Identification of the leading role of pore structure in determining recovery during low salinity water flooding
- Imperial College London, Department of Earth Science & Engineering, United Kingdom of Great Britain – England, Scotland, Wales (epa114@ic.ac.uk)
Low salinity water flooding is a promising enhanced oil recovery technique that has been observed, in experiments over a range of scales, to increase oil production by up to 14% in some systems. However, there is still no way of reliably predicting which systems will respond favourably to the technique. This shortcoming is partly because of a relative lack of pore scale observations of low salinity water flooding. This has led to a poor understanding of how mechanisms on the scale of micrometres lead to changes in fluid distribution on the scale of centimetres to reservoir scales. In this work, we present the first systematic comparison of the pore scale response to low salinity flooding across multiple sandstone samples. We use X-ray micro-CT scanning to image unsteady state experiments of tertiary low salinity water flooding in Berea, Castlegate, and Bunter sandstone micro-cores. We observe fluid saturations and characterise the wetting state of samples using imagery of fluid-solid fractional wetting and pore occupancy analysis. In the Berea sample, we observed an additional oil recovery of 3 percentage points during low salinity water flooding, with large volumes of oil displaced from small pores but also re-trapping of mobilised oil in large pores. In the Bunter sandstone, we observed 4 percentage point additional recovery with significant displacement of oil from small pores and no significant retrapping of oil in large pores. However, in the Castlegate sample, we observed just 1 percentage point of additional recovery and relatively small volumes of oil mobilisation. We observe a significant wettability alteration towards more water-wet conditions in the Berea and Bunter sandstones, but no significant alteration in the Castlegate sample. We hypothesise that the pore structure, specifically the connectivity of the largest pores in each sample, significantly affected production. This work gives the first pore scale insights into the role of pore geometry and topology on the mobilisation and retrapping of oil during low salinity water flooding.
How to cite: Andrews, E., Jones, A., Muggeridge, A., and Krevor, S.: Identification of the leading role of pore structure in determining recovery during low salinity water flooding , EGU General Assembly 2022, Vienna, Austria, 23–27 May 2022, EGU22-12516, https://doi.org/10.5194/egusphere-egu22-12516, 2022.