Seong-Pil Kang scite author profile

The main purpose of this study was to develop a new hydrate-based gas separation (HBGS) process especially for recovering CO2 from flue gas. Temperature and pressure conditions for hydrate formation have been closely examined at the various CO2 concentrations of flue gases. Tetrahydrofuran (THF) chosen as a hydrate promoter can also participate in forming hydrates and produces a mixed hydrate together with CO2. The hydrate stability region was greatly expanded by using THF for lowering the equilibrium formation pressure. To confirm thermodynamic validity of the HBGS process, the three-phase equilibria of hydrate, liquid, and vapor were measured for the systems comprising CO2, N2 and water with or without THF in the temperature range of 272−295 K. In addition, two phase equilibria of hydrate and vapor were experimentally investigated for the same systems at several temperatures. Through close examination of the overall experimental results, it was firmly verified that the HBGS process makes it possible to recover more than 99 mol % of CO2 from the flue gas. The key unit operations of the HBGS lie in hydrate formation and subsequent dissociation similarly to gas absorption and desorption using the sterically hindered amines. The HBGS provides several advantages over the conventional ones. First, the operational temperature is moderate in the range of 273−283 K, and continuous operation allows this process to treat a large amount of gaseous stream. Second, only a small amount of THF is needed together with water and therefore severe corrosion problem can be avoided. Third, the aqueous solution containing THF after dissociation can be easily recycled to the hydrator.

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Hydrate phase equilibria of the guest mixtures containing CO2, N2 and tetrahydrofuran

Kang

Lee

et al. 2001

Fluid Phase Equilibria

253

152

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Experimental determination and thermodynamic modeling of methane and nitrogen hydrates in the presence of THF, propylene oxide, 1,4-dioxane and acetone

Seo

Kang

Lee

2001

Fluid Phase Equilibria

163

127

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Phase equilibria of methane and carbon dioxide hydrates in the aqueous MgCl2 solutions

Kang

Chun

Lee

1998

Fluid Phase Equilibria

126

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Thermodynamic and kinetic hydrate inhibition performance of aqueous ethylene glycol solutions for natural gas

Cha

Shin

Kim

et al. 2013

Chemical Engineering Science

139

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Seong-Pil Kang

Recovery of CO₂ from Flue Gas Using Gas Hydrate: Thermodynamic Verification through Phase Equilibrium Measurements

Hydrate phase equilibria of the guest mixtures containing CO2, N2 and tetrahydrofuran

Experimental determination and thermodynamic modeling of methane and nitrogen hydrates in the presence of THF, propylene oxide, 1,4-dioxane and acetone

Phase equilibria of methane and carbon dioxide hydrates in the aqueous MgCl2 solutions

Thermodynamic and kinetic hydrate inhibition performance of aqueous ethylene glycol solutions for natural gas

Contact Info

Product

Resources

About

Seong-Pil Kang

Recovery of CO2 from Flue Gas Using Gas Hydrate: Thermodynamic Verification through Phase Equilibrium Measurements

Hydrate phase equilibria of the guest mixtures containing CO2, N2 and tetrahydrofuran

Experimental determination and thermodynamic modeling of methane and nitrogen hydrates in the presence of THF, propylene oxide, 1,4-dioxane and acetone

Phase equilibria of methane and carbon dioxide hydrates in the aqueous MgCl2 solutions

Thermodynamic and kinetic hydrate inhibition performance of aqueous ethylene glycol solutions for natural gas

Contact Info

Product

Resources

About

Recovery of CO₂ from Flue Gas Using Gas Hydrate: Thermodynamic Verification through Phase Equilibrium Measurements