Abstract
Capillary pressure is an important characteristic that indicates the zones of interaction between two-phase fluids or fluid and rock occurring in the subsurface. The analysis of transition zones (TZs) using Goda (Sam) et al.’s empirical capillary pressure from well logs and 3D seismic data in ‘Stephs’ field, Niger Delta, was carried out to remove the effect of mobile water above the oil–water contact in reservoirs in the absence of core data/information. Two reservoirs (RES B and C) were utilized for this study with net thicknesses (NTG) ranging from 194.14 to 209.08 m. Petrophysical parameters computed from well logs indicate that the reservoirs’ effective porosity ranges from 10 to 30% and the permeability ranges from 100 to > 1000 mD, which are important characteristics of good hydrocarbon bearing zone. Checkshot data were used to tie the well to the seismic section. Faults and horizons were mapped on the seismic section. Time structure maps were generated, and a velocity model was used to convert the time structure maps to its depth equivalent. A total of six faults were mapped, three of which are major growth faults (F1, F4 and F5) and cut across the study area. Reservoir properties were modelled using SIS and SGS. The capillary pressure log, curves and models generated were useful in identifying the impact of mobile water in the reservoir as they show the trend of saturating and interacting fluids. The volume of oil estimated from reservoirs B and C without taking TZ into consideration was 273 × 106 and 406 × 106 mmbbls, respectively, and was found to be higher than the volume of oil estimated from the two reservoirs while taking TZ into consideration which was 242 × 106 and 256 × 106 mmbbls, respectively. The results have indicated the presence of mobile water, which have further established that conventionally recoverable hydrocarbon (RHC) is usually overestimated; hence, TZ analysis has to be performed for enhancing RHC for cost-effective extraction and profit maximization.
Highlights
The oil transition zone is the zone occurring between the zone of 100% water saturation (Sw) and the zone of 100% hydrocarbon saturation (Sh) which consists of mobile water above the irreducible water saturation
The effective porosity within the reservoirs ranges from 10 to 30%, and the permeability ranges from 100 to 1000 mD, which is an important characteristic of good hydrocarbon bearing zone
The modelling of these parameters further buttresses this point as it is evident on the models generated
Summary
The oil transition zone is the zone occurring between the zone of 100% water saturation (Sw) and the zone of 100% hydrocarbon saturation (Sh) which consists of mobile water above the irreducible water saturation. Capillary pressure is an important characteristic of rock that helps determine where hydrocarbons and water are located in the subsurface (Wu 2004). Capillary pressure curve is a plot of capillary pressure against water saturation which shows the trend of saturating and interacting fluids. It describes fluids interaction or fluid and matrix interaction with respect to the reservoir architecture. Each capillary pressure curve is specific to a facies, pore size distribution and fluid properties (Larsen et al 2000; Glover 2000; Pascoal 2015). Hydrocarbon/water contacts, rock matrix type and pore throat structure, heights of transition zones within the reservoir can be determined. A universal empirical model by Goda (Sam) et al (2011) for obtaining the reservoir capillary pressure information of a field in the absence of core information was utilized and validated using well logs information from ‘Stephs’ field
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
