The characterization
of the pore structure of tight sandstones
is of great importance for the exploration and development of tight
oil reservoirs. However, little attention has been given to the geometrical
features of pores with various scales, which implies that the effect
of pores on the fluid flow and storage capacity is still ambiguous
and presents a significant challenge to the risk assessment of tight
oil reservoirs. This study investigates the pore structure characteristics
of tight sandstones by applying thin section petrography, scanning
electron microscopy, nuclear magnetic resonance, fractal theory, and
geometric analysis. The results indicate that the tight sandstones
have a binary pore system, consisting of small pores and combine pores.
A shuttlecock model expresses the shape of the small pore. The radius
of the small pore is comparable to the throat radius, and the connectivity
of the small pore is poor. A spiny spherical model describes the shape
of the combine pore. The connectivity of the combine pore is good,
and the pore radius is larger than the throat radius. The most significant
contribution to the storage space of the tight sandstones is attributed
to the small pores, while permeability is primarily controlled by
the combine pores. The heterogeneity of the combine pore has a strong
positive correlation with flow capacity, which is associated with
the multiple throats of the combine pores that developed during diagenesis.
Therefore, the sandstones that are dominated by combine pores and
are located near the source rocks represent the most favorable area
for the exploitation and development of tight sandstone reservoirs.
Major shale gas exploration and development fields are located in the Sichuan basin. It requires huge water sources for shale gas fracking, but the well sites are mostly in the hills, which limits the industrialization of shale gas development. CO2 foam fluids can meet the requirements of fracking fluids and relieve water stress. It analyzed the feasibility of CO2 foaming fracturing for shale gas formation fracturing, proposed a design philosophy for CO2 foaming fracturing, and optimized fracturing parameters such as foam mass, proppant concentration, friction, and discharge rate. The flowchart of CO2 foam fracturing was established in, where the fracture morphology and propagation behavior of CO2 foam fracturing were obtained from numerical simulations comparable to the hydraulic fracture generated by conventional hydraulic fracturing. The CO2 foaming fracturing technique can provide a discharge rate of 6.0 m3/min and fluid volume and captures the volume effect of the current stimulated reservoir, which needs to be improved. It can be considered an initial survey of CO2 foam fracturing available in the Sichuan Basin shale formation, which may provide new methods and clues for stimulation.
The physical property of Chang 6 reservoir in Yanchang oilfield is poor, and the heterogeneity is strong. Multistage fracturing of horizontal wells is easy to form only one large horizontal fracture, but it is difficult to control the fracture height and length. The new mining method of “bow horizontal well + multistage horizontal joint” can effectively increase the multistage horizontal joint’s spatial position, which improves the drainage area and stimulation efficiency of oil wells. Due to the reservoir’s low permeability and strong heterogeneity, the single well mode of “bow horizontal well + multistage horizontal fracture” cannot effectively produce Chang 6 reservoir. To improve the production degree of the g 6 reservoir, the fracture model is established using equivalent conductivity and the multigrid method. The pressure response functions of horizontal wells and volume fracturing horizontal wells are established by using the source function, and the relationship between reservoir permeability and starting pressure gradient in the block is calculated. On this basis, the reservoir productivity equation of the block is established, which provides a basis for optimizing the fracturing design parameters of horizontal wells. It is proposed that the flow unit should be considered in the design of fracturing parameters of horizontal fractures, the number of fractures should comprehensively consider whether the fractures can make each flow unit be used, and have large controlled reserves, and the scale of fracturing should comprehensively consider the output and cost. The fracture network model is established by using equivalent conductivity and multi-gridthod, and the volume fracturing design parameters of horizontal wells are optimized, considering the seepage characteristics of the flow unit. The fracturing design parameters of the horizontal section are further defined, which provides a theoretical basis for the efficient development of shallow tight reservoirs.
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