海上枯竭气田碳捕集与封存技术研究

R. Tewari, C. Tan, M. Sedaralit
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引用次数: 3

摘要

二氧化碳的捕获、利用和储存是减少大气中二氧化碳排放从而控制大气中温室气体浓度的最佳选择。尽管有这些好处,但仅为二氧化碳封存而实施的项目数量有限。油气行业在储层注气以维持压力和提高采收率方面非常精通。然而,向枯竭油气藏注入二氧化碳与工程封存二氧化碳之间存在显著差异。当储存地点是海上的碳酸盐岩和大容量储存时,差异和挑战变得更加复杂。最重要的是要事先知道二氧化碳可以储存在一个潜在的储存地点,并证明该地点可以满足所需的储存性能安全标准。利用地理、地质、地球物理、地质力学和油藏工程数据和技术,对马来西亚沙捞越海上合适的二氧化碳储存地点进行了全面筛选,以评估储存量、容器结构、压力和温度条件。特定于场地的输入数据被集成到静态和动态模型中,用于表征和生成场地的性能场景。此外,还研究了CO2与储层岩石的地球化学相互作用,以了解注入期间/之后可能发生的变化及其对注入过程/机制的影响。采用动态-地球化学-地质力学过程的三维耦合模型,研究了地层中CO2的长期动态行为和命运。3-way耦合建模有助于了解注入物未来可能的状态和储存机制,即结构、溶解度、残留和矿化圈闭。它还提供了真实的存储容量估计,包括储层压实和孔隙度/渗透率的变化。研究表明,覆岩翼面断层局部塑性剪切应变不足,而其他断层均保持稳定。由于目标注入压力设定为初始油藏压力,远低于注入过程中盖层破裂压力,因此潜在的泄漏威胁很小。此外,发现地球化学反应影响较浅且局限于储层顶部,保证了长期安全储存。对现有油井的完整性进行了潜在泄漏评估,并制定了适当的缓解计划。综合测量、监测和验证(MMV)也使用最先进的工具和动态仿真结果进行了设计。通过额外的技术工作来改善技术应用并减少不确定性,可以缩小理解差距。对海上CO2封存项目进行全面研究,确定关键影响因素,对于估算、注入、遏制和监测CO2羽流至关重要。这些信息和工作流程可用于评估全球范围内碳酸盐和碎屑储层的其他CO2项目,以实现温室气体的长期无问题储存。
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A Toolkit for Carbon Capture and Storage in Offshore Depleted Gas Field
Carbon dioxide (CO2) capture, utilization, and storage is the best option for mitigating atmospheric emissions of CO2 and thereby controlling the greenhouse gas concentrations in the atmosphere. Despite the benefits, there have been a limited number of projects solely for CO2 sequestration being implemented. The industry is well-versed in gas injection in reservoir formation for pressure maintenance and improving oil recovery. However, there are striking differences between the injection of CO2 into depleted hydrocarbon reservoirs and the engineered storage of CO2. The differences and challenges are compounded when the storage site is karstified carbonate in offshore and bulk storage volume. It is paramount to know upfront that CO2 can be stored at a potential storage site and demonstrate that the site can meet required storage performance safety criteria. Comprehensive screening for site selection has been carried out for suitable CO2 storage sites in offshore Sarawak, Malaysia using geographical, geological, geophysical, geomechanical and reservoir engineering data and techniques for evaluating storage volume, container architecture, pressure, and temperature conditions. The site-specific input data are integrated into static and dynamic models for characterization and generating performance scenarios of the site. In addition, the geochemical interaction of CO2 with reservoir rock has been studied to understand possible changes that may occur during/after injection and their impact on injection processes/mechanisms. Novel 3-way coupled modelling of dynamic-geochemistry-geomechanics processes were carried out to study long-term dynamic behaviour and fate of CO2 in the formation. The 3-way coupled modelling helped to understand the likely state of injectant in future and the storage mechanism, i.e., structural, solubility, residual, and mineralized trapping. It also provided realistic storage capacity estimation, incorporating reservoir compaction and porosity/permeability changes. The study indicates deficient localized plastic shear strain in overburden flank fault whilst all the other flaws remained stable. The potential threat of leakage is minimal as target injection pressure is set at initial reservoir pressure, which is much lower than caprock breaching pressure during injection. Furthermore, it was found that the geochemical reaction impact is shallow and localized at the top of the reservoir, making the storage safe in the long term. The integrity of existing wells was evaluated for potential leakage and planned for a proper mitigation plan. Comprehensive measurement, monitoring, and verification (MMV) were also designed using state-of-art tools and dynamic simulation results. The understanding gaps are closed with additional technical work to improve technologies application and decrease the uncertainties. A comprehensive study for offshore CO2 storage projects identifying critical impacting elements is crucial for estimation, injection, containment, and monitoring CO2 plume. The information and workflow may be adopted to evaluate other CO2 projects in both carbonate and clastic reservoirs for long-term problem-free storage of greenhouse gas worldwide.
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