Correlations among the design factors of the CO₂ ocean sequestration system, GLAD

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• 作者：Niwa ; Kentaro ; Kosugi ; Sanai ; Saito ; Takayuki ; Kajishima ; Takeo ; Hamaogi ; Kenji
• 刊名：Energy
• 出版年：2005
• 出版时间：August - September, 2005
• 年：2005
• 卷：30
• 期：11-12
• 页码：2308-2317
• 全文大小：314 K

文摘

An ocean sequestration method to dispose of a large amount of CO₂ gas has been developed to mitigate global warming. This system is called the gas lift advanced dissolution (GLAD) system. This system works by dissolving CO₂ gas into seawater at a depth of 200–300. The CO₂-rich seawater is then transported to a depth greater than 1000m. This system is composed of short riser pipes for gas-lift and CO₂ dissolution, a tank for separating indissoluble gas ingredients from seawater, and long down-comers for transporting CO₂-rich seawater to great depths. For the system to function optimally, the riser pipe needs to be long and wide enough to dissolve CO₂ thoroughly. Also the down-comer has to be long enough to transport the CO₂-rich seawater to great depths and sufficiently large in diameter to enable transportation of large quantities of seawater. The most important aspect for disposal of CO₂ into the ocean is minimizing the environmental impact, especially its influence on marine life. The CO₂ concentration of seawater, therefore, must be limited below a certain value in order to minimize the environmental impact. This paper describes a mathematical model of GLAD's internal flow, which was derived to optimize the system specifications, and the correlations among the design factors of GLAD system derived by using this mathematical model.