Fracture closure modes during flowback from hydraulic fractures

Taleghani, Arash Dahi; Cai, Yuzhe; Pouya, Ahmad

doi:10.1002/nag.3086

Cited by 16 publications

(3 citation statements)

References 11 publications

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“…In future works, the fracture network will be verified in the tight oil reservoir by microseism or fiber optic testing, and the discrete fracture model (DFM) or the embedded discrete fracture model (EDFM) will be employed to treat the fracture network when meaningful field data can be obtained [41,42]. In addition, after hydraulic fracturing, the fracturing liquid cannot flow back totally; hence, in the early flow period, the fluid flow should be a two-phase flow, which would affect the transient pressure performance in new models [43,44].…”

Section: Discussionmentioning

confidence: 99%

Transient Pressure Performance Analysis of Hydraulically Fractured Horizontal Well in Tight Oil Reservoir

Sun,

Fang,

Fan

et al. 2024

Energies

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Utilizing the discrete fracture model (DFM), a transient flow model is established for fractured horizontal wells in tight oil reservoirs, accounting for threshold pressure gradient (TPG), stress sensitivity effect, hydraulic fracture parameters, and fracture distribution pattern. This model is solved using the finite-volume method (FVM), and an important sensitivity analysis is conducted. The findings reveal that the models incorporated by the threshold pressure gradient result in an upward trend in the pressure-derivative curve. As the threshold pressure gradient increases, this upward trend becomes more pronounced, rendering the distinction between flow regimes more challenging. The stress sensitivity effect predominantly impacts the pressure-derivative curve during the later flow period. Additionally, as the fracture half-length increases, the pressure performance of both fracture radial flow and formation radial flow becomes more difficult. Fracture conductivity has a significant influence during the early flow period, facilitating the identification of flow regimes with the trend of increasing fracture conductivity.

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Section: Discussionmentioning

confidence: 99%

Transient Pressure Performance Analysis of Hydraulically Fractured Horizontal Well in Tight Oil Reservoir

Sun,

Fang,

Fan

et al. 2024

Energies

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“…Hydraulic fracturing is a well stimulation technology that is effective in increasing hydrocarbon production in unconventional reservoirs such as shale gas, coal-bed methane, and tight sandstone (Montgomery and Smith, 2010; Dahi Taleghani et al, 2020; Wang et al, 2020b). A large volume of viscous fluid is continuously injected into such a formation to promote hydraulic fracture propagation, which occurs at a depth of several thousand metres and accordingly cannot be directly observed.…”

Section: Introductionmentioning

confidence: 99%

Complex Fracture Closure Pressure Analysis During Shut-in: A Numerical Study

Wang

et al. 2022

Energy Exploration & Exploitation

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Conventional fracture closure models typically assume homogeneous formation. This assumption renders complex fracture closure pressure analysis during shut-in insufficient at present. In this paper, we use a cohesive zone method (CZM)-based finite element model to obtain the fracture closure pressure and minimum horizontal principal stress of the major fracture and the branch fracture based on pressure fall-off analysis. Key factors including leak-off rate, injection time, and stress anisotropy are discussed in detail. A quantitative relationship between fracture closure pressure and these factors is plotted to reduce or eliminate the errors caused by conventional fracture injection diagnostic models. The results show that leak-off rate, injection time, and stress anisotropy have a significant effect on the fracture closure process. Fracture closure in naturally fractured formations is a slow process, and the early closure pressure represents the closure of the branch fracture, which is much higher than the minimum horizontal stress. This investigation provides new insight into how to estimate the in-situ stress in naturally fractured reservoirs.

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“…Unconventional reservoirs such as shale have extremely low permeability. The function of hydraulic fractures will be undermined (e.g., fracture closure) after a long-term production, which will lead to a decline in oil and gas production [1,2]. Correspondingly, it is difficult to achieve the economic and efficient development of shale oil and gas resources.…”

Section: Introductionmentioning

confidence: 99%

Experimental Investigation of the Growth Law of Multi-Fracture during Temporary Plugging Fracturing within a Stage of Multi-Cluster in a Horizontal Well

Zhang

Zou

2022

Processes

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Temporary plugging fracturing in a horizontal well with multi-stages and multi-clusters is usually used to improve stimulation efficiency and increase the gas production from shale gas reservoirs. However, the fracture propagation geometry and the mechanism of temporary plugging are still unclear, which restricts the further optimization of temporary plugging fracturing scheme. In this study, taking the Longmaxi shale as the research object and considering the intrafracture and intrastage temporary plugging, the true tri-axial hydraulic fracturing system was used to put forward an experimental method for simulating the temporary plugging fracturing in a horizontal well with multi-stages and multi-clusters. Afterward, the effects of the size combination and concentration of temporary plugging agents and the cluster number in a stage on the fracture geometry created in the secondary fracturing were investigated in detail. The results show that an optimal fracture propagation geometry tends to be obtained by using the combinations of 100 to 20/70 mesh, and 20/70 to 10~18 mesh temporary plugging agents for the intrafracture and intrastage temporary plugging, respectively. Increasing the proportion of the temporary plugging agent of a larger particle size can improve the effectiveness of intrafracture and intrastage temporary plugging fracturing, and tends to open new fractures. With the increase in temporary plugging agent concentration and the cluster number within a stage, both the number of diverting fractures formed and the overall complexity of fractures tend to increase. After fracturing, the rock specimen with a high peak in the temporary plugging pressure curve has more transverse fractures, indicating a desirable diversion effect. By contrast, the fractured rock specimen with a low peak pressure has no transverse fracture, generally with fewer fractures and poor diversion effect.

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Fracture closure modes during flowback from hydraulic fractures

Cited by 16 publications

References 11 publications

Transient Pressure Performance Analysis of Hydraulically Fractured Horizontal Well in Tight Oil Reservoir

Transient Pressure Performance Analysis of Hydraulically Fractured Horizontal Well in Tight Oil Reservoir

Complex Fracture Closure Pressure Analysis During Shut-in: A Numerical Study

Experimental Investigation of the Growth Law of Multi-Fracture during Temporary Plugging Fracturing within a Stage of Multi-Cluster in a Horizontal Well

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