The key to the efficient
development of a tight reservoir is its
accurate evaluation. In this study, the pore throat structure characteristics
of sandstone samples in the study block were analyzed by high-pressure
mercury injection technology. According to the characteristics of
the capillary pressure curve, the sandstone samples in the study block
were divided into three types: the first type has a reservoir permeability
greater than 0.7 mD and a core mercury injection saturation of 96%
with a good reservoir quality; the second type has a reservoir permeability
ranging from 0.4 to 0.7 mD and a core mercury injection saturation
of 80% with a moderate reservoir quality; and the third type has a
reservoir permeability between 0.1 and 0.4 mD and a core mercury injection
saturation of 50% with a poor reservoir quality. Also, high-resolution
synchrotron radiation imaging and scanning electron microscopy were
used to observe the pore throat structure, connectivity, and microscopic
heterogeneity of sandstone samples, showing an increasing level of
pore disconnection, serious microscopic heterogeneity, and poor reservoir
performance as reservoir permeability declines. As mineral composition
tests show, the lithology of the tight sandstone in the target block
is mainly medium-grained and fine-grained feldspar lithic sandstone
and the longitudinal heterogeneity of lithology and mineral components
of tight sandstone is relatively weak at above the centimeter level.
Besides, based on the high-pressure mercury injection test data, fractal
theory is applied to calculate the fractal dimensions of the three
types of reservoirs. The result shows a gradual increase in fractal
dimensions with the decrease of reservoir quality, in which the closer
the fractal dimension is to 3, the more serious the microscopic heterogeneity
is, and the stronger the roughness of the pore surface is. As a result,
the more heterogeneous the tight reservoir gets, the more likely the
injected fluid is to flow along the developed and connected pore regions.
The Chang 8 (C8) reservoir is a transitional oil pool type from a tight oil sandstone to a lithologic trap in the Upper Triassic Yanchang Formation of the Honghe oil field, southwest Ordos Basin, China. Vertical faults play important roles in the formation and distribution of the sweetness. To predict favorable high-yield well areas and guide horizontal well deployment, 3D seismic data are used to analyze these faults’ distribution, formation phase, stress property, and control on the oil accumulation. The results indicate that the X shape of the east–northeast and north–northeast conjugate shear faults were formed during the Indosinian epoch, and the northwest faults were formed during the Yanshan epoch. Meanwhile, the earlier east–northeast faults partially experienced reactivity and rework later but the north–northeast faults ceased since the Indosinian. The strike-slip faults in the area are classified into three categories based on their intensity, density, formation stage, and oil control effectives: types I, II, and III. The type I faults extended in the northwest and east–northeast directions and were cut from the Ordovician up to the top Cretaceous. They are characterized by the maximum extensions aerially and vertically thereby faulting the thickest strata. Type II faults mainly extended in the east–northeast direction and were cut from the Triassic up to the top Cretaceous in small intension. Type III faults mainly extended in the north–northeast direction and were cut from the Ordovician up to the Upper Permian. The faults connect the C8 sandstone reservoir and the Chang 7 source shale by penetrating the interlayered silty mudrock in between them. The low permeable reservoir also requires additional permeability imparted by the type I faults. High-yield horizontal wells are distributed along intensive type I faults. The water-bearing zones or oily water zones are mostly related to no fault or to the type II and III faults.
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