Fracturing Completion System Optimization through Advanced Hydraulic Modeling

Deshpande, Kedar; Simpkins, Douglas; Gandikota, Raju; Ring, Lev

doi:10.2118/160552-ms

Cited by 7 publications

(2 citation statements)

References 11 publications

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“…Deshpande et al presented a methodology which combined CFD and theoretical approaches to calculate split flow rate and pressure drop of fracturing fluid in a multiple sliding sleeve system. Their method can be useful in designing a sliding sleeve (Deshpande et al, 2012). Rosine et al used computational fluid dynamics software to provide greater insight into actual coiled tubing flow patterns, including fluid flow velocity profiles, secondary flow regimes and erosion phenomenon.…”

Section: Introductionmentioning

confidence: 99%

Structural optimization of downhole fracturing tool using turbulent flow CFD simulation

Zheng

Wang

et al. 2015

Journal of Petroleum Science and Engineering

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Section: Introductionmentioning

confidence: 99%

Structural optimization of downhole fracturing tool using turbulent flow CFD simulation

Zheng

Wang

et al. 2015

Journal of Petroleum Science and Engineering

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“…Multiphase flow in wells was studied by Dong et al [10] using a drift flux model coupled with a dynamic gridding technique. A detailed CFD modeling coupled with hydraulics modeling was developed by Deshpande et al [9] to predict the flow behavior in hydraulic fracturing, where advanced 3-D CFD software that simulated flow behavior accurately helped develop closed form equations utilized by field personnel. A general dynamic model for multiphase flows was developed by Peterson et al [2] that could be utilized in a real time drilling environment.…”

Section: Introductionmentioning

confidence: 99%

Multiphase Flow Modeling of Surface Equipment in Managed Pressure Drilling Operations

Deshpande

Northam

Sabhapathy

et al. 2014

SPE Annual Technical Conference and Exhibition

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Surface equipment for Managed Pressure Drilling operations handles a multiphase mixture of drilling mud, cuttings and reservoir fluid influx. It is mandatory for safe MPD operations that surface equipment be able to handle pressure surges, pressure drops as well as any phase change of the fluid without causing any safety issues. In MPD operations, the surface choke is a key surface manifold component through which the fluid passes before entering the measurement gauges or solids control processing. Depending on choke position and flow conditions, part of the fluid can change phase from liquid to gas as it flows through the chokes resulting in formation of a gaseous phase that can be problematic for the downstream flow measurement devices and equipment integrity. A detailed analysis of the phase transition of the fluid in the surface equipment is necessary that can elucidate design modifications to ensure accurate measurements for safe and efficient drilling operations.In this work, multiphase fluid flow is analyzed numerically using 3-D computational fluid dynamics (CFD) and a 1-D hydraulics network solver to understand the effects of choke positions on the overall pressure drop, pressure surges and onset of phase transformation to ensure surface equipment safety. 1-D hydraulics network results are validated against the 3-D CFD software as well as against experimental studies. Based on extensive numerical 1-D studies, look-up tables and charts were developed that help field personnel design the best surface equipment configuration, determine associated pressure drop and guard against the possibility of phase transformation.

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Dual String Section Milling Tool Design Optimisation Using Advanced Numerical Simulations

Deshpande

Haq

Gajula

et al. 2016

SPE Asia Pacific Oil &Amp; Gas Conference and Exhibition

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Well Intervention Plug and Abandon (P&A) operations play an important role at the end of life cycle of a subsea well in safely dismantling the well such that the well no longer poses any environmental hazards. P&A operations for subsea wells require sophisticated and efficient downhole tools that can operate at downhole pressures safely and reduce Non-Productive Time (NPT). A Dual String Section Milling (DSSM) downhole tool removes two adjacent casings in single trip reducing NPT while conducting safe P&A operations is discussed in this paper. This paper’s objectives are two fold first is to utilize advanced computational fluid dynamics (CFD) to improve DSSM tool life span for safe and economical P&A operations and second is to develop methodology for a quick and reliable solution for field personnel by combining CFD results with known closed form hydraulic models. The DSSM tool must maintain a certain pressure drop and flow range to achieve optimum performance. Higher flow rates and pressures can reduce tool life and cause erosion/washouts due to higher flow velocities. To address these issues simultaneously numerical simulations are conducted to optimize the DSSM tool design and operating parameters. To prove validity of numerical results CFD simulation outputs are compared against available test data and a good match is observed. Three dimensional CFD simulations are conducted using pressure based algorithm for numerically solving Reynolds-Averaged Navier-stokes (RANS) equation using second order upwind discretization scheme and k-ε turbulence model. Extensive CFD results are utilized in generating flow coefficients for closed form hydraulics models to formulate pressure drop versus flow rate charts for field usage. CFD simulations are conducted for flow rates between 100 gpm to 700 gpm to understand flow characteristics and pressure drop distribution within DSSM tool. CFD simulations showcased the locations prone to washouts; particularly washouts were observed around 90 degrees bend angles. The washout locations indicated by CFD analysis matched very well against the available test data. The DSSM tool design was then optimized using CFD simulations such that fluid velocities were below washout velocity and also higher annular velocities were maintained to alleviate hole cleaning problem during milling operations. The pressure drop versus flow rates curves obtained using flow coefficients showed correct trends with higher pressure drop for higher flow rates and higher pressure drop for reduced nozzle size. Thus utilizing CFD analysis, optimization and laboratory testing, service life of DSSM tool was increased, thus saving substantially on field NPT.

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Fracturing Completion System Optimization through Advanced Hydraulic Modeling

Cited by 7 publications

References 11 publications

Structural optimization of downhole fracturing tool using turbulent flow CFD simulation

Structural optimization of downhole fracturing tool using turbulent flow CFD simulation

Multiphase Flow Modeling of Surface Equipment in Managed Pressure Drilling Operations

Dual String Section Milling Tool Design Optimisation Using Advanced Numerical Simulations

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