A Newly Developed Aqueous-Based Consolidation Resin Controls Proppant Flowback and Aids in Maintaining Production Rates in Fracture-Stimulated Wells

Salah, Mohamеd K.; Abdel-Meguid, Ahmed; Abdelbaky, Amr; El-Maghraby, Omar

doi:10.2118/181297-ms

Cited by 4 publications

(1 citation statement)

References 5 publications

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“…Currently, water-based resins are used, first tested in Egypt in 2009. The cost of strengthening the bottomhole zone with a water-based resin is half that of using a hydrocarbon-based resin [8].…”

Section: Introductionmentioning

confidence: 99%

Development of composition of cementing slurry for fastening of low-cemented rocks

Kondrat¹,

Dremliukh²,

Khaidarova³

2021

Min. miner. depos.

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Purpose. Improving the producing capacity and ensuring the stable operation of gas wells that develop unstable, low-cemented reservoirs by preventing the sand entry from the reservoir by means of creating the cement stone with the corresponding values of strength and permeability in the bottomhole formation zone. Methods. The technological characteristics of the cementing slurry and the formed cement stone are measured using standard recording equipment. The cementing slurry consistency is measured with a pycnometer, the cement mixture spread ability – using AzNII cone, water separation is measured according to standard methods (DSTU BV.2.7 – 86-99), and the time of the cementing slurry hardening is determined on a consistometer KTS-3. The ultimate parameters of the stone strength during bending are determined on a special device for testing linear objects in tension, and compression – on a PSU-10 hydraulic press. Findings. The cementing slurry composition for creating the cement stone with the corresponding values of compression strength and gas permeability in the bottomhole formation zone has been developed, which includes oilwell cement, expanded perlite, non-ionic surfactant, plasticizer and water. Dependences of the cement stone compression strength and the stone permeability coefficient on the proportion of expanded perlite in the cementing slurry solution have been revealed. It is recommended to use the proposed cementing slurry for creating a cement stone with specified values of compression strength and permeability in the expanded well shaft in the interval of the producing reservoir. Originality. The optimal proportion of the expanded perlite in the solution has been found, at which the corresponding values of the compression strength (up to 4 MPa) and gas permeability (up to 3.47 μm2) of the cement stone is provided. Practical implications. When using the developed composition, it is possible to increase the yield of wells with unstable reservoirs and improve their working conditions by preventing the sand entry from the reservoir into the well.

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Section: Introductionmentioning

confidence: 99%

Development of composition of cementing slurry for fastening of low-cemented rocks

Kondrat¹,

Dremliukh²,

Khaidarova³

2021

Min. miner. depos.

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Self-healing elastomer modified proppants for proppant flowback control in hydraulic fracturing

Zhang

et al. 2022

Petroleum Science

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Mitigating Proppant Flowback through Surface Treatment of Proppant-Laboratory Studies and Field Performance

Lu¹,

O’Neil²,

Zhang³

et al. 2018

Day 3 Thu, October 18, 2018

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Post stimulation proppant flowback can be a serious problem after the hydraulic fracturing process and can cause a variety of issues like: reduced fracture propping resulting in decreased conductivity and hydrocarbon production;erosion related damage to surface and downhole equipment; and increased costs in dealing with recovered proppant disposal. To address the concerns related to proppant flowback, various technologies, including chemical, mechanical, and engineering design have been employed. A common and long term commercial approach is to apply a resin to the surface of the sand. However, resin coatings can be costly relative to the cost of the sand substrate, often doubling or tripling the cost of the sand substrate to which they are applied. Additionally, resin coated proppants often need to be activated with exposure to temperature and pressure. The requirement for additional chemical activators at lower reservoir temperatures can also add additional cost to the treatment. Furthermore, resin coated sands are typically manufactured near a sand mine and then shipped to remote well locations. This offers another layer of logistical complexity to bringing large volumes of sand to a site or often multiple types of sand and thus can add additional costs. In some cases, on-site or near-site manufacturing of resin coatings is possible, but again at an additional cost. A proppant flowback control measure which is cost-effective and can function over a wide range of reservoir conditions would be advantageous to the hydraulic fracturing process. A new technology for proppant flowback control was previously presented where chemically modifying the proppant surface with the proppant consolidation additive (PCA) can induce a strong capillary attraction among proppant grains leading to proppant agglomeration (Lu et al., 2016). This study serves to further examine this sand surface modifying chemical. Additional experimental results will focus on conductivity measurement of surface treated proppant and flow resistance tests of treated proppants relative to untreated proppants at varying conditions. The field performance of more than 50 wells in western Canada in terms of proppant flowback control using thisnewly developed technology will also be presented. A discussion of field application and results in several scenarios will demonstrate the correlation of the laboratory experimental results to actual field performance. Compared with untreated either Tier 1 or Tier 2 proppant, the surface treatment of proppant increases flow resistance under all the tested confining pressure, also, noticeable increase of proppant conductivity under high confining pressure was observed, which is an advantage of the surface treatment of proppants. The field performance data show that this newly developed technology gives similar or better results relative to resin coated proppants in terms of proppant flowback control. This technology demonstrates the following advantages: 1) it can be applicable to either Tier 1 or Tier 2 proppant; 2) it can be easily applied on-the-fly to sand during a fracturing operation, either as the tail in sand stage, alternating during the entire stage, or being sprayed on all the sand stage, which makes it flexible for operators to design proppant flowback control and to ease the logistics of managing proppant delivery to location as well; 3) it perfroms under a wide range of reservoir conditions because it is independent of reservoir pressures and temperatures.

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A Newly Developed Aqueous-Based Consolidation Resin Controls Proppant Flowback and Aids in Maintaining Production Rates in Fracture-Stimulated Wells

Cited by 4 publications

References 5 publications

Development of composition of cementing slurry for fastening of low-cemented rocks

Development of composition of cementing slurry for fastening of low-cemented rocks

Self-healing elastomer modified proppants for proppant flowback control in hydraulic fracturing

Mitigating Proppant Flowback through Surface Treatment of Proppant-Laboratory Studies and Field Performance

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