The Effect of Resin-Coated Proppant and Proppant Production on Convergent-Flow Skin in Horizontal Wells With Transverse Fractures

Shaoul, Josef R.; Park, Jason; Langford, Marc

doi:10.2118/197052-pa

Cited by 4 publications

(2 citation statements)

References 30 publications

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“…Proppant flowback is an issue after an oil well is hydraulically stimulated in Xinjiang oilfield. It generally refers to proppant production phenomenon after a fractured well is put in production [1]. It leads to many negative effects including production loss, corrosion of surface and downhole equipments and increase of production costs etc., so some techniques must be applied to control proppant flowback during production of a fractured well [2,3].…”

Section: Introductionmentioning

confidence: 99%

Feasibility of Proppant Flowback Control by Use of Resin-coated Proppant

Jiao,

Zhu,

Chang

et al. 2024

J. Basic Appl. Sci.

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Proppant flowback is a problem in Xinjiang oilfield. It decreases production rate of a fractured oil well, corrodes surface and downhole facilities and increases production costs. Curable resin-coated sand is a common technique to control proppant flowback. This article presents an experimental investigation whether it is feasible to control proppant flowback by use of resin-coated sand and whether resin-coated sand has a negative effect on proppant pack conductivity. It included two kinds of experiments, Proppant flowback experiment measured critical flow rate while the Proppant pack conductivity one measured proppant conductivity. The experimental results of proppant flowback show that the critical flow rate of resin-coated sand is far greater than that of common sand which means proppant flowback would not happen by resin-coated sand tail-in. Compared to Xinjiang sand conductivity, resin-coated sand conductivity is far smaller though it declines slightly which means use of resin-coated sand would lead to conductivity loss and sequentially results in production impairment. Experimental results show that it is feasible to control proppant flowback by use of resin-coated sand and resin-coated sand would affect fracture conductivity of a fractured oil well. Based on the experimental results, resin-coated proppant conductivity can be improved by use of resin-coated ceramic or liquid-resin-coated proppant. The achievements can give a direction towards how to select a resin-coated proppant and how to improve resin-coated proppant.

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Section: Introductionmentioning

confidence: 99%

Feasibility of Proppant Flowback Control by Use of Resin-coated Proppant

Jiao,

Zhu,

Chang

et al. 2024

J. Basic Appl. Sci.

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show abstract

“…This greatly limits their practical application. In addition, coating technologies are rarely applied for proppants except when coating proppants to adjust density to enhance suspension ability [28][29][30] or thermally fixing the proppant in a hydraulic fracturing crack in order to limit the removal of the proppant from the well during production. Additionally, few existing studies have focused on using superhydrophobic-coated proppants in fractures with excellent compression resistance and temperature stability to achieve water plugging and oil permeability in fractures.…”

Section: Introductionmentioning

confidence: 99%

A New Coated Proppant for Packing Fractures in Oil Reservoirs

et al. 2023

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The method of packing conventional proppant into fractures is used to maintain high liquid permeability. In this study, by coating a hydrophobic material on the surface of a proppant, the layer packed with this coated proppant was endowed with water-plugging and oil-permeability capacities. Moreover, several research experiments were carried out to verify the proposed method: a water plugging capacity (WPC) test of the coated proppant layer, compression and temperature resistance tests of the coated proppant (temperature range from 90 to 210 °C; pressure range from 5.9 to 91.4 MPa), and a 3D test of the oil recovery enhancement. The results show that the proppant coating has good compression resistance, and the proppant begins to break at 27.3 MPa. The upper limit of the temperature resistance of the coating is 170 °C. The WPC of the layer packed with coated proppant was still reliable during fracture, which was enhanced by at least 20% compared with that of the layer packed with a conventional proppant. The fracture packed with the coated proppant had superior working performance compared with that packed with a conventional proppant. It can reduce the flow capacity of the water phase breaking into the dominant flow passage so as to delay the rise in the water production of the oil well and prolong the duration of oil production. In this way, oil recovery could be increased by about 7.7%. In conclusion, the technology proposed in this paper has particular water-plugging and oil-permeating characteristics, with remarkable technical advantages, thus providing a new idea for the development of water control in fracture reservoirs.

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Minimizing Erosion of Downhole Proppant Flowback Control Equipment During Fracturing

Woiceshyn

Dikshit

Agnihotri

et al. 2020

Day 4 Thu, November 12, 2020

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Proppant flowback from hydraulic fracturing is widespread and costly due to erosion and/or blockage of producing hydrocarbons due to proppant accumulation. One remedy is to install sand control equipment integrated into a sliding sleeve device (SSD) as part of the completion string, which raises concern about erosion during fracturing. While some installations have been successful, at least one experienced sand control failure. Computational Fluid Dynamics (CFD) was deployed to evaluate the root cause and identify more robust designs, as presented herein. Firstly, we identified the most probable causes of sand control failure during multistage fracturing (MSF) in openhole (OH) horizontals. State-of-the-art CFD simulations were then performed on the installed design using actual flow conditions (rates, slurry properties, treatment time) from a failed installation. The static CFD methodology in an initial undeformed geometry proved to be ultra-conservative, so a new quasi dynamic mesh (QDM) methodology was developed, which yielded more realistic (albeit still conservative) erosion-depth predictions. The results revealed areas for improving the design of key components, and CFD was re-run to confirm erosion resistance targets. The modifications were then implemented for a field trial. Since frack location between two openhole packers is unknown, and the frack port is located between multiple screen/SSD assemblies, one must consider annular flow across the assembly in both directions. Accurate CFD predictions of erosion of completion components versus time during MSF in OH proved challenging. The quicker static methods were useful in ruling out some components as problem areas, such as the sand control media, but proved overly conservative on other key components. The QDM methodology gave more realistic results and indicated that erosion depths in specific locations could be deep enough to possibly cause sand control failure. To reduce the erosion risk, such components were modified, and the result was a reduction in predicted erosion depths to acceptable levels. A safety factor was already built into the predictions because of two key conservative assumptions: ignored initially were 1) particle-particle interaction and 2) erosion of the reservoir wall. The former was further investigated. While waiting for the field trial results, the main conclusion thus far is that CFD is a valuable tool for diagnosing erosion failures and improving equipment design. However, it’s essential to use a methodology that realistically captures downhole conditions. Presented herein is a more robust design of a screen/SSD assembly for proppant flowback control, as well as an improved CFD methodology for diagnosing sand control failures during MSF and for identifying design improvements of completion equipment. Furthermore, the inherent challenges of controlling proppant flowback without causing erosion or flow blockage of hydrocarbons are discussed.

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The Effect of Resin-Coated Proppant and Proppant Production on Convergent-Flow Skin in Horizontal Wells With Transverse Fractures

Cited by 4 publications

References 30 publications

Feasibility of Proppant Flowback Control by Use of Resin-coated Proppant

Feasibility of Proppant Flowback Control by Use of Resin-coated Proppant

A New Coated Proppant for Packing Fractures in Oil Reservoirs

Minimizing Erosion of Downhole Proppant Flowback Control Equipment During Fracturing

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