Foam Cement Job Simulations: Learning from Field Measurements

Dooply, Mohammed; Flamant, Nicolas; Kanahuati, Alia Iza; Pringuey, Thibault

doi:10.2118/166094-ms

Cited by 4 publications

(1 citation statement)

References 3 publications

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“…In addition, Dooply, et al85 mentioned that the foam quality would change 70% at the surface and 10% downhole. There is large uncertainty about the foam cement density.…”

mentioning

confidence: 99%

Numerical Study on Casing Integrity During Hydraulic Fracturing Shale Formation

Han

Yang

et al. 2019

SPE Oklahoma City Oil and Gas Symposium

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Due to the layered texture and sedimentation environment, shale formations usually characterized as high heterogeneity and anisotropy in in-situ stresses. During the hydraulic fracturing process, fracturing fluid is injected at a pressure above the formation pressure. This injection process changes the local in-situ stresses in a quick and significant manner while generating fracture systems. In the regions of existing geo-features such as natural fractures and faults, local stress changes could lead to the activation of formation movement, which in return impacts the casing going through the locale. Casing deformations during hydraulic fracturing have been observed in Southwest China Sichuan basin, and it have impeded completion operations in certain regions. In order to ensure further exploring, we analyszed this phenomenon and propose practical solutions for fault reactivation prevention. To study the mechanism of local slippage and the impact on casing integrity, we set up a 2D finite element model with considerations of in-situ stresses acquired from fields, natural fracture orientation from available seismic data, and we simulated water injection process in order to quantify potential slippage and displacement. The finite element model features an integration of casing, cementing, and formation under the hydraulic fracturing conditions. For particular parameters such as permeability and leak-off coefficeint, we conducted sensitivity studies to quantify their impacts on displacement amount. The theoretical geomechanics studies indicate water induced slippage existence in shale due to its fracture reactivation. Using the finite element model, this paper interpreted and quantified the impact of fracturing fluid injection on casing from strike-slip fault regiems. Simulation results revealed that water injection into natural fractured shale formation can induce finite displacement characterized as fault slippage along discontinues surfaces. This study could help engineers to have a better prediction as how hydraulic fracture intereact with subsurface structures and potential risks that comes along with it. This type of casing damage can be reduced by improving well trajectory design, completion operation, and higher strength level of casing-cement system. The findings from this study not only can be applied to naturally fractured formations, but also to other pre-existing geo-features such as discountinues surfaces. It also provides fundamental basis for more practical solution to find the measures and overcome the casing deformation problems in hydraulic fracturing.

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“…In addition, Dooply, et al85 mentioned that the foam quality would change 70% at the surface and 10% downhole. There is large uncertainty about the foam cement density.…”

mentioning

confidence: 99%

Numerical Study on Casing Integrity During Hydraulic Fracturing Shale Formation

Han

Yang

et al. 2019

SPE Oklahoma City Oil and Gas Symposium

View full text Add to dashboard Cite

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Application of Real-Time Process Control and Engineering Software Simulation in Foam Cementing

Dooply

Elhancha

Bruijn

et al. 2014

IADC/SPE Drilling Conference and Exhibition

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Foamed cement operations not only require a solid knowledge of the foam quality during placement, but also good control of nitrogen injection throughout the operation. These two factors ensure optimum well control during placement and provide well integrity after placement completion. A real-time foamed cement process control system is capable of handling dramatic changes in the cement slurry pump rate which allows for delivering quality foamed cement with the designed proportions of gaseous nitrogen and surfactants. The process-controlled system can also perform operations with more than 200 stages of varying nitrogen ratios to provide a near-constant density column of foamed cement in the wellbore. A dynamic compressible fluid placement simulator provides better understanding on the evolution of foam quality across the wellbore during the placement. The simulator computations take into account the influence of circulating pressures and temperatures on nitrogen compressibility. The simulator then evaluates the computed surface and downhole pressures and foam qualities throughout cement placement and after cement in place, and issues warnings whenever those parameters fall outside the design criteria at any time during the operation. Such feedback allows the engineer to adjust the design to meet the job objectives. The combination of these two technologies effectively reduces the operational complexities on foamed cement operations, which will substantially increase the success rate and enhance well integrity. Several case studies of foamed cement operations performed in the Gulf of Mexico are presented in which the use of real-time process control and dynamic placement simulation provided successful job execution and proper cement placement.

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Learning from Field Measurements: Engineering Method to Improve Cement Returns in Riserless Deepwater Jobs

Dooply

Peternell

Long

2014

Day 1 Wed, September 10, 2014

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With the increased importance of achieving zonal isolation in the shallow riserless sections of deepwater wells, it has become critical to understand the results of the cement placement. Riserless cementing job design has historically been a static process largely independent of the drilling parameters, particularly in these large-diameter boreholes.Variable borehole shape and quality affects the wellbore cleaning, wellbore stability while drilling and the smooth operation of the casing run. Borehole quality can also compromise cement placement efficiency and mud displacement mechanics. It has become increasingly important to develop a greater understanding of the impact that borehole size and the identification of borehole degradation have in cementing design and placement, to increase the likelihood of achieving zonal isolation objectives.Caliper tools provide an explicit method that uses physical measurements to evaluate not only wellbore quality but also formation characteristics. Caliper measurement is used to optimize the cementing design by adjusting key parameters such as cement slurry volumes, centralization, pre-flush volumes, and fluids pump rate, so that effective mud removal and optimized cement placement are achieved.A review the current practices of field measurements and observations to understand and detect cement returns in the deepwater drilling environment and also the applications and key learnings from the engineering workflow led to new development of tools to improve the understanding of the cement volumes required for these particular top hole sections.

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Foam Cement Job Simulations: Learning from Field Measurements

Cited by 4 publications

References 3 publications

Numerical Study on Casing Integrity During Hydraulic Fracturing Shale Formation

Numerical Study on Casing Integrity During Hydraulic Fracturing Shale Formation

Application of Real-Time Process Control and Engineering Software Simulation in Foam Cementing

Learning from Field Measurements: Engineering Method to Improve Cement Returns in Riserless Deepwater Jobs

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