Geomechanical modeling of hydraulic fractures interacting with natural fractures — Validation with microseismic and tracer data from the Marcellus and Eagle Ford

Aimène, Yamina; Ouenes, Ahmed

doi:10.1190/int-2014-0274.1

Cited by 46 publications

(17 citation statements)

References 38 publications

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“…The concept of J integral has been used in many other industries that deal with fracture propagation, but to the best of our knowledge, it has never been quantitatively applied in the oil and gas industry prior to the introduction of the MPM geomechanical workflow . Because its introduction in modeling the interaction between HF and NFs in hydraulic fracturing problems, the J integral was found to be very useful in quantifying HF stage performance, and in some cases it shows interesting correlations with production logs Aimene and Ouenes, 2015;Yang et al, 2015). Because there are 32 stimulation stages modeled in this Wolfcamp well, we estimate 32 J integral curves (Figure 3, item 6).…”

Section: Methodsmentioning

confidence: 96%

“…This geomechanical modeling requires sophisticated computational tools that can account for a realistic distribution of the NFs. A new geomechanical workflow was recently introduced to the oil and gas industry Ouenes et al, 2014;Aimene and Ouenes, 2015) to quantify the impact of NFs on shale stimulations. The new workflow was validated in multiple unpublished projects and published case studies from the Marcellus (Aimene and Nairn, 2014), Eagle Ford Umholtz and Ouenes, 2015), and Montney formations ; the Longmaxi Formation in China (Yang et al, 2015); and the Fayetteville Shale (McKetta et al, 2016).…”

Section: Methodsmentioning

confidence: 99%

“…This geomechanical workflow includes new elements that try to solve many problems that previously hindered the industry-wide application of geomechanics to shale well stimulation and completion optimization. A major feature of this new workflow is the combined use of the material point method (MPM) computational tool to model the interaction between HFs and NFs Aimene and Ouenes, 2015) and the continuous fracture modeling (CFM) approach Jenkins et al, 2009) to model the distribution of the NFs. The new geomechanical workflow is also fast because it only takes a few hours to complete a well-scale simulation and it can easily be incorporated in current hydraulic fracturing design processes.…”

Section: Methodsmentioning

confidence: 99%

“…The workflow uses geophysics and geology to quantify the distribution of NFs in a realistic manner. These data are used as input into FracPredictor™, a particle-based geomechanical computation tool (Aimene and Nairn, 2014; Aimene and Ouenes, 2015). This new 3G workflow provides multiple outputs including horizontal differential stress Aimene and Ouenes, 2015), local maximum horizontal stress directions and the related origins of where stress rotations occur, , and strain resulting from the stimulation process and its correlation to microseismicity Ouenes et al, 2014Ouenes et al, , 2015Aimene and Ouenes, 2015).…”

Section: Background and Previous Studies Modeling The Interaction Betmentioning

confidence: 99%

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Using geomechanical modeling to quantify the impact of natural fractures on well performance and microseismicity: Application to the Wolfcamp, Permian Basin, Reagan County, Texas

Ouenes¹,

Umholtz²,

Aimène

2016

Interpretation

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We have evaluated workflows to quantify the mechanical impact of natural fractures (NFs) on the production performance of hydraulically stimulated stages in shale wells. Variations in fracture orientation and density can enhance or degrade the transport and effectiveness of fracturing fluids. Specifically, we studied the effect of a complex fault splay system on a horizontal Wolfcamp B reservoir well. A general workflow that combines geophysics, geology, and geomechanics (3G) was evaluated and applied to the well. The benefits of the 3G workflow are threefold. First, the quantitative impact of the NFs on the regional stress is provided through the differential horizontal stress variation, which impacts fracturing complexity. Then, the reservoir strain map, validated with microseismic data, gives insights into the stimulated drainage pathways. Finally, the ability of the J integral to predict poor hydraulic fracturing stages as a function of fracture density along the wellbore or as a function of the energy required to propagate a fracture. Building on the validated 3G workflow, a well placement workflow that takes into account the quantitative impact of NFs on well performance was developed on the sample Wolfcamp well. By comparing the J integral of the same completion stage in simulations with and without NFs, stages with similar J integral values in both simulations were identified as those not being affected by the NF network. This allows the workflow to provide the optimal position of a well in the presence of NFs associated with a complex fault system that may produce undesirable water. The result is a validated 3G workflow that provides a geomechanical explanation for an empirical relationship showing that high oil production is achieved within a "Goldilocks" range of natural fracturing. IntroductionThe importance of natural fractures (NFs) in shale reservoirs, their impact on a successful stimulation, and the resulting well performance is reviewed by Gale et al. (2014) andLi (2014). The 71 pages that make up the two review papers include 14 pages of references that discuss NFs in shale reservoirs. A petroleum or completion engineer reading the 71 pages will wonder how to quantify the impact of the NFs on the stimulated shale well's performance.Geologists and geophysicists (G&G) may not adequately relate the role of NFs in shale reservoirs to the bottom line of the completion and petroleum engineers. To enhance communications between engineering and G&G staff, NF density and other key geologic factors including total organic carbon, brittleness, and porosity are quantitatively combined to form a new reservoir property called shale capacity (Ouenes, 2014;Newgord et al., 2015), which demonstrates the value of geoscience in predicting the engineer's bottom

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Section: Methodsmentioning

confidence: 96%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Background and Previous Studies Modeling The Interaction Betmentioning

confidence: 99%

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Using geomechanical modeling to quantify the impact of natural fractures on well performance and microseismicity: Application to the Wolfcamp, Permian Basin, Reagan County, Texas

Ouenes¹,

Umholtz²,

Aimène

2016

Interpretation

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“…Aimene and Nairn [39] and Aimene and Ouenes [40] introduced the Material Point Method (MPM) to facilitate the representation of the natural fractures in a multi-scale continuum problem. MPM combines Lagrangian and Eulerian descriptions of the material and in doing so overcomes the inherent drawbacks of methods relying on using only one perspective.…”

Section: Discrete Fracture Network Models and Limitationsmentioning

confidence: 99%

Shale Reservoir Drainage Visualized for a Wolfcamp Well (Midland Basin, West Texas, USA)

Weijermars¹,

Harmelen²

2018

Energies

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Closed-form solution-methods were applied to visualize the flow near hydraulic fractures at high resolution. The results reveal that most fluid moves into the tips of the fractures. Stranded oil may occur between the fractures in stagnant flow zones (dead zones), which remain outside the drainage reach of the hydraulic main fractures, over the economic life of the typical well (30-40 years). Highly conductive micro-cracks would further improve recovery factors. The visualization of flow near hypothetical micro-cracks normal to the main fractures in a Wolfcamp well shows such micro-cracks support the recovery of hydrocarbons from deeper in the matrix, but still leave matrix portions un-drained with the concurrent fracture spacing of 60 ft (~18 m). Our study also suggests that the traditional way of studying reservoir depletion by mainly looking at pressure plots should, for hydraulically fractured shale reservoirs, be complemented with high resolution plots of the drainage pattern based on time integration of the velocity field.

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Evolution of Stress Transfer Mechanisms During Mechanical Interaction Between Hydraulic Fractures and Natural Fractures

Jha

2019

Hydraulic Fracturing and Well Stimulation

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Geomechanical modeling of hydraulic fractures interacting with natural fractures — Validation with microseismic and tracer data from the Marcellus and Eagle Ford

Cited by 46 publications

References 38 publications

Using geomechanical modeling to quantify the impact of natural fractures on well performance and microseismicity: Application to the Wolfcamp, Permian Basin, Reagan County, Texas

Using geomechanical modeling to quantify the impact of natural fractures on well performance and microseismicity: Application to the Wolfcamp, Permian Basin, Reagan County, Texas

Shale Reservoir Drainage Visualized for a Wolfcamp Well (Midland Basin, West Texas, USA)

Evolution of Stress Transfer Mechanisms During Mechanical Interaction Between Hydraulic Fractures and Natural Fractures

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