地质CO2封存点地表和中间覆盖层气相地球化学监测方法的发展

Z. Pokryszka, A. Charmoille, G. Bentivegna
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引用次数: 16

摘要

本文中介绍的进展和结果来自地球碳监测项目的一部分,该项目部分由法国国家研究机构(ANR)资助。该项目的一个重要部分包括对地表以及地质CO2储存地点盖层内的气体监测方法。INERIS所进行的工作针对的是经常被建议为监测未来储存地点所必需的两种具体方法:早期探测(预警),基于对从地表钻入中间盖层的专用钻孔底部的气体取样和分析;对从地面释放到大气中的二氧化碳气体通量的检测和量化。这两种方法先后在实验室开发,然后在尽可能接近未来储存地点的条件下进行现场应用和测试。它们的优点是确保直接测量,并提供有关存在或相反,没有二氧化碳泄漏的实时信息。在一个200米深的钻孔上进行的测试表明,由于对钻孔底部积聚的气体的成分进行了连续采样和分析,可以检测到穿过中间覆盖层的二氧化碳泄漏。特别是对从围岩中释放出的少量气体的探测,产生了许多好的结果。这些泄漏可能是更大泄漏的前兆。同样,它也可以采集样本,并确保天然气在距离采样点1000米的长距离运输。这样做不会造成任何明显的变形或稀释初始气体信号,即使是低幅度泄漏。这些结果使我们能够设想实施一种相对简单的系统,用于检测和监测通过中间盖层的气体泄漏。该系统将主要由现成的传统工业气体传感器组成。直接测量从地面发出的气体流量是监测储存地点最有效的方法之一。已改进了INERIS积累室方法,以测量低和极低的CO2通量率。它现在可用于测量范围很广的二氧化碳通量率,从0.05至0.2厘米3分-1的极低排放水平。M-2高达极高的通量,约为3000厘米。通过在实验室和测试平台上进行的测试,以及在自然释放二氧化碳的现场进行的实际条件下的现场测量,检查和验证了室法的准确性和操作特性。这些试验表明,该方法在技术上已经完全成熟,可以在实际层面上用于探测和监测地面的二氧化碳和甲烷排放。经过测试的两种方法现已投入使用,并准备纳入未来二氧化碳储存场址的监测战略。它们可用于存储站点生命周期的每个阶段:站点侦察、初始状态定义、注入、注入后阶段以及站点废弃后的剩余监测。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Development of Methods for Gaseous Phase Geochemical Monitoring on the Surface and in the Intermediate Overburden Strata of Geological CO2 Storage Sites
The developments and results presented in this paper are taken from the work carried out as part of the GeoCarbon-Monitoring project, which was partly funded by the French National Research Agency (ANR). An important part of this project covers methods for gas monitoring on the surface as well as within the cap rock of geological CO2 storage sites. The work undertaken by INERIS was targeted at two specific approaches which are often recommended as essential for the monitoring of future storage sites : early detection (pre-alert), based on the sampling and analysis of gas at the bottom of the dedicated boreholes which are drilled from the surface into the intermediate cap rock strata ; the detection and quantification of the gaseous flux of CO2 released from the ground into the atmosphere. These two approaches were developed in the laboratory successively and then applied and tested in-situ, under conditions that are as close as possible to those of the future storage sites. They offer the advantage of ensuring a direct measurement as well as providing real-time information on the presence or, on the contrary, the absence of CO2 leaks. The tests undertaken on a 200 meter deep borehole have shown that the detection of CO2 leaks passing through the intermediate overburden strata was possible thanks to the continuous sampling and analysis of the composition of the gas which accumulated at the bottom of the borehole. In particular, the detection of small releases of gas emanating from the surrounding rock gave rise to a number of good results. These releases may be a precursor to a larger leak. Likewise, it has been possible to take a sample and ensure the transit of gas over long distances, up to 1000 meters from the sampling point. This was done without causing any significant deformation or dilution of the initial gaseous signal, even for low amplitude leaks. These results allow us to envisage the implementation of a relatively simple system for detecting and monitoring gas leaks through intermediate cap rock strata. This system will largely comprise conventional industrial gas sensors which are available off the shelf. The direct measurement of gas flows emanating from the ground is one of the most effective ways to monitor a storage site. The INERIS accumulation chamber method has been improved to measure low and very low CO2 flux rates. It can now be used to measure a wide range of CO2 flux rates, from very low emission levels of 0.05 to 0.2 cm3.min-1.m-2 up to extremely high flux rates of some 3000 cm3.min-1.m-2. The accuracy and operational characteristics of chamber method have been checked and validated by tests performed in a laboratory and on a test rig, as well as through field measurements taken under real conditions at sites that naturally release CO2. These tests have shown that the method has reached full technical maturity and that it can be applied on a practical level to detect and monitor CO2 and methane emissions on the ground's surface. The two methods which have been tested are now operational and ready for integration into the surveillance strategy applied at future CO2 storage sites. They can be used at every stage of a storage site's life : site reconnaissance, definition of the initial state, injection, post-injection phase, and residual monitoring after the site has been abandoned.
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