Hydraulic barrier design and applicability for managing the risk of CO₂ leakage from deep saline aquifers

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• 作者：Arnaud R¨¦veill¨¨re ; J¨¦r¨¦my Rohmer ; Jean-Charles Manceau
• 关键词：CO2 geological storage ; Hydraulic barrier ; Leakage ; Risk management ; Corrective measure ; Remediation
• 刊名：International Journal of Greenhouse Gas Control
• 出版年：2012
• 出版时间：July, 2012
• 年：2012
• 卷：9
• 期：Complete
• 页码：62-71
• 全文大小：1205 K

文摘

A proper risk management scheme for CO₂ storage should include an adequate monitoring plan completed with a site-specific intervention plan in order to demonstrate that any undesired consequence can be prevented, if not corrected. In the case of CO₂ escape from the storage reservoir to an overlying aquifer through a vertical conduit (representing the degraded cement of a well or a permeable fault), directly modifying the leak hydraulic properties (e.g. permeability) may be unfeasible. An appealing option is to counter the driving forces of the migration (natural CO₂ buoyancy and injection-induced over-pressure) by increasing the pressure over the leak through brine or water injection within the overlying aquifer, i.e. by creating a ¡°hydraulic barrier¡±. The present article presents and discusses the operational and strategic issues associated with this corrective technique and proposes a methodology in order to set the main design parameters (injection flow rate and duration) depending on the site specificities. The methodology is tested on a leakage scenario and three implementation cases of hydraulic barriers (brine injection 10 m away from the leak with or without delay, or 1 km away without delay) are simulated using the 3D multiphase flow transport code TOUGH2/ECO2N. We assess their effectiveness for stopping the leakage and for trapping (residual and dissolution) the CO₂ accumulated in the overlying aquifer. This example shows that the hydraulic barrier can be suited to low transmissivity overlying aquifers, and that its effectiveness will primarily depend on the distance from the leak to the brine injection well. When possible, a brine injection within the overlying aquifer formation in the vicinity of the leak ensures a rapid stop of the leakage and an effective trapping of the CO₂.