Mechanical Behavior of Hydrate-Bearing Clayey-Silty Sediments in the South China Sea: Strain-Rate Dependency

Li, Yanghui; Hao, Yun; Wu, Peng; Hu, Wenkang; Song, Yongchen

doi:10.1021/acs.energyfuels.4c00399

Cited by 2 publications

(1 citation statement)

References 80 publications

(116 reference statements)

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“…In offshore HBS with mudstone and siltstone lithologies and weak cementation, the stress–strain curve often shows strain-hardening behavior without a distinct peak stress. The failure strength is defined as the deviator stress at an axial strain of 15%, typically not exceeding 20 MPa. − Consequently, heat generation powder has significant potential to induce secondary cracks in weakly cemented, low-strength HBSs, enhancing the permeability of the decomposition zone during NGH exploitation.…”

Section: Resultsmentioning

confidence: 99%

Feasibility Analysis on Hydrate Exploitation by Heat Generation Powders Thermal Stimulation

Zhang,

Ji,

Yang

et al. 2024

Energy Fuels

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A rigorous study was conducted to assess the potential of a novel “in situ heat generation method using heat generation powders” for natural gas hydrate (NGH) exploitation. This method was evaluated based on its ability to accelerate NGH decomposition through efficient heating. The experiment meticulously examined the impact of heat generation powders thermal stimulation (HPTS) on gas extraction from hydrate-bearing sediments (HBSs) at temperatures of 14 and 8 °C. Key parameters, such as gas production, temperature variations, energy efficiency, and thermal efficiency, were closely monitored throughout the NGH exploitation process. The study documented the cementation of HBS, where hydration products bonded loose sand grains after hydrate decomposition. Additionally, it provided a comprehensive overview of the five major mechanisms of heat generation powders: in situ heat supply, high expansion force, cementation, porosity enhancement, and increased pore volume. Gas production was feasible at both 14 and 8 °C, with the in situ hydration reaction at 14 °C demonstrating greater intensity, leading to higher average gas production rates, rapid cementation of loose sand grains, and reduced hydration and exploitation durations. HPTS effectively mitigated temperature disturbances, fostering a safer and more stable environment for NGH exploitation. Notably, the energy efficiency (η) and thermal efficiency (ξ) of HPTS surpassed those of traditional thermal stimulation methods at both HBS temperatures. At 8 °C, HPTS exhibited superior η and ξ, reaching values of 13.255 and 0.8109, respectively, thus offering substantial advantages over conventional methods. Post-experiment observations revealed that hydration products facilitated the cementation of all loose sand particles in Reservoir 1 and a portion in Reservoir 2, forming visually striking cemented cores. The findings underscored HPTS’s ability to deliver favorable gas production, improved heat transfer, and exceptional HBS cementation. With three hydration heat regulation methods, the hydration heat for heating the reservoir skeleton is expected to be further reduced, increasing the proportion of hydration heat consumed in hydrate decomposition, thereby enhancing heat utilization efficiency and achieving higher η. In conclusion, the HPTS method demonstrates significant promise at HBS temperatures of 14 and 8 °C, with the potential to drive sustainable development and foster environmentally friendly production practices.

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Section: Resultsmentioning

confidence: 99%

Feasibility Analysis on Hydrate Exploitation by Heat Generation Powders Thermal Stimulation

Zhang,

Ji,

Yang

et al. 2024

Energy Fuels

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Investigation of methane gas bubble dynamics and hydrate film growth during hydrate formation using 4-D time-lapse synchrotron X-ray computed tomography

Khan,

Sahoo,

Falcon-Suarez

et al. 2024

Front. Earth Sci.

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We present a time-lapse 4-D high-resolution synchrotron imaging study of the morphological evolution of methane gas bubbles and hydrate film growth on these bubbles. Methane gas and partially water-saturated sand were used to form hydrate with a maximum hydrate saturation of 60%. We investigated the transient evolution of gas bubble size distribution during hydrate formation and observed three distinct stages: a) nucleation and hydrate film formation, b) rapid bubble break-up, c) gas bubble coalescence and hydrate framework formation. Our results show that the average gas bubble size distribution decreases from 34.17 µm (during hydrate nucleation) to 8.87 µm (during secondary bubble formation). The small-size methane bubble population (mean diameter below 10 µm) initially increases at the expense of the larger methane bubble population (mean diameter above 50 µm) due to breakage of the larger bubbles and coalescence of the smaller bubbles. We quantified that the average hydrate film thickness increases from 3.51 to 14.7 µm by tracking the evolution of a particular gas bubble. This thickness increase agrees with an analytical model with an average deviation error of 3.3%. This study provides insights into gas bubble distribution and hydrate film growth during hydrate formation, both of which impact the geophysical and mechanical properties of hydrate-bearing sediments.

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Mechanical Behavior of Hydrate-Bearing Clayey-Silty Sediments in the South China Sea: Strain-Rate Dependency

Cited by 2 publications

References 80 publications

Feasibility Analysis on Hydrate Exploitation by Heat Generation Powders Thermal Stimulation

Feasibility Analysis on Hydrate Exploitation by Heat Generation Powders Thermal Stimulation

Investigation of methane gas bubble dynamics and hydrate film growth during hydrate formation using 4-D time-lapse synchrotron X-ray computed tomography

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