Experimental and Numerical Investigation of Characteristics of Highly Heterogeneous Rock Mechanical Responses in Tight Sandy Conglomerate Reservoir Rock Under Tri-axial Compression

Bin, Chen; Ji, Jiaqi; Lin, Jingqi; Chen, Hong‐Yuan; Wang, Xueliang; Guo, Xuyang; Yang, Wentao; Lin, Jiaying

doi:10.3389/feart.2021.735208

Cited by 11 publications

(8 citation statements)

References 33 publications

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“…For the infill zone, the 200 m well spacing results in very insignificant

S_{Hmax}

reorientations, while the 300 and 400 m well spacing scenarios lead to certain

S_{Hmax}

reorientations. Therefore, for the 300 and 400 m well spacing scenarios, a future infill well fracturing job can experience greater frictional loss within the fractures during pumping, as the likelihood of non‐planar fracture growths is higher in these cases with more reorientations in the principal stress field 34,35 . Combined with the observation in Figures 8‐10, it is estimated that, although the pore pressure is largely depleted in the infill zone, the 200 m spacing can reduce the energy required to establish infill well fracture networks.…”

Section: Effects Of Parent Well Spacing On Poroelastic Behaviors In T...mentioning

confidence: 94%

“…Log interpretations and rock mechanical tests are used to determine these mechanical properties, where typical logs such as acoustic logs, resistivity logs, and GR logs are used in the interpretation, and tri-axial tests are used for elastic property evaluation. 34,35 The permeability of the matrix is 0.047 mD with a porosity of 8. pressure values at hydraulic fractures are all equal to the depletion pressure of 25 MPa. After 12 months, pressure depletion is mainly contained in SRVs and the infill zone only has slight pressure decreases.…”

Section: Base Case Modelingmentioning

confidence: 99%

“…A tensile strength value of 10 MPa is obtained. Log interpretations and rock mechanical tests are used to determine these mechanical properties, where typical logs such as acoustic logs, resistivity logs, and GR logs are used in the interpretation, and tri‐axial tests are used for elastic property evaluation 34,35 . The permeability of the matrix is 0.047 mD with a porosity of 8.4%.…”

Section: Base Case Modelingmentioning

confidence: 99%

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Effects of parent well spacing on the poroelastic behaviors in the infill zone in shale oil reservoirs: A case study in Jimsar Shale Oil, China

Wang

Guo

Zheng³

et al. 2022

Energy Science & Engineering

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The efficient and commercial development of shale oil reservoirs often relies on the use of horizontal wells and hydraulic fracturing techniques. [1][2][3][4] Successful hydraulic fracturing operations can generate fracture networks for the increase in the contact area with the low permeability matrix. [5][6][7] Typically, tightly spaced horizontal wells that are hydraulically fractured are placed in shale oil reservoirs for better production performance. In consequence,

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“…For the infill zone, the 200 m well spacing results in very insignificant

S_{Hmax}

reorientations, while the 300 and 400 m well spacing scenarios lead to certain

S_{Hmax}

Section: Effects Of Parent Well Spacing On Poroelastic Behaviors In T...mentioning

confidence: 94%

Section: Base Case Modelingmentioning

confidence: 99%

Section: Base Case Modelingmentioning

confidence: 99%

See 1 more Smart Citation

Effects of parent well spacing on the poroelastic behaviors in the infill zone in shale oil reservoirs: A case study in Jimsar Shale Oil, China

Wang

Guo

Zheng³

et al. 2022

Energy Science & Engineering

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“…Tight oil reservoirs in this region have been commercially developed (Wang et al, 2022a;Wang et al, 2022b). The implementation of horizontal well drilling and hydraulic fracturing has largely improved the productivity here (Chen et al, 2021b;Zhi et al, 2021). Unlike tight sand reservoirs or shale reservoirs, tight conglomerate reservoirs have strong heterogeneities caused by the existence of gravels.…”

Section: Case Studymentioning

confidence: 99%

The experimental and numerical analysis of elastic rock mechanical properties in tight conglomerate rock samples: a case study in Junggar Basin

Qi,

Li,

Zhao

et al. 2024

Front. Energy Res.

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Tight conglomerate rocks consist of gravels and rock matrices. The existence of these stiff gravels leads to heterogeneity in conglomerates and makes it difficult to characterize rock mechanical properties, which then affects drilling and hydraulic fracturing operations in tight conglomerate hydrocarbon-bearing reservoirs. This case study introduces a series of experimental and numerical analyses for the better understanding of rock deformation and elastic wave propagation patterns in a tight conglomerate reservoir in Junggar Basin, China. Tri-axial compression tests, acoustic test, and finite element modeling of rock deformation and elastic wave propagation in conglomerate rocks are presented. Experimentally tested samples exhibit good brittleness and shearing failure patterns, while well correlated static-dynamic elastic moduli and P-S wave velocities are captured. Numerical results show that the existence of stiff gravels leads to strong direction-dependent stress and strain anisotropies. Stress concentrations are also induced by gravels radially and axially. In the elastic wave domain, stiff gravels facilitate the propagation of elastic waves. The gravel close to the wave source also induces stronger compressive/tensile states in the wave domain, indicating that the existence of gravels in conglomerates can alter waveforms. This integrated approach improves the quantitative understanding of stress, strain, and elastic wave responses in heterogeneous tight conglomerates. This case study also serves as a reference for the brittleness evaluation and geomechanical evaluation in the study area. The contribution of this work is primarily about the integrated experimental study, solid deformation modeling, and elastic wave modeling of tight conglomerate rocks.

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“…Experimental and numerical studies of the rock mechanical behaviors are relevant since they can help to determine the essential elastic and plastic properties of reservoir rocks. These properties are related to the hydraulic fracturing processes since they usually govern brittleness and fracability (Lecampion et al, 2018;Chen et al, 2021b;Guo et al, 2021b), and they are often correlated with the fluid flow and rock deformation behaviors in the hydrocarbon-bearing formations (Guo et al, 2023). Zhang et al (2021) proposed an experimental method to quantify the effect of loading rates and lithologies on Kaiser effects during in-situ stress measurements, where loading rate selection criteria are determined.…”

mentioning

confidence: 99%

A study of effects of different impact loads on the dynamic and elastoplastic behavior in reservoir rocks at the beginning of hydraulic fracturing

Abulimiti,

Wang,

Zang

et al. 2023

Front. Earth Sci.

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Successful hydraulic fracturing is very important in the development of hydrocarbon-bearing formations. The loading introduced by hydraulic fracturing causes deformation and failure, which are related to the damage accumulation and hydraulic fracture initiation process. This study employs a numerical model that considers the dynamic and elastoplastic behaviors in rocks under the influence of impact loads. The acceleration and wave propagation behaviors are quantified using the model. A time integration algorithm is used to ensure numerical accuracy and stability. The effects of loading rate, loading location, and heterogeneity are quantified. Results show that the elastoplastic and dynamic can effectively capture the wavy mechanical responses in the domain. Strain rate, acceleration, and plasticity can all exhibit oscillatory distribution patterns. Increasing the loading rate can magnify acceleration, strain rate, and the maximum plastic strain, while it reduces the range experiencing these induced changes. Changing the loading types and introducing the heterogeneity consideration both largely alter the mechanical response in the domain, and the waveforms of the mechanical parameters are significantly changed. Failure can occur earlier in layers with more elastic mechanical properties. Exerting 50 MPa loading in 0.01 ms can effectively introduce deformation and failures in the reservoir rock. Doubling the loading rate can effectively improve the ability of creating rock failures, which facilitates the following fracture initiation and propagation processes. This study can be a reference for the understanding of near-well and instantaneous rock mechanical behaviors at the beginning of fracturing.

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Experimental and Numerical Investigation of Characteristics of Highly Heterogeneous Rock Mechanical Responses in Tight Sandy Conglomerate Reservoir Rock Under Tri-axial Compression

Cited by 11 publications

References 33 publications

Effects of parent well spacing on the poroelastic behaviors in the infill zone in shale oil reservoirs: A case study in Jimsar Shale Oil, China

Effects of parent well spacing on the poroelastic behaviors in the infill zone in shale oil reservoirs: A case study in Jimsar Shale Oil, China

The experimental and numerical analysis of elastic rock mechanical properties in tight conglomerate rock samples: a case study in Junggar Basin

A study of effects of different impact loads on the dynamic and elastoplastic behavior in reservoir rocks at the beginning of hydraulic fracturing

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