Experimental Study on the Gas Permeability of Marine Sediments with Various Hydrate Saturations and Effective Stresses

Natural gas hydrate is a promising clean and efficient energy source, but reformation during mining can impede commercial utilization. The impact of gas flow on hydrate reformation and reservoir seepage characteristics has not been extensively researched despite being a crucial parameter in hydrate mining processes. This study employs a core holder to simulate the formation and dissociation of hydrate in clayey silt sediments from the South China Sea (SCS). Differential gas pressure gradients were manipulated to simulate reformation under varying gas flow conditions, during which the water content and pore distribution were quantified with a low-field nuclear magnetic resonance (NMR) spectrometer. Meanwhile, the gas permeabilities k(S h) concerning different hydrate saturation (S h) were measured under constant effective stress. Results indicated that gas flow effectively enhances hydrate reformation, resulting in an increase of the maximum hydrate saturation from 9.44% to 21.15% and an increase of the average reformation rate from 0.15 cm3/h to 0.26 cm3/h with an escalating gas pressure differential from 0 to 1 MPa. Hydrate growth primarily occurs laterally along the gas–water interface under low saturation conditions (ΔS h < 10%), while vertical growth dominates at high hydrate saturations (ΔS h > 10%). Notably, the gas flow encourages hydrates to occupy capillaries with a smaller radius under high saturation conditions.

Section: Introductionmentioning

confidence: 99%

The Impact of Gas Flow on Hydrate Reformation and Reservoir Seepage Characteristics in Clayey Silt Sediments

Wen,

Yao,

Sun

et al. 2024

“…The results show that under unconsolidated (consolidation degree = 20%) and low effective stress (σ′ = 1.2 MPa) conditions, the gas permeability increases gradually with the decreasing methane hydrate saturation, indicating that hydrate saturation is the main factor dominating dynamic permeability at low hydrate saturation. This is crucial for understanding the permeability characteristics of hydrate sediments containing a large number of fine components in the muddy silt type. − Li et al studied the water-phase-effective permeability of silty sand soil and silty clay containing methane hydrate by the steady-state water injection method. The experimental results show that lower methane hydrate saturation also has a large effect on the absolute permeability of the water phase.…”

Section: Introductionmentioning

confidence: 99%

Experimental Study on Permeability of Methane Hydrate Clayey Interbedded Sediments Considering Effective Stress and Hydrate Dissociation

Zhou

Zhu

et al. 2023

Owing to the heterogeneity of methane hydrate reservoirs in the South China Sea, hydrate and silty clay particles mostly exist in the form of interbedded reservoirs. Permeability is a decisive factor for the efficiency of interbedded methane hydrate deposits. Therefore, using montmorillonite as the simulated sediment material, permeability measurements of interbedded sediments with different methane hydrate distributions and effective stresses were carried out for the first time in this study. By comparing with homogeneous sediments, the permeability evolution of interbedded sediments under different hydrate distributions and effective stresses is explored, and the effect of methane hydrate dissociation on the permeability of interbedded sediments is analyzed. The results show that the permeability of interbedded sediments with different hydrate saturation levels has little difference and is almost the same as that of pure soil sediments. With the increase of effective stress, the porosity of methane hydrate interbedded sediments decreases and permeability damage is caused, but the final permeability damage is less obvious than that of homogeneous hydrate sediments. In addition, the gas slip effect exists in methane hydrate interbedded sediments. Moreover, the dissociation of methane hydrate causes clay swelling, which leads to the decrease of interbedded permeability, but the degree of permeability damage is lower than that of homogeneous sediments. The results of this study provide a theoretical basis for the development and utilization of interbedded methane hydrate sediments in the South China Sea.

“…Second, NGHs have abundant reserves; conservative estimates suggest that the energy contained in NGHs is twice that of all other hydrocarbon sources. Third, NGHs possess an extremely high energy density, with one cubic unit of NGHs containing as much as 180 SCM (standard cubic meters) of gas. , Production of natural gas from NGH reservoirs requires breaking the thermodynamic equilibrium of NGHs. − However, hydrate-bearing sediment (HBS) exhibits a complex mechanical behavior due to the metastable structure of NGHs . In the exploitation of NGHs, the microstructure of HBS usually changes, such as cementation failure and local shear deformation, resulting in structural instability of the production well, seabed deformation, and even submarine landslides. , Therefore, a comprehensive mechanical study of HBS is required to ensure the safe exploitation of NGHs.…”

Section: Introductionmentioning

confidence: 99%

Effect of Hydrate Distribution on the Mechanical Response of Hydrate-Bearing Sand: Discrete Element Method Simulation

You

Sun

et al. 2022

Self Cite

Natural gas hydrates are cage-like crystalline solids that are globally recognized as a potential energy suitable for sustainable development. Hydrate distribution often affects the mechanical properties of hydrate-bearing sediments. The objective of this work is to investigate the underlying strengthening mechanisms of hydrate-bearing sediments under different hydrate distributions. The discrete element method is used to prepare numerical hydrate-bearing sediments and simulate biaxial compression tests. Hydrates are simulated as small cemented particles that are either randomly distributed or gathered filling the hydrate-free sediments. The simulation results show that at hydrate saturation of 45%, the sediment with randomly distributed hydrates exhibits higher peak strength, strain-softening and a run-through shear band, while the sediment with gathered hydrates shows higher residual strength and a cross-type shear band. Micromechanical exploration finds that many hydrate-related micro force chains are created to share the load component. In the sediment with a randomly distributed hydrate, a more stable force chain complex is formed, which is subjected to a smaller force concentration, improving the strength and stability of the sediment. As the hydrate particles gather in the sediment, the bonding forces become more concentrated and the hydrate can participate in the skeleton that contributes to the residual strength of the sediment.