Geomechanical Modelling Application to Support Reservoir Selection for Carbon Dioxide Utilization and Storage

E. Korelskiy, Y. Petrakov, Alexey Sobolev, A. Ablaev, D. Mylnikov, D. Melnichuk
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引用次数: 2

Abstract

During recent years reduction of carbon dioxide emission driving development of different technologies for CO2 capturing and utilization. Carbon dioxide injection in underground reservoirs is on of effective methods for storage or utilization as enhanced oil recovery agent. Selection of the potential reservoir for CO2 injection is critically important for long term gas storage. In this paper demonstrated software solutions and workflows for modelling of geomechanical modelling of CO2 injection. Injection of CO2 into the reservoir entails a change in reservoir pressure and a change in reservoir temperature. In turn, the stress-strain state of the massif changes, which can lead to the destruction of the reservoir rock and host rocks, reactivation of faults, and, as a consequence, the loss of the integrity of the seal and uncontrolled interstratal crossflows. This paper will describe an example of choosing a reservoir for CO2 injection based on the study of the stress-strain state of the rock mass and its changes due to gas injection. Currently, there are various approaches to CO2 recovery into the reservoir, including injection into depleted gas reservoirs, aquifers and oil reservoirs for the purpose of enhanced oil recovery. For injection planning, it is extremely important to understand both the initial injection conditions and their changes over time. In the work on the published materials, the world experience of CO2 injection into the reservoir with the aim of its utilization was studied. Using the tools of combined geomechanical modeling of the reservoir, the modeling of the change in the stress-strain state of the massif during the injection process was carried out and the conditions under which the destruction of the reservoir cap and the reactivation of faults occur. The influence of uncertainty in elastic-strength parameters on the critical state of the rock mass and the potential of the permissible injection volume is shown. Comparison of injection potential into reservoirs with terrigenous and carbonate seals has been performed.
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地质力学建模在支持二氧化碳利用和储存储层选择中的应用
近年来,二氧化碳排放的减少推动了各种二氧化碳捕获和利用技术的发展。地下油藏注二氧化碳作为提高采收率的一种有效的储层或利用方法。选择潜在的储层注入二氧化碳对于天然气的长期储存至关重要。本文演示了二氧化碳注入地质力学建模的软件解决方案和工作流程。向储层注入CO2会引起储层压力和储层温度的变化。反过来,岩体的应力-应变状态发生变化,这可能导致储集岩和寄主岩的破坏,断层的重新激活,最终导致密封完整性的丧失和不受控制的内部交叉流动。本文将在研究岩体应力-应变状态及其注气变化的基础上,给出一个选择注CO2储层的实例。目前,有多种方法将二氧化碳注入储层,包括注入枯竭气藏、含水层和油藏以提高采收率。对于注入计划,了解初始注入条件及其随时间的变化是非常重要的。在对已发表资料的整理工作中,研究了世界各国以利用为目的向储层注入二氧化碳的经验。利用储层地质力学联合建模工具,对注入过程中岩体应力-应变状态的变化进行了模拟,并对储层盖层破坏和断层复生的条件进行了模拟。分析了弹性强度参数的不确定性对岩体临界状态和潜在允许注入量的影响。对比了陆源和碳酸盐岩两种封闭条件下储层的注入潜力。
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