Experimental Study on the Influence of the Temperature and Gas–Liquid Ratio on Hydrate-Based CO2 Separation from the CH4–CO2 Gas Mixture under Static Conditions

Zhang, Xuemin; Yin, Shaoqi; He, Jiajing; Liu, Qingqing; Li, Jinping; Wang, Yingmei; Wu, Qingbai

doi:10.1021/acs.energyfuels.3c03788

Energy Fuels

2023

DOI: 10.1021/acs.energyfuels.3c03788

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Experimental Study on the Influence of the Temperature and Gas–Liquid Ratio on Hydrate-Based CO₂ Separation from the CH₄–CO₂ Gas Mixture under Static Conditions

Xuemin Zhang,

Shaoqi Yin,

Jiajing He

et al.

Abstract: The purification of bionatural gas is the premise and basis for the efficient utilization of biological gas. The separation of mixed gas by the hydrate-based method can realize the efficient separation of CO 2 gas from bionatural gas. The formation features of mixed gas hydrates were studied under static conditions through experiments in this work, and the quantitative effects of the temperature, gas−liquid ratio, and other factors on the formation process of the CH 4 /CO 2 mixed gas hydrate and the selective … Show more

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Experimental study on the effect of THF/DTAC and adsorption coupling on the separation and carbon capture process of CH4/CO2 gas mixture by hydrate-based method

Zhang,

He,

Sun

et al. 2024

Journal of Environmental Chemical Engineering

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Experimental study on the effect of THF/DTAC and adsorption coupling on the separation and carbon capture process of CH4/CO2 gas mixture by hydrate-based method

Zhang,

He,

Sun

et al. 2024

Journal of Environmental Chemical Engineering

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Hydrate Formation and Agglomeration in the Compound of Hydrophilic Nano-CaCO₃ and Inhibitors

Guo,

Sun,

Yao

et al. 2024

Energy Fuels

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The addition of nanoparticles to drilling fluid is an effective method for reducing fluid invasion. Furthermore, hydrophilic nanoparticles have been proven to inhibit hydrate formation at certain concentrations and particle sizes. However, this inhibition effect fails under high subcooling conditions. In such cases, chemical hydrate inhibitors are required to assist in inhibiting hydrate formation and agglomeration. Nonetheless, the impact of nanoparticles and inhibitor compounds on hydrate formation remains to be fully understood. Therefore, this study addressed this issue by experimentally exploring the effects of different particle sizes (20, 70, and 700 nm) of hydrophilic nano-CaCO3 and hydrate inhibitors (thermal hydrate inhibitor (THI), kinetic hydrate inhibitor (KHI), and antiagglomerant (AA)) on methane hydrate formation and agglomeration in a dynamic system. Macroscopic kinetic parameters such as induction time, the amount of methane consumption, and the average rate of methane consumption were obtained. The results indicate that although hydrophilic nanoparticles, THI (3.5 wt % NaCl), and KHI (0.5 wt % polyvinylcaprolactam (PVCap)) in single-component systems can all inhibit hydrate nucleation and growth, their compound does not exhibit synergistic effects. The inhibition ability of the compound is intermediate between that of the single components, which is superior to using nano-CaCO3 aqueous solution alone. Conversely, while AA (0.5 wt % PKO) can prevent hydrate agglomeration, the kinetic inhibition ability of the compound is somewhat weakened with the addition of AA. As a result, hydrophilic nanoparticles, 3.5 wt % NaCl, and 0.5 wt % PVCap are selected as drilling fluid additives, and AA will not be added to the hydrate drilling fluid in this study. Additionally, a possible compounding mechanism model has been proposed. The findings of this study will be of significant theoretical and practical value for the design of deep-water and hydrate drilling fluids using nanoparticles, and will also provide insights into the compounding mechanism of multiple hydrate inhibitors in the field of flow assurance.

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Experimental Study on the Influence of the Temperature and Gas–Liquid Ratio on Hydrate-Based CO₂ Separation from the CH₄–CO₂ Gas Mixture under Static Conditions

Cited by 2 publications

References 50 publications

Experimental study on the effect of THF/DTAC and adsorption coupling on the separation and carbon capture process of CH4/CO2 gas mixture by hydrate-based method

Experimental study on the effect of THF/DTAC and adsorption coupling on the separation and carbon capture process of CH4/CO2 gas mixture by hydrate-based method

Hydrate Formation and Agglomeration in the Compound of Hydrophilic Nano-CaCO₃ and Inhibitors

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Experimental Study on the Influence of the Temperature and Gas–Liquid Ratio on Hydrate-Based CO2 Separation from the CH4–CO2 Gas Mixture under Static Conditions

Cited by 2 publications

References 50 publications

Experimental study on the effect of THF/DTAC and adsorption coupling on the separation and carbon capture process of CH4/CO2 gas mixture by hydrate-based method

Experimental study on the effect of THF/DTAC and adsorption coupling on the separation and carbon capture process of CH4/CO2 gas mixture by hydrate-based method

Hydrate Formation and Agglomeration in the Compound of Hydrophilic Nano-CaCO3 and Inhibitors

Contact Info

Product

Resources

About

Experimental Study on the Influence of the Temperature and Gas–Liquid Ratio on Hydrate-Based CO₂ Separation from the CH₄–CO₂ Gas Mixture under Static Conditions

Hydrate Formation and Agglomeration in the Compound of Hydrophilic Nano-CaCO₃ and Inhibitors