Abstract
Advancements in drilling and production technologies have made exploiting resources, which for long time were labeled unproducible such as shales, as economically feasible. In particular, lateral drilling coupled with hydraulic fracturing has created means for hydrocarbons to be transported from the shale matrix through the stimulated network of microcracks, natural fractures, and hydraulic fractures to the wellbore. Because of the degree of confinement, the ultimate recovery is just a small fraction of the total hydrocarbons in place. Our aim was to investigate how augmented pressure gradient through hydraulic fracturing when coupled with another derive mechanism such as heating can improve the overall recovery for more sustainable exploitation of unconventional resources. Knowledge on how hydrocarbons are stored and transported within the shale matrix is uncertain. Shale matrix, which consists of organic and inorganic constituents, have pore sizes of few nanometers, a degree of confinement at which our typical reservoir engineering models break down. These intricacies hinder any thorough investigations of hydrocarbon production from shale matrix under the influence of pressure and thermal gradients. Kerogen, which represents the solid part of the organic materials in shales, serves as form of nanoporous media, where hydrocarbons are stored and then expelled after shale stimulation procedure. In this work, a computational representation of a kerogen–hydrocarbon system was replicated to study the depletion process under coupled mechanisms of pressure and temperature. The extent of production enhancement because of increasing temperature was shown. Moreover, heating requirements to achieve the enhancement at reservoir scale was also presented to assess the sustainability of the proposed method.
Highlights
Thermal enhanced recovery of conventional resources through steam injection, electrical heating, and in situ combustions have shown significant improvement on oil recovery
In unconventional resources of shale gas and oil, a large amount of hydrocarbons is stored in the organic constituents of the shale matrix known as kerogen [1]
Unconventional resources are produced under the influence of augmented pressure gradient through hydraulic fracturing under isothermal conditions
Summary
Thermal enhanced recovery of conventional resources through steam injection, electrical heating, and in situ combustions have shown significant improvement on oil recovery. In unconventional resources of shale gas and oil, a large amount of hydrocarbons is stored in the organic constituents of the shale matrix known as kerogen [1]. The modeling approach usually incorporates mechanisms such as adsorption, slip flow, and molecular and surface diffusions. Unconventional resources are produced under the influence of augmented pressure gradient through hydraulic fracturing under isothermal conditions (i.e., reservoir temperature being constant throughout production time). Increasing the temperature through means of adding heat to the reservoir may alter some of the aforementioned transport and storage mechanisms for enhanced production. Our aim was to investigate how coupling pressure depletion with heating can impact hydrocarbon recovery from organic materials of shales through a molecular computational approach. A reservoir scale design of hydraulically fractured reservoir assisted with heating was investigated for the power requirements and heat propagation
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
