Kinetics and morphology of gas hydrate formation from MEG solution in under-inhibited systems

[Display omitted] •MEG alters hydrate growth pattern, preventing hydrate film formation at interface.•MEG induces loose and low-saturation hydrate in solution, followed by solidification.•MEG leads to the formation of dense surface hydrate blocks at under-inhibition.•MEG concentration below 20 % doe...

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Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Switzerland : 1996), 2024-08, Vol.494, p.152946, Article 152946
Main Authors: Liang, Huiyong, Chu, Jiawei, Liu, Yanzhen, Yang, Lei, Shen, Shi, Lv, Xin, Song, Yongchen
Format: Article
Language:English
Subjects:
Flow assurance
Formation kinetics
Gas hydrate
Mono ethylene glycol
Under-inhibition
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Summary:[Display omitted] •MEG alters hydrate growth pattern, preventing hydrate film formation at interface.•MEG induces loose and low-saturation hydrate in solution, followed by solidification.•MEG leads to the formation of dense surface hydrate blocks at under-inhibition.•MEG concentration below 20 % does not exhibit significant self-inhibition of hydrate formation. Natural gas hydrate blockages pose a major risk to deepwater oil and gas development. Thermodynamic under-inhibition is a cost-effective hydrate management strategy, but the impact of mono ethylene glycol (MEG) on hydrate formation kinetics and mass transfer at the gas–water interface requires further understanding for hydrate-related flow assurance. This study investigates the kinetics and morphology of hydrate growth from MEG solutions using in situ micro X-ray CT and a macro transparent reactor. MEG concentration emerged as the primary factor influencing hydrate growth morphology. Findings revealed that MEG alters the growth morphology of gas hydrates by inhibiting the formation of a hydrate film at the gas–liquid interface and inducing flocculent hydrate growth within the solution. MEG can also induce the formation of low-saturation hydrates, with no significant self-inhibition observed at concentrations below 20 %. Over time, a dense hydrate shell tended to form on the surface of the hydrate lump, increasing the risk of blockage. Additionally, it was observed that subcooling also affects the hydrate growth morphology; higher subcooling accelerates the hydrate growth rate and increases the density of the formed hydrate. This research explored the mechanisms underlying hydrate formation in under-inhibited systems, aiming to extend the safe operational boundary for oil and gas transportation and provide theoretical support for deepwater hydrate management.
ISSN:1385-8947
DOI:10.1016/j.cej.2024.152946