Dynamic Interference Behaviors of Arbitrary Multilayer Commingling Production in Heavy Oil Reservoirs with Water Flooding

Xu, Jiafeng; Xue-zhi, HU; Ning, Bo

doi:10.1021/acsomega.0c06154

Cited by 6 publications

(2 citation statements)

References 15 publications

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“…30 Xu et al derived a mathematical model for oil and water co-production from an arbitrary multilayer. 31 Zhou et al evaluated interlayer interference during the co-production process in an offshore oilfield through a theoretical model considering reservoir heterogeneity and two-phase flow. 32 Chai et al conducted a series of numerical simulations on gas production from multilayer tight sandstone reservoirs and investigated the influence of interlayer interference and production rate.…”

Section: Introductionmentioning

confidence: 99%

“…Mastbaum et al proposed a method for testing the two-phase flow capacity in two-layer reservoirs in the Laplace domain by analytical solutions of well pressure responses . Xu et al derived a mathematical model for oil and water co-production from an arbitrary multilayer . Zhou et al evaluated interlayer interference during the co-production process in an offshore oilfield through a theoretical model considering reservoir heterogeneity and two-phase flow .…”

Section: Introductionmentioning

confidence: 99%

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Impact of Crossflow and Two-Phase Flow on Gas Production from Stacked Deposits

et al. 2023

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The gas production from stacked gas deposits with coalbed, shale, and tight sandstone reservoirs in the coal measure is an effective new technology to enhance per well gas production. However, previously developed numerical models for stacked gas deposits usually target one or two reservoir types. The contribution and impact mechanism of crossflow and two-phase flow on gas production from stacked gas deposits are unclear for the stacked gas deposits with coalbed, shale, and tight sandstone reservoirs in the coal measure. This paper develops a numerical simulation model for the gas production from stacked deposits with shale, coalbed, and tight sandstone reservoirs. This numerical simulation model considers the two-phase flow, gas diffusion in different porosity, pore deformation, and interlayer crossflow. After verification with available data from the literature, this numerical simulation model is used to explore the effects of crossflow across interlayers and two-phase flow on gas transport and production efficiency. The simulation results show that the main sources of gas production from stacked deposits are shale and coalbed reservoirs. The gas in these two reservoirs can be rapidly transported to the wellbore through the tight sandstone reservoir. The gas production from stacked deposits will be underestimated without the interlayer crossflow and overestimated if the two-phase flow is ignored. The gas production efficiency can be effectively improved through the enhancement of the crossflow rate at the interlayer and the decrease of the water saturation in the reservoir.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%