Abstract
The distribution of proppant injected in hydraulic fractures significantly affects the fracture conductivity and well performance. The proppant transport in thin fracturing fluid used during hydraulic fracturing in the unconventional reservoirs is considerably different from fracturing fluids in the conventional reservoir due to the very low viscosity and quick deposition of the proppants. This paper presents the development of a threedimensional Computational Fluid Dynamics (CFD) modelling technique for the prediction of proppant-fluid multiphase flow in hydraulic fractures. The proposed model also simulates the fluid leak-off behaviour from the fracture wall. The Euler-Granular and CFD-Discrete Element Method (CFD-DEM) multiphase modelling approach has been applied, and the equations defining the fluid-proppant and inter-proppant interaction have been solved using the finite volume technique. The proppant transport in hydraulic fractures has been studied comprehensively, and the computational modelling results of proppant distribution and other flow properties are in good agreement with the published experimental study. The parametric study is performed to investigate the effect of variation in proppant size, fluid viscosity and fracture width on the proppant transport. Smaller proppants can be injected early, followed by larger proppants to maintain high propping efficiency. This study has enhanced the understanding of the complex flow phenomenon between proppant and fracturing fluid and can play a vital role in hydraulic fracturing design.
Highlights
In the last decade, the advancements in horizontal drilling and multistage hydraulic fracturing have resulted in considerable progress in the hydrocarbon production [Warpinski, Mayerhofer, Vincent et al (2009)]
The key objective in the present study is to provide a detailed understanding of the proppant transport considering the effect of fluid leak-off from the fracture wall in a planar fracture in the unconventional reservoir
A user-defined function was defined in order to mimic and model the fluid leakoff rate in the porous reservoir through the hydraulic fracture
Summary
The advancements in horizontal drilling and multistage hydraulic fracturing have resulted in considerable progress in the hydrocarbon production [Warpinski, Mayerhofer, Vincent et al (2009)] Both these techniques are closely related to geomechanics, i.e., in order to create a multi transverse hydraulic fracture, wells are drilled horizontally in the direction of minimum horizontal in-situ stress. Due to the very low viscosity of slick water and negligible chemical additives, the tendency of suspending the proppant particles dramatically decreases [Sahai, Miskimins and Olson (2014)]. This results in early deposition of the proppants compare with the fracturing fluids in conventional reservoirs [Alotaibi and Miskimins (2015)]. The hydraulic fracturing in an unconventional reservoir is considered successful when the long multiple hydraulic fractures are created with uniform proppant distribution resulting in the flow of hydrocarbon fluids economically [Gu and Mohanty (2014)]
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