Characterization of Hydrate Formation and Flow Influenced by Hydrophilic–Hydrophobic Components within a Fully Visual Rocking Cell

Lang, Chen; Han, Bingyue; Zou, Henglong; Liu, Zaixing; Yao, Haiyuan; Li, Qingping; Chen, Haihong; Yang, Lei; Zhao, Jiafei; Song, Yongchen; Zhang, Lunxiang

doi:10.1021/acs.energyfuels.3c04492

Cited by 4 publications

(2 citation statements)

References 68 publications

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“…Clathrate hydrates are nonstoichiometric cage-like crystalline compounds formed by gas molecules trapped in water molecules under low temperatures and high pressures . Hydrates have the advantages of high calorific value and strong gas storage capacity, which has led to extensive research in the utilization of hydrate technology. − However, natural gas hydrate formation is harmful in some cases, such as during the process of gas and oil transportation, where hydrate formation can cause serious economic loss and safety problems. − …”

Section: Introductionmentioning

confidence: 99%

Crystal Growth of CO₂–CH₄ Hydrate on a Solid Surface with Varying Wettability in the Presence of PVCap

Zhang,

Wang,

Lang

et al. 2024

Crystal Growth & Design

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Pipeline transportation has become the main way of long-distance and large-scale energy transportation because of its high efficiency, safety, economy, and environmental friendliness. During the exploitation of offshore gas fields containing CO 2 , the pipelines easily form hydrates under appropriate environmental conditions, which can cause great harm to the flow assurance. Therefore, adding inhibitors and surface coatings in the pipeline is used to prevent hydrate formation. To better fit the actual blockage problem of the deep-sea oil and gas pipeline transportation process, it is necessary to study the hydrate growth kinetics of mixed gases on different wettability surfaces with or without inhibitors. The crystal morphology and growth process of CH 4 and CO 2 mixed hydrate crystals forming from a droplet were investigated by a CCD camera and microscope. The results showed that the droplets will not form hydrates completely in a high CO 2 content system, but all converted into hydrates in a low CO 2 system. The villous dendrites on the surface of droplets are more abundant, and the growth rate is slower with the increase in PVCap concentration. On the superhydrophobic surface, the hydrate nucleation rate and hydrate growth rate are the lowest, which means inhibition to hydrate nucleation and growth. These research results are hoped to provide a solid theoretical basis for solving the actual flow safety problems of deep-sea oil and gas pipelines.

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Section: Introductionmentioning

confidence: 99%

Crystal Growth of CO₂–CH₄ Hydrate on a Solid Surface with Varying Wettability in the Presence of PVCap

Zhang,

Wang,

Lang

et al. 2024

Crystal Growth & Design

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“…In recent years, there has been significant advancement and enrichment in visualization techniques, , with the utilization of X-ray − or optical microscopy, − emerging as a prevailing research trend for studying the formation dynamics of hydrates. Rui et al observed that under gas-filled conditions, as the water migration rate increases, the hydraulic stability transitions from grain-coating hydrate to grain-filling hydrate and finally to load-bearing hydrate.…”

Section: Introductionmentioning

confidence: 99%

Phase Transition Characteristics of Hydrate Formation Process in Microscale Pores

Deng,

Kou,

et al. 2024

Energy Fuels

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Gas hydrates are ubiquitous in nature, with their formation within microscale pores involving intricate physical and chemical process. Recent advancements in visualization methods have propelled further investigations into the formation mechanisms of gas hydrates. The exploration of characteristics pertaining to the hydrate formation process through visual data has emerged as a prominent research avenue. However, it is still difficult to directly point out the relationship between the visual phenomenon and mechanism with a systematic approach. This article focuses on discerning significant temporal changes and categorizes phase transition features of microscale pore hydrate formation into two distinct yet conceptually clear domains: distribution probability and phase transition probability. Then, a statistical discussion of these probabilities has been proposed. Distribution probability elucidates the structural performance and physical attributes of hydrates at the microscale, while phase transition probability offers insights into visualizing kinetic parameters of hydrate reactions, which are conventionally challenging to gauge using traditional sensors. These probabilities linked visual information to physical information. It enabled the quantitative statistical evaluation of various factors during the phase transition process of hydrates, moving beyond a mere visual qualitative analysis. In essence, this innovative methodology furnishes hitherto unexplored concepts and a systematic framework for investigating microscale interface reactions and illuminating their internal mechanisms and evolutionary principles.

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Investigation of hydrate formation and slurry flow visualization in Oil-gas–water multiphase systems

Liu,

Ma,

et al. 2024

Chemical Engineering Journal

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Characterization of Hydrate Formation and Flow Influenced by Hydrophilic–Hydrophobic Components within a Fully Visual Rocking Cell

Cited by 4 publications

References 68 publications

Crystal Growth of CO₂–CH₄ Hydrate on a Solid Surface with Varying Wettability in the Presence of PVCap

Crystal Growth of CO₂–CH₄ Hydrate on a Solid Surface with Varying Wettability in the Presence of PVCap

Phase Transition Characteristics of Hydrate Formation Process in Microscale Pores

Investigation of hydrate formation and slurry flow visualization in Oil-gas–water multiphase systems

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Characterization of Hydrate Formation and Flow Influenced by Hydrophilic–Hydrophobic Components within a Fully Visual Rocking Cell

Cited by 4 publications

References 68 publications

Crystal Growth of CO2–CH4 Hydrate on a Solid Surface with Varying Wettability in the Presence of PVCap

Crystal Growth of CO2–CH4 Hydrate on a Solid Surface with Varying Wettability in the Presence of PVCap

Phase Transition Characteristics of Hydrate Formation Process in Microscale Pores

Investigation of hydrate formation and slurry flow visualization in Oil-gas–water multiphase systems

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Product

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Crystal Growth of CO₂–CH₄ Hydrate on a Solid Surface with Varying Wettability in the Presence of PVCap

Crystal Growth of CO₂–CH₄ Hydrate on a Solid Surface with Varying Wettability in the Presence of PVCap