite difference simulators, which are handicapped with regard to these calculations in that numerical dispersion effects can be orders of magnitude greater than physical dispersion. The introduction of chemical reaction calculations into streamline simulation models presents a very significant opportunity for improving the accuracy of such calculations. While numerical dispersion effects for immiscible calculations (eg water displacing oil) can be countered by pseudoisation of the relative permeability functions, in finite difference models it is difficult to control numerical dispersion for miscible displacements e.g. seawater (with a Sulphate concentration) displacing formation water (with a Barium concentration), which may lead to scaling in the reservoir (Barium Sulphate precipitation). Streamline simulation reduces the numerical errors for both miscible and immiscible displacement, thus making the scaling calculations much more accurate. The objective of this PhD project was to study the application of a streamline simulator, which has the appropriate chemistry modeling capabilities, to realistic reservoir scenarios. The project consisted of two stages:
1) Study of synthetic systems to identify the impact of brine mixing in simple scenarios (eg single layer and multi-layer quarter five spot patterns)
2) Application of the technique to full field reservoir systems to improve the capability of making scale management decision during the project Front End Engineering and Design (FEED) phase.
The calculations performed demonstrate where, and under what conditions, scale precipitation takes place in situ in the reservoir, and what the resulting impact on the chemical composition of the produced brine will be. This information is key in the planning of the management of oilfield scale.||en_US