Reduced Numerical Model for Methane Hydrate Formation under Conditions of Variable Salinity. Time-Stepping Variants and Sensitivity

Fracture-hosted methane hydrate deposits exist at many sites worldwide. The growth behavior of CH4 hydrate in fractured media was simulated by TOUGH + HYDRATE (T + H) code. The effects of fracture size, initial condition, and salinity on the growth behavior of hydrate in fractures were investigated. In general, the hydrate layer grew from the two ends and gradually covered on the surface of the fracture. With the formation of hydrate in fractures, the temperature increased sharply since the hydrate acted as a thermal insulation layer. In longer fractures, fast growth of hydrate at the ends of the fracture led to the formation of hydrate plugs with high saturation (called as stopper). In narrower fractures, hydrate dissociation occurred in the middle of the fracture during hydrate growing in the whole fracture due to the cutoff of gas supply by the stopper at the ends. At a low initial subcooling, hydrate formed both on the surface and in the micropores of the media, which was different from that at higher subcooling. In salt solution, the formation of hydrate stopper was inhibited by the salt-removing effect of hydrate formation and the growth of hydrate was more sustainable.

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The impact of mono-ethylene glycol and kinetic inhibitors on methane hydrate formation

Chemical Engineering Journal ◽

10.1016/j.cej.2021.131531 ◽

2021 ◽

pp. 131531

Author(s):

Vincent W.S. Lim ◽

Peter J. Metaxas ◽

Michael L. Johns ◽

Zachary M. Aman ◽

Eric F. May

Keyword(s):

Ethylene Glycol ◽

Methane Hydrate ◽

Hydrate Formation ◽

The Impact

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A Numerical Model of In-Channel Pebble Bed Thermal Storage for a Solar Chimney

Volume 6: Energy, Parts A and B ◽

10.1115/imece2012-88356 ◽

2012 ◽

Author(s):

Brandon Schulte ◽

O. A. Plumb

Keyword(s):

Numerical Model ◽

Present Model ◽

Thermal Storage ◽

Implicit Time ◽

Heat Transfer Characteristics ◽

Solar Chimney ◽

Pebble Bed ◽

One Dimensional ◽

Time Stepping ◽

Daily Energy

In this study, solar chimney performance is numerically modeled. Previously published models have considered water bags and natural earth as means to store daytime thermal energy for nighttime operation of the system. The present model considers in-channel pebble bed thermal storage. A one-dimensional, implicit time stepping numerical model is developed to predict solar chimney performance throughout a 24 hour period. The model is partially verified with available experimental data. The daily energy, daily efficiency and heat transfer characteristics of the solar chimney with pebble bed thermal storage are summarized. The numerical simulation showed that by introducing a pebble bed, nightly exit velocities reach 40% of the peak daytime velocity. However, the daily kinetic energy delivered by a solar chimney with pebble bed thermal storage is much less than a traditional solar chimney, suggesting pebble bed thermal storage is more practicable in building heating applications as opposed to power generation.

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Kinetic analysis of dual impellers on methane hydrate formation

International Journal of Chemical Reactor Engineering ◽

10.1515/ijcre-2020-0231 ◽

2021 ◽

Vol 0 (0) ◽

Author(s):

Sotirios Nik Longinos ◽

Mahmut Parlaktuna

Keyword(s):

Power Consumption ◽

Kinetic Analysis ◽

Induction Time ◽

Methane Hydrate ◽

Formation Rate ◽

Hydrate Formation ◽

Mixed Flow ◽

Pitched Blade Turbine ◽

Decline Rate

Abstract This study investigates the effects of types of impellers and baffles on methane hydrate formation. Induction time, water conversion to hydrates (hydrate yield), hydrate formation rate and hydrate productivity are components that were estimated. The initial hydrate formation rate is generally higher with the use of Ruston turbine (RT) with higher values 28.93 × 10−8 mol/s in RT/RT with full baffle (FB) experiment, but the decline rate of hydrate formation was also high compared to up-pumping pitched blade turbine (PBTU). Power consumption is higher also in RT/RT and PBT/RT with higher value 392,000 W in PBT/RT with no baffle (NB) experiment compared to PBT/PBT and RT/PBT experiments respectively. Induction time values are higher in RT/RT experiments compared to PBT/PBT ones. Hydrate yield is always smaller when there is no baffle in all four groups of experiments while the higher values exist in experiments with full baffle. It should be noticed that PBT is the same with PBTU, since all experiments with mixed flow have upward trending.

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