Improving Fracture Conductivity by Developing and Optimizing Channels within the Fracture Geometry: CFD Study

Gomaa, Ahmed M.; Hudson, Harold; Nelson, Scott G.; Brannon, Harold

doi:10.2118/178982-ms

Cited by 12 publications

(1 citation statement)

References 52 publications

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“…Malhotra [3] alternated between two viscosity fracturing fluids during the experiment and compared the distribution patterns formed by different viscosity ratios. In order to analyze the influence of factors such as fluid viscosity, injection speed and pulse interval time on the construction effect, Gomaa [4,5] and Li [6] simulated the distribution of proppant clusters in fractures of different sizes under the action of pulse sand addition by CFD model. Wen [7] Based on the experimental results, the calculation model of the relevant parameters was established, and the change law of the conductivity of the gas-liquid two phases under different support patterns was analyzed.…”

Section: Introductionmentioning

confidence: 99%

Effect of pulse injection on proppant distribution in fracture

Bai,

2023

AETR

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The trend of changes in proppant concentration and fracture conductivity is essentially identical. When combined with an analysis of the average conductivity of effectively propped fractures at different locations, it becomes evident that the proppant distribution pattern becomes uneven after pulse injection. However, this pattern displays a discontinuous distribution law on the macro level. Influenced by the proppant distribution pattern, fracture conductivity exhibits significant variation at different locations. During the conventional injection process, the conductivity of fractures near the wellbore gradually decreases from proximity to distance. Conversely, the proppant phase distribution during pulse injection induces fluctuation in fracture conductivity, transitioning from proximity to distance.

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Section: Introductionmentioning

confidence: 99%

Effect of pulse injection on proppant distribution in fracture

Bai,

2023

AETR

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A visualization study of proppant transport in foam fracturing fluids

Tong

Singh

Mohanty

2018

Journal of Natural Gas Science and Engineering

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Computational Fluid Dynamics Applied To Investigate Development of Highly Conductive Channels Within the Fracture Geometry

Gomaa

Hudson

Nelson

et al. 2017

SPE Production &Amp; Operations

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Summary A conventional proppant pack may lose up to 99% of its conductivity because of gel damage, fines migration, multiphase flow, and non-Darcy flow. Therefore, the concept of pillar fracturing was developed to generate highly conductive paths for hydrocarbon to flow. This paper describes experimental results and numerical models of a new method to generate stable proppant pillars. The proposed treatment method depends on fingering phenomena observed when a less-viscous fluid that does not carry proppant is injected to displace a more-viscous one that carries proppant. Because the low-viscosity fluid tends to move faster than the high-viscosity fluid, the low-viscosity fluid can penetrate the high-viscosity fluid and create channels inside it. This reshapes and divides the proppant-laden, high-viscosity fluid into isolated patterns that create proppant pillars. Large-scale experiments (slot test, 2-ft height and 16-ft length) were performed to evaluate the development and stability of the created channels by use of different injection rates and different fluid viscosities. In addition, a computational fluid dynamics (CFD) model was constructed to simulate the experiment results and to scale them up into full fracture dimensions. The study focused on the effects of surface-injection rate [1 to 40 (bbl/min)/cluster], pulsing time (5 to 60 seconds), and viscosity ratio (from 2 to 200) between the two injected fluids. Experimental results and numerical modeling showed that with the use of viscous-fingering phenomena, a pillar-propped fracture with conductive and stable channels can be created. Channel shape and size were dependent on injection rate where increasing the injection rate reduces the main channel width with increasing the channel branching. Full piston-displacement behavior was noticed after 60% of the fracture height, when a high-viscosity fluid displaced a low-viscosity fluid, and their viscosity ratio was greater than 5. By reducing the viscosity ratio between the two fluids, the created channel shape converts from cylindrical (where the beginning and end of the channel have the same width) to conical behavior (where the beginning of the channel is wider than the end). This explains why the length of the channel decreases with the viscosity ratio between the two fluids. Distance between pillars was reduced with increasing travel distance from the wellbore, or with reduced pulse-stage volume, time, or rate.

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Improving Fracture Conductivity by Developing and Optimizing Channels within the Fracture Geometry: CFD Study

Cited by 12 publications

References 52 publications

Effect of pulse injection on proppant distribution in fracture

Effect of pulse injection on proppant distribution in fracture

A visualization study of proppant transport in foam fracturing fluids

Computational Fluid Dynamics Applied To Investigate Development of Highly Conductive Channels Within the Fracture Geometry

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