Pilot-Scale Experimental Investigation of Multifield Coupling and Heterogeneity during Hydrate Dissociation

Wan, Kun; Li, Xiao-Sen; Wang, Yi; Kou, Xuan; Hu, Heng-Qi; Zhang, Yu

doi:10.1021/acs.energyfuels.1c00711

Cited by 6 publications

(3 citation statements)

References 43 publications

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“…In addition to gas storage, − gas hydrates are relevant to other sectors of the environmental and energy industry such as a cleaner energy source, ,− gas separation and carbon capture, ,− carbon sequestration, − desalination of saline water, − and cold energy storage . Gas hydrates also present a long-standing hazard to the flow assurance in oil and gas industry as they tend to cause flow blockage. − Owing to such scientific and application significances, research in gas hydrates has grown strongly over recent decades.…”

Section: Fundamental Basicsmentioning

confidence: 99%

Prospect and Challenges of Hydrate-Based Hydrogen Storage in the Low-Carbon Future

Nguyen

2023

Energy Fuels

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Hydrogen hydrate is a promising material for safe and potentially cost-effective hydrogen storage. In particular, hydrogen hydrate has potential for applications in large-scale stationary energy storage to dampen the temporal variation of renewable energy, for example, in the form of hydrogen-ready gasfired power plants for generating energy when the renewable power is not available. Preliminary SWOT (strengths, weaknesses, opportunities, threats) analysis indicates that such hydrate-based hydrogen storage (HBHS) has intrinsic competitive edges. However, while the theoretical hydrogen density of the hydrate could reach ∼5 wt %, experiments have not achieved such a high hydrogen storage capacity under practical conditions. This low gravimetric hydrogen density, plus the slow kinetics of hydrogen inclusion in the hydrate, presents an outstanding challenge for commercializing the HBHS. Future research is urged to resolve both the gaps in knowledge and technological barriers for realizing this unconventional technology. Particular future directions include the elucidation of the working mechanism of hydrate promoters, rational designs of new promoters, upscaled experiments and demonstrations, the assessment of long-term stability of hydrogen hydrates, and systematic SWOT analysis. This paper offers an insightful view of the HBHS in low-emission economies.

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Section: Fundamental Basicsmentioning

confidence: 99%

Prospect and Challenges of Hydrate-Based Hydrogen Storage in the Low-Carbon Future

Nguyen

2023

Energy Fuels

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“…Natural gas hydrate (NGH) is an ice-like crystal that can only exist steadily under conditions of high pressure and low temperature, which is naturally found in permafrost and submarine areas. , It is considered as a potential alternative clean energy for the future due to its huge reservoir. , It is also related to submarine landslide and global warming . Production of gas from NGH reservoirs has been put on the agenda of energy consumption leading countries in the world .…”

Section: Introductionmentioning

confidence: 99%

Study on the Settlement Characteristics of Hydrate Bearing Sediment Caused by Gas Production with the Depressurization Method

Li,

Wang

et al. 2024

Energy Fuels

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The settlement of the reservoir caused by gas production from the hydrate reservoir is closely related to the safety of hydrate production. However, the settlement characteristics of a hydrate reservoir under a triaxial stress state are still unclear. In this study, the settlement characteristics of hydrate-bearing sediment (HBS) during the gas production process were experimentally investigated under a triaxial stress state. Additionally, numerical simulations were performed using the thermo-hydro-chemomechanical (THMC) fully coupled model for hydrate production implemented in COMSOL Multiphysics. Results show that the failure strength of the hydrate-bearing specimen increases significantly when hydrate saturation (S h ) is raised from 0 to 0.19 and 0.37 to 0.57, and only a slight change of failure strength is observed when S h is raised from 0.19 to 0.37. The secant modulus and cohesion are positively correlated with hydrate saturation, and the internal friction angle is negatively correlated with hydrate saturation. In the gas production process, the settlement of the specimens can be divided into three stages. The first stage is characterized by rapid settling caused by free gas discharge, which has the largest settlement amount. Then, a relatively gentle settling stage is caused by hydrate decomposition. In the final stage, with continuous gas production, the settlement of specimens remains constant. A specimen with lower S h or production pressure results in a greater settlement at the first stage. A larger settlement occurs at the second stage for a high S h specimen. The confining pressure has little effect on the HBS.

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“…The hydrate dissociation efficiency is mainly related to the multiphase flow resistance . In addition, these multiphase flows will be restricted during hydrate dissociation due to the formation of secondary hydrates. , Wan et al , investigated the hydrate decomposition, heat transfer, and gas flow process of NGH exploitation in a pilot-scale hydrate simulator (PHS), which found that the multifield coupling caused the heterogeneity of hydrate dissociation. The enhancement of the NGH reservoir permeability in these placements of heterogeneity was critical for the NGH exploitation scheme.…”

Section: Introductionmentioning

confidence: 99%

Exploring Porous Flow Behavior of the Decomposed Gas from CH₄ Hydrate in Clayey Sediments by Molecular Dynamics Simulation

Yan,

Mao,

Kou

et al. 2024

Langmuir

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A fundamental understanding of the fluid flow mechanism during CH 4 hydrate dissociation in nanoscale clayey sediments from the molecular perspective can provide invaluable information for macroscale natural gas hydrate (NGH) exploration. In this work, the fluid flow behaviors of the decomposed gas from CH 4 hydrate within clayey nanopores under different temperature conditions are revealed by molecular dynamics (MD) simulation. The simulation results indicate that the key influencing factors of gas−water flow in nanoscale clayey sediments include the diffusion and the random migration of gas molecules. The influencing mechanisms of fluid flow in nanopores are closely related with the temperature conditions. Under a low temperature condition, the gas diffusion process is impeded by the secondary hydrate formation, leading to the decline in gas transport velocity within nanopores. However, it is still noteworthy that the gas−water fluid flow channels are not completely blocked by the occurrence of secondary hydrate. Under a high temperature condition, the significant phenomenon of water migration during gas flow is observed, which can be ascribed to the gas−liquid entrainment effect in nanopores of the clayey sediment. These results may provide valuable implications and fundamental evidence for improving gas production efficiency in future field tests of NGH exploitation in marine sediments.

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Pilot-Scale Experimental Investigation of Multifield Coupling and Heterogeneity during Hydrate Dissociation

Cited by 6 publications

References 43 publications

Prospect and Challenges of Hydrate-Based Hydrogen Storage in the Low-Carbon Future

Prospect and Challenges of Hydrate-Based Hydrogen Storage in the Low-Carbon Future

Study on the Settlement Characteristics of Hydrate Bearing Sediment Caused by Gas Production with the Depressurization Method

Exploring Porous Flow Behavior of the Decomposed Gas from CH₄ Hydrate in Clayey Sediments by Molecular Dynamics Simulation

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Pilot-Scale Experimental Investigation of Multifield Coupling and Heterogeneity during Hydrate Dissociation

Cited by 6 publications

References 43 publications

Prospect and Challenges of Hydrate-Based Hydrogen Storage in the Low-Carbon Future

Prospect and Challenges of Hydrate-Based Hydrogen Storage in the Low-Carbon Future

Study on the Settlement Characteristics of Hydrate Bearing Sediment Caused by Gas Production with the Depressurization Method

Exploring Porous Flow Behavior of the Decomposed Gas from CH4 Hydrate in Clayey Sediments by Molecular Dynamics Simulation

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Exploring Porous Flow Behavior of the Decomposed Gas from CH₄ Hydrate in Clayey Sediments by Molecular Dynamics Simulation