The Colombian Caribbean region has become an important exploratory target, and recent discoveries confirm its potential as a gas province to overcome the expected-near future gas deficit.
A petrophysical and dynamic characterization workflow was implemented for this challenging deep water play, where the depositional environment is the result of turbidity current processes. The reservoirs consist mostly of thin to very thin sand layers, corresponding mainly to the Ta, Tb, Tc divisions of the Bouma Sequence as observed in the cored intervals. Bouma divisions Td and Te, are related with lowest rock quality and represent the non-reservoir intervals.
The greatest challenge in the characterization of this particular reservoir is the vertical resolution, given the very low thickness of the layers, which become very difficult to detect using standard resolution logs. Thus, tomography images, resultant CT-Scan curves, and their integration with routine and special core analyses, were used to reveal the true nature of this complex reservoir.
The proposed methodology focuses on the integration of Routine and Special Core Analysis for the petrophysical and dynamic characterization of the reservoir, where the pore throat radius distribution from high-pressure mercury injection becomes the basis of the differentiation between what is considered reservoir and what is not. Pore throat radius estimated from High Pressure Mercury Injection (R35) correlates extremely well with textural features and clay content in the rock therefore this parameter (R35) was used to define the different classes for rock typing. The approach taken was to develop a multilinear regression model of R35, as a function of very high-resolution tomography outputs in the cored zones, and then see how it may be extrapolated to the uncored zones using available high resolution logs. Special petrophysical analyses such as NMR Low Field, Porous Plate Capillary Pressure, Electrical Properties and Relative Permeability Curves (Steady State) showed correlation with the defined rock types and in turn allowed for determination of the gas accumulation potential of the area.
Finally, rock and fluid (dry gas) properties have been used to build a Single Well radial model to design initial well tests (DST), and predict production performance from each interval (selective tests). The simulation model represents the lateral and vertical heterogeneity related to the geological environment (Turbidites). The final results have defined the flow and shut-in times during tests to optimize budget.
The study area is located in the Sinú basin of the Colombian Caribbean Sea, near the Northwestern region of Colombia (See Figure 1). In the area, 3 wells have been drilled and the potential for dry gas accumulation (C1 > 95%) was recognized from bottom samples carried out in wells W-1 and W-2. Two of the wells (W-1 and W-2) were cored in the stratigraphic section of interest (a combine 162 meters for both wells) in order to perform a complete petrophysical and mineralogical characterization, and thus evaluate the potential of accumulation and production gas in the area.