Experimental Investigation of Cryogenic Fracturing of Rock Specimens Under True Triaxial Confining Stresses

Alqatahni, Naif B.; Cha, Min-Seok; Yao, Bowen; Yin, Xiaolong; Kneafsey, Timothy J.; Wang, Lei; Wu, Yu‐Shu; Miskimins, Jennifer

doi:10.2118/180071-ms

Cited by 36 publications

(20 citation statements)

References 21 publications

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“…According to the borehole pressure when the samples were fractured, CO 2 in the borehole could be either in supercritical or gas state. After post-injection characterization, dye solution was injected at low pressure to color the induced fractures (Yao et al 2017) and finally the samples were broken down by gas fracturing under tri-axial stresses to disclose the induced fracture planes (Alqahtani et al 2016). For each shale sample, the experimental procedures slightly varied but generally followed:…”

Section: Methodsmentioning

confidence: 99%

CO2 injection-induced fracturing in naturally fractured shale rocks

Wang

Yao

Xie

et al. 2017

Energy

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Niobrara shale cubes of 20 cm from Colorado were employed to investigate gas and supercritical CO 2 injection-induced fracturing in naturally fractured caprocks of deep aquifers/depleted reservoirs and fractured shale reservoirs. Under tri-axial stresses, gas or supercritical CO 2 was injected into the center of the cubes to induce fracturing. Real-time pressure and temperature, acoustic wave, pressure decay, fracture coloring, and gas fracturing were used to characterize the fracturing process and fracture morphology. Without pore pressure, CO 2 injection-induced fracturing occurred and completed instantly, accompanied by an evident temperature drop. Strongly bonded fractures barely affected transverse fracture propagation, whereas weakly bonded or open fractures arrested the injected fluid first and then allowed it to generate new fractures perpendicular to the minimum horizontal stress. Breakdown pressures for cubes with preexisting fractures using gas and supercritical CO 2 are much lower than both poroelastic predictions and slick-water fracturing pressure, and some are even lower than the minimum horizontal stress. This is attributed to unconformable preexisting fractures and the low viscosity of CO 2. Moreover, decreasing tri-axial stress levels and increasing stress differences tend to lower the breakdown pressure. This study is instructive for understanding and tackling geomechanical issues related to CO 2 geological storage and fracturing of shale reservoirs.

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Section: Methodsmentioning

confidence: 99%

CO2 injection-induced fracturing in naturally fractured shale rocks

Wang

Yao

Xie

et al. 2017

Energy

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“…It was found that specimen temperature and confining stress play noticeable roles in pressure decay results. Detailed pressure decay results and analysis are reported in Alqatahni et al (2016). The pressure decay results allow only relative, qualitative comparisons.…”

Section: Acoustic Wavesmentioning

confidence: 99%

Laboratory system for studying cryogenic thermal rock fracturing for well stimulation

Cha

Alqahtani

Yin

et al. 2017

Journal of Petroleum Science and Engineering

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Highlights• A laboratory system for cryogenic fracturing under true-triaxial loading is developed.• Cryogen is flown through boreholes by a coaxial assembly under controlled pressure.• Designs for physical parameter measurements at cryogenic temperatures are optimized.• Acoustic, pressure decay, and breakdown tests effectively capture cryogenic fractures.• Data shows the laboratory design works adequately for cryogenic stimulation studies. AbstractThe concept of cryogenic fracturing is that a sharp thermal gradient developed by applying a cryogenic fluid on a rock surface causes a strong local tensile stressthat initiates fractures. Prior field tests suggest that field application with special equipment rated for cryogenic temperatures may deliver potential benefits. The tests did not, however, identify the fracture mechanisms at work in downhole conditions. In this study, we present our laboratory designs and procedures developed for studying cryogenic fracturing mechanisms in a well environment, and examine typical data indicative of the performance of the system. The experimental apparatus and procedures were specifically designed to conduct cryogenic fracturing tests in specimens under confining stress, with integrated cryogen transport, measurements, and fracture characterization.A true-triaxial loading system was built to simulate reservoir stress levels and anisotropic stress application, and was designed to avoid thermal stresses in tests involving cryogen by arranging discrete components in an open chamber. To maximize thermal shock on the wellbore surface, tubing and wellhead are configured so that liquid nitrogen enters the borehole and flow out after contributing to thermal shock.The temperature at boreholes and along flow lines, borehole pressure, and liquid nitrogen consumption are monitored throughout treatments. Acoustic transmission and pressure-decay measurements are used to characterize fractures before and after the experiments. Breakdown tests performed on un-stimulated specimens and stimulated specimens compare breakdown pressures of the two groups and thus evaluate the performance of thermal fracturing. The laboratory design was able to effectively apply cryogenic stimulations to laboratory rock specimens. The characterization methods were able to capture fracture creation and rock property changes due to cryogenic fracturing. KeywordsCryogenic rock fracturing Thermal shock Well stimulation Laboratory developmentShale and tight gas reservoirs

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“…under the same stresses as S1 unexpectedly broke down during LN 2 treatment, after which the pressure decay only built up to 168 psi. More details of these cases can be found in the studies of Alqahtani (2015) and Alqahtani et al (2016).…”

Section: Breakdown Pressure and Fracture Profilementioning

confidence: 99%

Waterless fracturing technologies for unconventional reservoirs-opportunities for liquid nitrogen

Wang

Yao

Cha

et al. 2016

Journal of Natural Gas Science and Engineering

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During the past two decades, hydraulic fracturing has significantly improved oil and gas production from shale and tight sandstone reservoirs in the United States and elsewhere.Considering formation damage, water consumption, and environmental impacts associated with water-based fracturing fluids, efforts have been devoted to developing waterless fracturing technologies because of their potential to alleviate these issues. Herein, key theories and features of waterless fracturing technologies, including Oil-based and CO 2 energized oil fracturing, explosive and propellant fracturing, gelled LPG and alcohol fracturing, gas fracturing, CO 2 fracturing, and cryogenic fracturing, are reviewed. We then experimentally elaborate on the efficacy of liquid nitrogen in enhancing fracture initiation and propagation in concrete samples, and shale and sandstone reservoir rocks. In our laboratory study, cryogenic fractures generated were qualitatively and quantitatively characterized by pressure decay tests, acoustic measurements, gas fracturing, and CT scans. The capacity and applicability of cryogenic fracturing using liquid nitrogen are demonstrated and examined. By properly formulating the technical procedures for field implementation, cryogenic fracturing using liquid nitrogen could be an advantageous option for fracturing unconventional reservoirs.

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Experimental Investigation of Cryogenic Fracturing of Rock Specimens Under True Triaxial Confining Stresses

Cited by 36 publications

References 21 publications

CO2 injection-induced fracturing in naturally fractured shale rocks

CO2 injection-induced fracturing in naturally fractured shale rocks

Laboratory system for studying cryogenic thermal rock fracturing for well stimulation

Waterless fracturing technologies for unconventional reservoirs-opportunities for liquid nitrogen

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