Sand Prediction: A Practical Finite-Element 3D Approach for Real Field Applications

Volonté, Giorgio; Scarfato, Francesco; Brignoli, M.

doi:10.2118/134464-pa

Cited by 17 publications

(5 citation statements)

References 16 publications

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“…The numerical simulation method studies the coupled situation of fluid and solid phases in the formation. Volonté established a dynamically coupled numerical model of rock and fluid mechanics [3]. The model parameters are complicated and difficult to obtain, and the calculation process is time-consuming.…”

Section: Introductionmentioning

confidence: 99%

Sand Production Prediction and Safe Differential Pressure Determination in a Deepwater Gas Field

Qiu¹,

Wu²,

Wen³

et al. 2023

Fluid Dynamics &Amp; Materials Processing

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Sand production is a critical issue during the development of offshore oil and gas fields. Certain gas fields (e.g. the AB gas field) have high porosity and high permeability, and with water at the bottom of the reservoir, the risk of sand production greatly increases at high differential pressures. Based on reservoir properties, geological conditions, production requirements, and well logging data, in this study an ultrasonic time difference method, a B index method, and a S index method are used together with a model of rock mass failure (accounting for water influx and pressure depletion) to qualitatively predict sand production. The results show that considered sample gas field has an overall high risk of sand production. The critical differential pressure (CDP) without water influx is in the range of 1.40 to 2.35 MPa, the CDP after water influx is from 0.60 to 1.41MPa. The CDP under pressure depletion is in the range of 1.20 to 1.92 MPa. The differential pressure charts of sand production are plotted, and the safe differential pressure windows with or without water influx are obtained. The model calculation results and the experimental results are consistent with the field production data, which indicates that the implemented prediction method could be taken as a reference for sand production prediction in similar deep water gas fields.

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Section: Introductionmentioning

confidence: 99%

Sand Production Prediction and Safe Differential Pressure Determination in a Deepwater Gas Field

Qiu¹,

Wu²,

Wen³

et al. 2023

Fluid Dynamics &Amp; Materials Processing

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show abstract

“…They found the fracture mechanism was a combination of volume collapse (compaction zone formation) and hydrodynamic transport of failed material, and the sand production volume monotonically increased with simulation time. Volonté et al 31 established a three‐dimensional (3D) coupled model using finite element modeling to simulate fluid flow and rock deformation, and quantified the spatial distribution and damage severity of the rock around the perforation, adopting several optimal geometries and meshes describing the wellbore, perforation tunnel, and surrounding strata. Kim et al 32 showed a 3D numerical model quantitatively describing the sand failure, erosion, and production.…”

Section: Introductionmentioning

confidence: 99%

Critical drawdown pressure prediction for sanding production of underground gas storage in a depleted reservoir in China

Song,

Xie,

Zhang

et al. 2023

Energy Science & Engineering

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Sanding production of the underground gas storage (UGS) in the depleted reservoir will cause the decline of effective storage capacity, and the erosion of well string and auxiliary equipment, and other engineering problems. A deep understanding of the sanding production contributes to maintaining the injection and production capacity of gas storage and the long‐term safety of the UGS. In this paper, core samples of five main sedimentary microfacies were drilled from the UGS in middle China. The mechanical properties with different conditions of the moisture content in multi‐cycling injection–production process were tested. The critical drawdown pressure (CDP) calculation methods for the UGS were established based on the stress analysis near the wellbore and the Mogi–Coulomb criterion. Adopting the finite element method simulation on the geological model of the target UGS, the geo‐stress of the formation was calculated by inversed analysis and validated based on the Kaiser effect of rock. Then, the CDP of two target wells of the UGS were investigated. The effects of the water moisture and the cycling times of the injection–production process on the CDP were also analyzed. The geo‐stress distribution shows that the horizontal maximum principal stress ranges from 53 to 68 MPa, and the horizontal minimum principal stress is 46–58 MPa in the target reservoir section, and the vertical minimum principal stress is 69–77 MPa in the target reservoir. The calculated CDP changed with the types of the sedimentary microfacies in the range of [6.27, 8.77] MPa, in which the CDP of the mixed mud and sand flat sedimentary facies was the lowest. The weakness of the CDP with the increasing of the moisture content and the cycling times were analyzed quantitively.

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“…In general, sand production is investigated with models based on field or experimental observations often calibrated by field or laboratory data to prove their predictive efficiency. Research works on numerical, analytical and experimental investigations include: Qiu et al, 1 Osisanya, 2 Papamichos, 3 Rahmati et al, 4 Volonte et al, 5 Ikporo and Sylvester, 6 Wang and Sharma, 7 Gravanis et al, 8,9 Gholami et al, 10 Li et al, 11 Eshiet et al, 12 Fetrati and Pak, 13 van den Hoek et al, 14 Subbiah et al, 15 Sarris et al, 16 Ma et al, 17 Zhang et al 18 and Kakonitis et al 19 Many researchers have attempted to explain the cause of sand production. Sanding is attributed to the increase of effective Rate of softening (Eqs.…”

Section: Introductionmentioning

confidence: 99%

A hydro-mechanical semi-analytical framework for hollow cylinder sanding tests

Kakonitis,

Gravanis,

Sarris

2023

Geomechanics for Energy and the Environment

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Sand Prediction: A Practical Finite-Element 3D Approach for Real Field Applications

Cited by 17 publications

References 16 publications

Sand Production Prediction and Safe Differential Pressure Determination in a Deepwater Gas Field

Sand Production Prediction and Safe Differential Pressure Determination in a Deepwater Gas Field

Critical drawdown pressure prediction for sanding production of underground gas storage in a depleted reservoir in China

A hydro-mechanical semi-analytical framework for hollow cylinder sanding tests

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