Pore-scale Analysis of Residual Oil in Sandstones and its Dependence on Waterflood Salinity, Analysed by Tomography and Microscopy
Abstract
Understanding of the pore scale phenomena in porous
media is a crucial step towards designing a more efficient
enhanced oil recovery techniques in large scale oil reservoirs.
Three dimensional (3D) x-ray micro CT imaging and recent advanced
in 3D image analysis are primary tools that provide unprecedented
level of detailed pore scale information of complex rock
structures. Combining this technology with laboratory EOR
experiments provides valuable insights into the mechanisms behind
the oil recovery process. Low salinity water flooding is a
relatively convenient and efficient tertiary recovery method
which is applicable to the most of the reservoir types. However,
its performance prediction is uncertain because this technique is
not fully understood. Fundamental understanding of underlying
mechanisms of low salinity water flooding, at the pore-scale, by
direct visualization and image analysis is the aim of this
thesis. In this thesis a technique to quantify fluids and rocks
using series of images is developed and applied to 3D images of
mini-plugs that underwent Spontaneous imbibition of high and low
salinity brine or flooded by high or low salinity brine. Further,
oil/rock and oil//brine interfacial areas, oil/brine interfacial
mean curvature and oil saturation configuration in each pore was
determined for each mini-plug. The image analysis and data
interpretation demonstrate that small incremental oil recovery by
low salinity brine corresponded to a slight shift towards
water-wet in clay-rich outcrop sandstones. Further, the influence
of oil composition in the low salinity brine flooding of
reservoir sandstones was investigated. Two crude oil which are
mainly distinctive in their total acid number (TAN) were used in
spontaneous imbibition experiments. All mini-plugs shows strongly
oil wet state after spontaneous imbibition of high and low
salinity brine. The low salinity effect was observed in mini plug
with high TAN oil while the mini-plugs with low TAN oil exhibited
much less tertiary recovery. The analysis of mini-plug with high
TAN oil shows that the salinity-induced wettability shift was
sufficient to displace oil from locations that were already more
water-wet in the state after spontaneous imbibition of high
salinity brine, but was insufficient to cause oil movement from
more oil-wet locations. Pore scale study of core flooded
mini-plug shows that the low salinity brine redistributed oil
blobs by displacing them from smaller to the larger pores and
disconnecting oil. Microscopy studies of mini-plugs after
spontaneous imbibition or core flooding provided further insight
to the low salinity oil recovery mechanism at local minerals or
wettability of pore walls.
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