Prediction of Proppant Settling Velocity in Fiber-Containing Fracturing Fluids

Bai, Zhifeng; Li, Mingzhong

doi:10.1021/acsomega.3c03369

Cited by 3 publications

(2 citation statements)

References 36 publications

(62 reference statements)

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“…where ρ f g(1 + C(η − 1)) is the additional gravity component arising from the difference in density between proppant and fracturing fluid, which is only available in the longitudinal direction, η = ρ p ρ f . The proppant settling velocity is given by (Bai and Li, 2023;Kong et al, 2015;Li et al, 2024;Pan et al, 2018;Roostaei, 2017;Sahai and Moghanloo, 2019;Singh et al, 2022) (Table 1):…”

Section: Numerical Modelingmentioning

confidence: 99%

“…), different proppant types (grain size (Sahai and Moghanloo, 2019), sphericity (Zhang, 2017), density (Hao, 2018;Li, 2018)), different carrying fluid viscosities (Anschutz et al, 2023;Zhang et al, 2021), different injection flow rates (Liang et al, 2018;Liu et al, 2019;Zhang et al, 2023b), different fracture types (eg. even-wide fractures (Liang et al, 2018), elliptical shape fractures (Zhu et al, 2023) or complex fractures (Li et al, 2024;Qu et al, 2023;Xiang and Li, 2023)) were also investigated in the indoor tests to obtain the proppant accumulation distribution under various conditions, which then served as a reference for optimization of the parameters of the hydraulic fracturing in the field, Bai and Li (2023) and Zhou et al (2023) did research on the friction and settling characteristics by indoor tests to provide parameters for numerical model. However, the model equipment of indoor tests during hydraulic fracturing does not fully simulate the actual situation of a fracture morphology in the subsurface.…”

Section: Introductionmentioning

confidence: 99%

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Simulation and solution of a proppant migration and sedimentation model for hydraulically fractured inhomogeneously wide fractures

Peiqi,

Lin,

et al. 2024

Energy Exploration & Exploitation

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The distribution of proppant during hydraulic fracturing may directly contribute to the flow conductivity of the proppant fracture, so research on the migration and sedimentation of proppant in the fracture and the final distribution pattern is of great relevance. The mass conservation equations of proppant solids and fracturing fluid were adopted to describe the distribution of proppant migration and sedimentation in the fracture, improving the additional gravity coefficient by utilizing the density difference between proppant and fracturing fluid and the concentration of proppant, together with the proppant sedimentation velocity at different Reynolds numbers in this study. The flow coefficients were obtained by discretizing the system of equations through the finite volume method combined with the harmonic mean method and the upstream weight method. The concentration additional pressure gradient term was computed by using the Superbee format innovatively to improve the solution convergence of the model. Numerical simulations with identical parameters were compared with indoor test results, which fully verified the correctness of the model and the accuracy of the discrete solution based on the finite volume method. The effects of flow rate of fracturing fluid, ratio of injected sand, viscosity of fracturing fluid, grain size of proppant and density of proppant on proppant migration and sedimentation based on three elliptical fracture morphologies: even-wide, top-wide and bottom-narrow as well as top-narrow and bottom-wide were investigated and analyzed through comparing the rate of proppant front movement, the level of sweeping range and the degree of inhomogeneity in the range under different conditions. Findings of this study suggest that: (1) top-wide and bottom-narrow fractures are more preferable for homogenous sanding in the early stage of proppant injection, and top-narrow and bottom-wide fractures are best for sanding in the later stage; (2) the viscosity of fracturing fluid is the most influential factor on proppant migration and sedimentation, which increases in the range of 100 mPa.s to enhance the sweeping range and homogeneity of proppant sanding and therefore achieve a better fracturing effect.

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Section: Numerical Modelingmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Simulation and solution of a proppant migration and sedimentation model for hydraulically fractured inhomogeneously wide fractures

Peiqi,

Lin,

et al. 2024

Energy Exploration & Exploitation

View full text Add to dashboard Cite

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Application of Machine Learning Method for Modeling Settling Behavior of a Spherical Particle in Fibrous Drilling Fluids

Elgaddafi,

Al Saba,

Ahmed

et al. 2024

Day 2 Tue, April 23, 2024

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In the oil and gas industry, several challenges are possibly encountered during drilling operations which can lead to an increase in the non-productive time. One of these problems is the wellbore cleanout process in extended horizontal wells. Counting on the adjustment of fluid properties to robust the wellbore cleanout becomes a privileged solution while drilling in depleted and deep formations. Fibrous sweep fluid has been exploited to effectively clean the horizontal segment of the wellbore. Understanding the settling of cuttings in drilling fluid is a crucial factor for successfully preparing fibrous drilling fluid. This study aims to model the sedimentation behavior of a particle in the fibrous fluid using an artificial intelligence technique. The model will significantly assist the engineers in designing drilling fluid formulation by finding the optimum base fluid properties and fiber concentration. In this study, a total of 1012 data points of settling velocity measurement were collected from the literature. The data possess a diversity of seven input features including particle size, particle density, fluid density, fluid rheological properties, and different fiber concentrations with their corresponding measured settling velocity. The database was graphically and statically analyzed to draw insights into the dataset. Five different supervised regression machine learning algorithms (Random Forest, Support vector machine, CatBoost, Extra Tree, and Gradient Boosting) were utilized to develop a settling velocity model. In addition, the best-performing model is compared to two existing mechanistic models. The feature variable-importance analysis is implemented to identify the most crucial parameters affecting the settling velocity. The results of this study disclosed that CatBoost has a superior performance among the tested models for predicting the settling velocity. The next best accuracy is attained by the Extra Tree model. However, both models (Catboost and Extra Tree) exhibit a slight reduction in their accuracy which drops from 99% on the training set to 95% on test data sets. Moreover, Random Forest and Gradient Boosting exhibit generalized abilities and are less influenced by data outliners. The relative feature importance analysis reveals that the influence of the input feature on the settling velocity is ranked from highest to lowest as follows particle density, particle diameter, fluid consistency, fluid density, yield point, fluid behavior index, and fiber concentration. The model comparison study finds that Elgaddafi's model is more generalized compared to CatBoost and Xu's models. A new ML model for accurately predicting a particle settling velocity in the fibrous drilling fluid is presented in this study. The developed model overcomes the constraints of a numerical iteration process for the mechanistic models and the uncertainty of empirical correlations. An accurate prediction of the settling velocity leads to enhancing the wellbore cleanout in the most challenging operation.

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Preparation and rheological properties of associative salt tolerant polymer by inverse-phase emulsion polymerization

Wen,

Wang,

Lai

et al. 2024

Preprint

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An associative and salt tolerant p(AM/AMC12S/GTE-10) polymer was synthesized through reverse-phase emulsion polymerization of acrylamide (AM), 2-acrylamide-sodium dodecyl sulfonate (AMC12S), and the hydrophobic monomer 29-(4-octylphenoxy)-3,6,9,12,15,18,21,24,27-nonaoxanonacosyl methacrylate (GTE-10). The structure and morphology of the polymer obtained were then characterized by FTIR, 1H-NMR, SEM, TEM, and a laser particle size distribution analyzer. This was followed by an evaluation of its rheological properties, thixotropic properties, and viscoelasticity. The results showed that the hydrophobic monomer GTE-10 was successfully incorporated into the polymer, resulting in a narrow and uniform particle size distribution of the emulsion after polymerization. The addition of salt made the aggregation of p(AM/AMC12S/GTE-10) molecules more compact, resulting in a more stable spatial network structure. The p(AM/AMC12S/GTE-10) polymer aqueous solution with a mass fraction of 0.7% exhibited excellent temperature resistance at 140 ℃. After being sheared at 120 ℃ and 170 s–1 for 1 h, the polymer solutions with a mass fraction of 0.7%, prepared at a mass concentration of 20000 mg/L NaCl and CaCl2 aqueous solutions exhibited viscosities of 64.7 and 54.2 mPa·s, respectively, with good shear recovery performance. The energy storage modulus was higher than the loss modulus, and the complex interaction between the metal ion and phenoxyethylene group enhanced the intermolecular forces, resulting in a more stable spatial structure and increased viscoelasticity.

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Prediction of Proppant Settling Velocity in Fiber-Containing Fracturing Fluids

Cited by 3 publications

References 36 publications

Simulation and solution of a proppant migration and sedimentation model for hydraulically fractured inhomogeneously wide fractures

Simulation and solution of a proppant migration and sedimentation model for hydraulically fractured inhomogeneously wide fractures

Application of Machine Learning Method for Modeling Settling Behavior of a Spherical Particle in Fibrous Drilling Fluids

Preparation and rheological properties of associative salt tolerant polymer by inverse-phase emulsion polymerization

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