Frictional stability of Longmaxi shale gouges and its implication for deep seismic potential in the southeastern Sichuan Basin

Zhang, Feng-Shou; Cui, Li; An, Mengke; Elsworth, Derek; He, Chuansong

doi:10.1002/dug2.12013

Cited by 19 publications

(8 citation statements)

References 52 publications

(76 reference statements)

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“…Therefore, it was beneficial to the geological storage of mine water in the basin-scale for the Ordos basin, but the renaissance of induced seismicity should be avoided [ 73 ]. The high frequency of water injection often induced the seismic activities around wells and was analogous to faults re-activation seismic in the gas extraction [ 74 ].…”

Section: Resultsmentioning

confidence: 99%

Deep Groundwater Flow Patterns Induced by Mine Water Injection Activity

Chen

Rudakov

et al. 2022

IJERPH

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Mine water injection into deep formations is one of the effective approaches for reducing the drainage from coal mines in the arid and semi-arid region of the Ordos basin, China. Many coal mines are attempting to execute the related projects. Under the influence of groundwater protection, the understanding of regional groundwater flow is becoming highly important to the mine water monitoring, whereas quite few academic research teams focus on the deep groundwater flow pattern by mine water injection. This paper reveals the spatial distribution of Liujiagou Formation that is in positive correlation with the terrain, and its local thickness is influenced by the dominant W-E and NE-SW directions of geological structures. Only a part of sandstone rocks consists of aquifers, the rest 61.9% of relatively dry rock provide the enhanced storage space and partial mudstone aquicludes decrease the possibility of the vertical leakage for mine water. The dynamic storage capacity is evaluated at 2.36 Mm3 per 1 km2 and over 25.10 billion m3 in this study area. Two hydrogeologic cross-sections of basin-scale identify the W-E and N-S regional groundwater flow directions, with the lower Yellow River catchment becoming the discharged region. The hierarchically and steadily nested flow systems containing coal mining claims are influenced by coal mining activity. The groundwater depression cone in a shallow coal measure aquifer is caused by mine water drainage whereas the groundwater mound in Liujiagou Formation is generated by mine water injection activity. The numerical simulation revealed that the groundwater head rebound is slightly decreased and will not recover to its initial baseline within 500 years due to its low porosity and permeability. This study elucidates the deep groundwater flow patterns induced by mine water injection and provides a practical methodology for the management and pollution monitoring of mine water injection activity.

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Section: Resultsmentioning

confidence: 99%

Deep Groundwater Flow Patterns Induced by Mine Water Injection Activity

Chen

Rudakov

et al. 2022

IJERPH

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“…These three types of reservoirs alternate in the vertical direction and have multiple distribution forms. , A typical distribution of multilayer reservoirs in the coal measure is shown in Figure , in the order of shale, coalbed, and tight sandstone reservoir. The interlayer is generally a low-permeability layer, such as mudstones, and its permeability is much smaller than that of gas reservoirs.…”

Section: Crossflow Model For Gas and Water Flow At The Interlayermentioning

confidence: 99%

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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“…As shown in Figure 2(b), the radial stress (σ rr ) is always one of the principal stresses, owing to it being always perpendicular to the wall of the wellbore, and the other two principal stresses must be within the plane of wellbore (θ, z b ). Therefore, according to material mechanics, both normal and shear stress within the plane of wellbore (θ, z b ) can be expressed as σ = σ θθ cos 2 γ + 2τ θz cos γ sin γ + σ zz sin 2 3 Geofluids Take the first derivative of σ with respect to γ to be zero, so that the direction of the major and minor principal stresses can be determined, and applying the Biot effective stress law (σ ′ = σ − αp p ), the effective principal stresses (EPSs) can be written as [21]…”

Section: Stress Components On the Wall Of Inclined Wellborementioning

confidence: 99%

“…In recent years, unconventional petroleum reservoirs are receiving increasing attentions [1], particularly, shale reservoir [2], tight-sand reservoir [3], and coalbed methane reservoir [4]. Owing to advances in directional drilling technologies, directional, horizontal, and extended-reach wells are widely employed to develop these unconventional petro-leum reservoirs [5,6].…”

Section: Introductionmentioning

confidence: 99%

Analytical Model of Wellbore Stability Analysis of Inclined Well Based on the Advantageous Synergy among the Five Strength Criteria

Shi

Zhang

et al. 2023

Geofluids

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The proper drilling mud density is vital for wellbore stability maintenance, which relies on both stress distribution on the borehole wall and rock strength. Thus, the selection of rock strength criterion is vital for wellbore stability analysis (WSA), and several strength criteria have been developed and employed to perform WSA, but the real collapse pressure does not comply with any single strength criterion. Therefore, to accurately predict the critical mud weight against wellbore collapse, an analytical model of WSA was proposed for inclined wells based on the advantageous synergy among the five types of strength criteria, such as the Mohr-Coulomb criterion, Mogi-Coulomb criterion, Drucker-Prager criterion, modified Wiebols-Cook criterion, and modified Lade criterion. The predicted results among these analytical and five conventional models were compared under three kinds of typical stress regimes, such as normal, strike-slip, and reverse faults. Finally, five kinds of typical oil and gas field data were collected to further verify the accuracy of this new model. The results indicated that different models predicted different collapse pressure, owing to the Mohr-Coulomb criterion ignoring the intermediate principal stress ( σ 2 ), so as to always give the greatest collapse pressure, followed by the present analytical model and the Mogi-Coulomb criterion, while the other three types of strength criteria gave different results, because of the difference in the influence of σ 2 , while the present analytical model integrated the advantageous synergy among the five strength criteria. The prediction error of the conventional analytical model ranges from 9.4 to 34.2% with an average of 22.1%, while the prediction error of this new model ranges from 2.3 to 12.5% with an average of 7.1%, so that the present analytical model has much higher accuracy than that of any single strength criterion. In addition, this new analytical model can be simplified as the conventional analytical model by adjusting the weight coefficients.

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Frictional stability of Longmaxi shale gouges and its implication for deep seismic potential in the southeastern Sichuan Basin

Cited by 19 publications

References 52 publications

Deep Groundwater Flow Patterns Induced by Mine Water Injection Activity

Deep Groundwater Flow Patterns Induced by Mine Water Injection Activity

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

Analytical Model of Wellbore Stability Analysis of Inclined Well Based on the Advantageous Synergy among the Five Strength Criteria

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