Predicting and Managing Sand Production: A New Strategy

Palmer, Ian; Willson, S.M.; Moschovidis, Z.A.; Cameron, John; Ispas, Ion

doi:10.2118/84499-ms

Cited by 40 publications

(15 citation statements)

References 13 publications

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“…A reasonable level of steady state sand production is <1 ppmv. 10 A failure in the gravel pack will lead to a significant spike in sand concentration and size.…”

Section: Comparison Of Subsurface and Surface Methodsmentioning

confidence: 99%

A Comparison of Methodologies for Handling Produced Sand and Solids to Achieve Sustainable Hydrocarbon Production

Rawlins

Hewett²

2007

European Formation Damage Conference

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fax 01-972-952-9435. AbstractAll oil and gas wells produce sand or solids in varying types and amounts. The size and concentration of natural solids (i.e. formation sand) and artificial solids (i.e. workover debris) determine their net effect on production equipment and the resulting management of hydrocarbon production. Conventional exclusion methodology prevents solids from entering the wellbore but may adversely affect inflow production due to skin buildup. Inclusion methodology allows the solids to be produced with well fluids for surface separation and handling. A comparison of the performance, operability, cost impact, and effect on production rate is made for both methods through application examples. The goal is to show that the increased production resulting from allowing solids to be produced in some high sand rate wells allows more sustainable hydrocarbon production with a cost benefit compared to downhole exclusion for certain producing regions.

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“…A reasonable level of steady state sand production is <1 ppmv. 10 A failure in the gravel pack will lead to a significant spike in sand concentration and size.…”

Section: Comparison Of Subsurface and Surface Methodsmentioning

confidence: 99%

A Comparison of Methodologies for Handling Produced Sand and Solids to Achieve Sustainable Hydrocarbon Production

Rawlins

Hewett²

2007

European Formation Damage Conference

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“…Seno-104 S102 S104 WS-4 well A02 well The sand prediction done for the West Seno wells uses a shear-failure-based prediction model 1,2 . It predicts the onset of failure/collapse (and substantial sanding), and is extended to predict levels of continuous sand production, within the following four-step approach:…”

Section: West Seno Sand Predictionmentioning

confidence: 99%

Sanding Study for Deepwater Indonesia Development Wells: A Case History of Prediction and Production

Palmer¹,

Higgs²,

Mathers³

et al. 2008

SPE International Symposium and Exhibition on Formation Damage Control

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A detailed sand prediction has been made for three wells at Chevron's West Seno field based on logs/lab data and the results have been calibrated with production data. Both maximum allowable drawdown and depletion increase with depth. Additionally, oriented perforations offer an improvement to perforation stability against sanding: the maximum allowable drawdowns and depletions are increased for all sands. Finally, an analysis is presented on the economics and trade-offs of vertically-oriented perforating (with possibly managed sand production) versus frac-packing. Sand onset prediction agrees fairly well with the observed drawdown/depletion for horizontal perforations. This benchmarking appears to support the validity of the shear-failure model. This is important because the model, while fairly simple, has many different inputs, including depth profiles for unconfined compressive strength (UCS) and in-situ stresses, which involve sophisticated prediction techniques themselves. Continuous sand rates (for oil wells) have also been predicted by extending the shear-failure sanding model. As depletion increases over time, added perforation intervals begin to fail/collapse, increasing the sand rate. There are periods of agreement and underestimation (by a factor of ~4) between observation and prediction. This is important because it is the first time this model has been benchmarked against observation at early times in a well's life. It appears the model can provide a first estimate of sanding levels in oil wells, which are useful to assist the design of well facilities for dealing with sand. Finally, a sand prediction was used to evaluate oriented perforating in lieu of frac-packed completions. The evaluation defined production scenarios, by building nodal and production forecast models, and ran incremental economics. It indicated that oriented perforating can provide favorable economics over fracpacks if critical rock properties and production plans are defined and understood.

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“…Formation failure, disaggregating, and sanding are irreversible phenomena (Dusseault and Santarelli, 1989). They may occur when the following sanding criterion is satisfied (Palmer et al, 2003):…”

Section: Stress Shock-critical Yield Stress (Cys)mentioning

confidence: 99%

“…The magnitude of the critical interstitial velocity or fluid drag is affected by the fluid viscosity and type (oil, gas, and water), friction, and capillary tension (Nouri et al, 2003). It depends on the grain contact strength (cementation) and the prevailing flowing pressure condition (Palmer et al, 2003, Wan and Wang, 2004, Hayatdavoudi, 2005.…”

Section: Surface Removal / Mobilizationmentioning

confidence: 99%

Formation Damage Mechanisms and Their Phenomenological Modeling—An Overview

Civan

2007

European Formation Damage Conference

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fax 01-972-952-9435. AbstractA review and phenomenological modeling of the various processes causing reservoir formation damage are presented. The mechanisms involved in the migration, deposition, and mobilization of the fine particles and inorganic and organic precipitates are described physically and mathematically. The various problems created by fine particles at the pore surface, clogging and dislodgment of the pore throats, aggregation, and interface particle transfer processes in multi-phase fluid systems flowing through porous media are described. The implications of the various mechanical, chemical, and thermal processes on the behavior of the particles are discussed. The various types of shock phenomena and their effects on the particulate processes are explained. The alteration of the pore connectivity, preferential hydraulic paths, permeability and porosity of porous media as a result of the various particulate processes are formulated. The phenomenological modeling of the particulate processes in single-and multiple-porosity reservoir formations is presented. The applications may concern with the damage by particles, injectivity decline in waterflooding wells, formation damage by drilling mud invasion, formation damage in naturally fractured reservoirs, asphaltene deposition, and sand production and gravel pack damage.

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Predicting and Managing Sand Production: A New Strategy

Cited by 40 publications

References 13 publications

A Comparison of Methodologies for Handling Produced Sand and Solids to Achieve Sustainable Hydrocarbon Production

A Comparison of Methodologies for Handling Produced Sand and Solids to Achieve Sustainable Hydrocarbon Production

Sanding Study for Deepwater Indonesia Development Wells: A Case History of Prediction and Production

Formation Damage Mechanisms and Their Phenomenological Modeling—An Overview

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