Abstract
In order to study the behavioral characteristics of the pore-scale hydrate formation, this experiment employs a high-pressure-resistant visible model in an etched glass plate to study the pore-scale methane hydrate formation and reveal its growth law s in porous media. The experiment shows that the evolution of natural gas hydrates is divided into three periods, namely, the instability period of gas–liquid dissolution, the hydrate growth period, and the hydrate formation period. The hydrate growth process accelerates when pressure increases. The increase in temperature yields a random trend. The hydrate growth period has three substages: the gas–liquid cluster and nucleation stage, the gas–liquid film formation and accretion stage, and the deposition and crystallization stage. The hydrate growth laws are drawn as follow: (1) The nucleation characteristics of the gas hydrate directly determine the hydrate’s spatial distribution in the pores. The heterogeneous nucleation is more likely to occur. (2) The spatiotemporal growth of the hydrates is an interaction of two kinds of transformations in the porous media, namely, the transformation from the disordered to the ordered, and the transformation from the hydrophobic to the hydrophilic. In the early stage, the gas–liquid contact appears to be hydrophobic, and the gas–liquid dissolution process shows a repeated disorder. In the later stage, the hydrate begins to be ”hydrophilic”, which means it follows the existing hydrate interface to grow orderly into the depth of the pores. (3) The geometric distribution of the pore structure can change the spatial structure of the water molecules’ growth, which leads the hydrate to distribute with a geometric anisotropy. The research results are aimed to provide a theoretical basis for the exploitation and optimization of marine natural gas hydrates.
Highlights
With unique advantages of small pollution, vast reserves, wide distribution and high energy density, Natural Gas Hydrate (NGH), or hydrates for short, are known as the commanding height for the global energy development in the future (Sloan, 1998) and have attracted worldwide attention
Since Mallik plan carried out hydrate trial production in the permafrost zone of Mackenzie Delta in Canada, at least
7 major hydrate trial production events had happened by the end of 2017, with rich practical experience being accumulated in natural gas hydrate trial production
Summary
With unique advantages of small pollution, vast reserves, wide distribution and high energy density, Natural Gas Hydrate (NGH), or hydrates for short, are known as the commanding height for the global energy development in the future (Sloan, 1998) and have attracted worldwide attention. In order to explore the micro-formation mechanism of hydrate at a pore-scale, based on the high-pressure-resistant visual model made by etching method on the glass plate, this experiment can comprehensively describe the micro-formation mechanism of hydrate in porous media after an observation of the hydrate crystal formation in porous media through a microscope. In other words, this experiment is to describe the hydrate crystal formation process in the pores and throat, analyze the distribution and size of hydrate in micro-porous structure, find out the time-varying characteristics during the hydrate formation, and conclude the dynamic process of hydrate nucleation and the controlling factors. The research results are aimed to provide data and theoretical basis for the selection and optimization of marine gas hydrate exploitation methods
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