Experimental Investigation of Stress Sensitivity of Elastic Wave Velocities for Anisotropic Shale in Wufeng–Longmaxi Formation

Feng, Yutian; Tang, Hongming; Tang, Haoxuan; Leng, Yijiang; Shi, Xuewen; Liu, Jia

doi:10.3390/pr11092607

Cited by 3 publications

(2 citation statements)

References 53 publications

(68 reference statements)

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“…However, in the construction of these models, the uncertainty associated with their parameters is often reduced to enhance their predictive capabilities and practical applicability. When implementing these models in real-world scenarios, it is advisable to account for parameter uncertainty to ensure a more precise and dependable analysis [15][16][17].…”

Section: Introductionmentioning

confidence: 99%

Risk Assessment Method for Analyzing Borehole Instability Considering Formation Heterogeneity

Gao,

Wang,

Shi

et al. 2023

Processes

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In the study of borehole instability, the majority of input parameters often rely on the average values that are treated as fixed values. However, in practical engineering scenarios, these input parameters are often accompanied by a high degree of uncertainty. To address this limitation, this paper establishes a borehole stability model considering the uncertainty of input parameters, adopts the Monte Carlo method to calculate the borehole stability reliability at different drilling fluid densities, evaluates the sensitivity of borehole instability to a single parameter, and studies the safe drilling fluid density window at different borehole stability reliability values under multi-parameter uncertainties. The results show that the uncertainty of rock cohesion has a great influence on the fracture pressure of the vertical and horizontal wells. The minimum horizontal stress has the greatest influence on the fracture pressure of the vertical and horizontal wells, followed by pore pressure. In the analysis of borehole stability, the accuracy of cohesion and minimum horizontal stress parameters should be improved. In scenarios involving multiple parameter uncertainties, while the overall trend of the analysis results remains consistent with the conventional borehole stability outcomes, there is a noteworthy narrowing of the safe drilling fluid density window. This suggests that relying on conventional borehole stability analysis methods for designing the safe drilling fluid density window can considerably increase the risks of borehole instability. Uncertainty assessment is crucial to determine the uncertainties associated with the minimum required mud pressure, thereby ensuring more informed decision-making during drilling operations. To meet practical application demands, structure and boundary condition uncertainties should be implemented for a more comprehensive assessment of borehole stability.

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Section: Introductionmentioning

confidence: 99%

Risk Assessment Method for Analyzing Borehole Instability Considering Formation Heterogeneity

Gao,

Wang,

Shi

et al. 2023

Processes

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“…Therefore, when calibrating f for HDWS specimens, it is not enough to consider only the effect of geometrical parameters on f for the specimen; the influence of anisotropic elastic parameters of the material on f must also be considered [27]. In actual engineering projects and scientific research, shale is often considered a transversely anisotropic material [28] with a symmetry axis perpendicular to the sedimentary plane [29]. For laminated rock, the bedding orientation is a key factor affecting the test results of SIF and f. In threedimensional space, three typical bedding orientations, namely, arrester (A), divider (D), and short-transverse (ST) [30,31], are often studied.…”

Section: Introductionmentioning

confidence: 99%

Fracture Toughness Testing of Brittle Laminated Geomaterials Using Hollow Double-Wing Slotted Specimens

Yao,

Fan,

Zhou

et al. 2023

Materials

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The fracture toughness of shale is a key parameter guiding hydraulic fracturing design and optimization. The hollow double-wing slotted (HDWS) specimen is a typical specimen configuration for measuring the mode I fracture toughness of rock. The calibration of the shape factor (f) is the basis for accurately obtaining the fracture toughness of rocks. In this study, the influences of crack length, hole size, and the anisotropy of elastic parameters on f for specimens with three typical bedding orientations—arrester (A), divider (D), and short-transverse (ST) orientations—are systematically investigated using finite element software. The numerical simulation results support the following findings. The mode I f increases monotonically with an increase in hole size. The influence of crack length on f varies depending on hole sizes. Under different bedding orientations, significant anisotropy in f was observed. In addition, the degree of anisotropy in Young’s modulus has a major impact on f, which is related to the bedding orientation of the specimen. The apparent shear modulus ratio has relatively little influence on f. As the hole size and crack length increase, the influence of the anisotropy of elastic parameters on f increases. Based on numerical calculations, hydraulic fracturing experiments were conducted on HDWS specimens of Longmaxi shale with three bedding orientations, and the results showed that the peak pressure and fracture toughness of the samples in the ST direction were the lowest, while those in the A direction were the highest.

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DEM Analysis of the P-Wave Anisotropy Response to the Microstructure of Sedimentary Rock Under Biaxial Compression

Zheng,

Zhang,

Liu

et al. 2024

Rock Mech Rock Eng

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Experimental Investigation of Stress Sensitivity of Elastic Wave Velocities for Anisotropic Shale in Wufeng–Longmaxi Formation

Cited by 3 publications

References 53 publications

Risk Assessment Method for Analyzing Borehole Instability Considering Formation Heterogeneity

Risk Assessment Method for Analyzing Borehole Instability Considering Formation Heterogeneity

Fracture Toughness Testing of Brittle Laminated Geomaterials Using Hollow Double-Wing Slotted Specimens

DEM Analysis of the P-Wave Anisotropy Response to the Microstructure of Sedimentary Rock Under Biaxial Compression

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