Protocol for sand control screen design of production wells for clayey silt hydrate reservoirs: A case study

Li, Yanlong; Ning, Fulong; Wu, N.; Chen, Qiang; Nouri, Alireza; Hu, Gaowei; Sun, Jiaxin; Kuang, Zenggui; Meng, Qingguo

doi:10.1002/ese3.602

Cited by 36 publications

(20 citation statements)

References 35 publications

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“…Larger production pressures, higher bottom-hole temperatures, larger horizontal stress differences, and higher permeabilities are deemed as causes for serious sand production . To improve the sand control efficacy, an optimization for the screen aperture size is needed as the screen should simultaneously retain coarse particles and avoid fine particle blockage . In addition, the dilatant behaviors under shearing in sediments with high hydrate saturations and low confining pressures can lead to tensile stresses.…”

Section: Introductionmentioning

confidence: 99%

“…24 To improve the sand control efficacy, an optimization for the screen aperture size is needed as the screen should simultaneously retain coarse particles and avoid fine particle blockage. 26 In addition, the dilatant behaviors under shearing in sediments with high hydrate saturations and low confining pressures can lead to tensile stresses. This is of particular significance as this phenomenon can contribute to unwanted hydrate dissociation in shallow methane hydrate reservoirs, and the geomechanical responses to methane hydrate exploitation can actually break the equilibrium in the hydrate-stable zones, 27,28 which may eventually evolve into uncontrolled gas release, sea floor subsidence, and submarine landslide.…”

Section: Introductionmentioning

confidence: 99%

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Numerical Investigation of the Gas Production Efficiency and Induced Geomechanical Responses in Marine Methane Hydrate-Bearing Sediments Exploited by Depressurization through Hydraulic Fractures

Guo

Jin

et al. 2021

Energy Fuels

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Methane hydrates are a promising source of natural gas. Several field tests have validated the feasibility of gas production from marine methane hydrate-bearing sediments. However, sustained and commercial production has not been obtained due to limited gas production efficiency and production-induced damage to the mechanical properties in the sediments. This study investigates the gas production efficiency and the geomechanical responses in hydrate-bearing sediments developed by depressurization in hydraulic fractures. A numerical model for the simulation of coupled thermal–hydraulic–mechanical–chemical behaviors is described. The model considers three phases of water, gas, and hydrate in the sediments. Heat transport and the kinetics for hydrate dissociation are also taken into account. A Mohr–Coulomb criterion for marine methane hydrate-bearing reservoirs is employed to describe the shear failure and damaged rock strength caused by depressurization in hydraulic fractures. Then, a base case for a 750-day depressurization in a hydraulic fracture is presented. The spatial and temporal evolutions of the pore pressure, temperature, hydrate dissociation, principal stress, and shear failure are described. Parametric studies for reservoir permeability, depressurization pressure, and fracture number are also presented. The results indicate that early-stage gas rates are high, while they drop significantly with time. At late stages, shear failure is highly correlated with the reduced rock strength, and stress concentrations are obtained near fracture tips. The evolution of strength is correlated with hydrate dissociation as dissociated hydrates weaken the mechanical properties in sediments, which is also time dependent. Local stress concentrations are observed around fracture tips as well. Higher reservoir permeabilities lead to greater early-stage production and lower late-stage production, indicating that the use of hydraulic fractures is preferable in low-permeability reservoirs. Also, increasing the hydraulic fracture number can improve the overall gas production efficiency, while the average gas production efficiency from individual fractures is decreased.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Numerical Investigation of the Gas Production Efficiency and Induced Geomechanical Responses in Marine Methane Hydrate-Bearing Sediments Exploited by Depressurization through Hydraulic Fractures

Guo

Jin

et al. 2021

Energy Fuels

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“…Depressurization is also restricted by potential geohazards such as severe sand production [14][15][16], wellbore instability [17], and deformation of the sediment [18,19]. These potential geohazards are mainly controlled by the mechanical properties of HBS [20,21].…”

Section: Introductionmentioning

confidence: 99%

Laboratory Study on Hydrate Production Using a Slow, Multistage Depressurization Strategy

et al. 2021

Geofluids

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Optimization of the depressurization pathways plays a crucial role in avoiding potential geohazards while increasing hydrate production efficiency. In this study, methane hydrate was formed in a flexible plastic vessel and then gas production processes were conducted at constant confining pressure and constant confining temperature. The CMG-STARS simulator was applied to match the experimental gas production behavior and to derive the hydrate intrinsic dissociation constant. Secondly, fluid production behavior, pressure-temperature ( P ‐ T ) responses, and hydrate saturation evolution behaviors under different depressurization pathways were analyzed. The results show that integrated gas-water ratio (IGWR) decreases linearly with the increase in depressurizing magnitude in each step, while it rises logarithmically with the increase in the number of steps. Under the same initial average hydrate saturation and the same total pressure-drop magnitude, a slow and multistage depressurization strategy would help to increase the IGWR and avoid severe temperature drop. The pore pressure rebounds logarithmically once the gas production is suspended, and would decrease to the regular level instantaneously once the shut-in operation is ended. We speculate that the shut-in operation could barely affect the IGWR and formation P ‐ T response in the long-term level.

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“…Li et al and Cao et al believe that the secondary formation of hydrates and clay accumulation on the sand control medium are the key to clogging [14,15]. They suggested that a sand-control gravel sizing method called "Holding Coarse Expelling Fine Particles (HCEFP)" and artificial interference of downhole temperature was proposed to tackle the problems caused by possible screen clogging [16,17]. Uchida et al establish thermohydromechanically coupled formulation to research the features of sand production in gas hydrate-bearing sediments.…”

Section: Introductionmentioning

confidence: 99%

Study on the Influence of Sand Production on Seepage Capacity in Natural Gas Hydrate Reservoirs

et al. 2021

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Sand production has become a common phenomenon in the exploitation of unconsolidated natural gas hydrate reservoirs, which will hinder the long-term production of natural gas hydrate reservoirs. However, there are few literatures reported on the influences in reservoir physical properties such as permeability and porosity, and production laws caused by sand production. This paper provides a numerical model, coupled with reservoir sand-gas-water multiphase flow processes, which is capable to simulate the process of sand production in natural gas hydrate reservoirs. The simulation results indicate that sand settlement is mainly concentrated near the wellbore due to the high concentration of migrated sand. The decrease in reservoir porosity and permeability caused by sand settlement has a significant impact on production. The impact of sand production on reservoir fluid fluidity shows that fluid flow is inhibited near the wellbore, while fluid flow performance increases far away from the wellbore. The numerical model and analysis presented here could provide useful insight into changes in reservoir physical properties and production laws caused by sand production in the natural gas hydrate-bearing marine sediments using depressurization method.

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Protocol for sand control screen design of production wells for clayey silt hydrate reservoirs: A case study

Cited by 36 publications

References 35 publications

Numerical Investigation of the Gas Production Efficiency and Induced Geomechanical Responses in Marine Methane Hydrate-Bearing Sediments Exploited by Depressurization through Hydraulic Fractures

Numerical Investigation of the Gas Production Efficiency and Induced Geomechanical Responses in Marine Methane Hydrate-Bearing Sediments Exploited by Depressurization through Hydraulic Fractures

Laboratory Study on Hydrate Production Using a Slow, Multistage Depressurization Strategy

Study on the Influence of Sand Production on Seepage Capacity in Natural Gas Hydrate Reservoirs

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