Application of Feature, Event, and Process Methods to Leakage Scenario Development for Offshore CO_(2) Geological Storage

Offshore carbon dioxide(CO_(2)) geological storage(OCGS) represents a significant strategy for addressing climate change by curtailing greenhouse gas emissions. Nonetheless, the risk of CO_(2) leakage poses a substantial concern associated with this technology. This study introduces an innovative approach for establishing OCGS leakage scenarios, involving four pivotal stages, namely, interactive matrix establishment, risk matrix evaluation, cause–effect analysis, and scenario development, which has been implemented in the Pearl River Estuary Basin in China. The initial phase encompassed the establishment of an interaction matrix for OCGS systems based on features, events, and processes. Subsequent risk matrix evaluation and cause–effect analysis identified key system components, specifically CO_(2) injection and faults/features. Building upon this analysis, two leakage risk scenarios were successfully developed, accompanied by the corresponding mitigation measures. In addition, this study introduces the application of scenario development to risk assessment, including scenario numerical simulation and quantitative assessment. Overall, this research positively contributes to the sustainable development and safe operation of OCGS projects and holds potential for further refinement and broader application to diverse geographical environments and project requirements. This comprehensive study provides valuable insights into the establishment of OCGS leakage scenarios and demonstrates their practical application to risk assessment, laying the foundation for promoting the sustainable development and safe operation of ocean CO_(2) geological storage projects while proposing possibilities for future improvements and broader applications to different contexts.

Potential evaluation of saline aquifers for the geological storage of carbon dioxide: A case study of saline aquifers in the Qian-5 member in northeastern Ordos Basin

The well-developed coal electricity generation and coal chemical industries have led to huge carbon dioxide(CO_(2))emissions in the northeastern Ordos Basin.The geological storage of CO_(2) in saline aquifers is an effective backup way to achieve carbon neutrality.In this case,the potential of saline aquifers for CO_(2) storage serves as a critical basis for subsequent geological storage project.This study calculated the technical control capacities of CO_(2) of the saline aquifers in the fifth member of the Shiqianfeng Formation(the Qian-5 member)based on the statistical analysis of the logging and the drilling and core data from more than 200 wells in the northeastern Ordos Basin,as well as the sedimentary facies,formation lithology,and saline aquifer development patterns of the Qian-5 member.The results show that(1)the reservoirs of saline aquifers in the Qian-5 member,which comprise distributary channel sand bodies of deltaic plains,feature low porosities and permeabilities;(2)The study area hosts three NNE-directed saline aquifer zones,where saline aquifers generally have a single-layer thickness of 3‒8 m and a cumulative thickness of 8‒24 m;(3)The saline aquifers of the Qian-5 member have a total technical control capacity of CO_(2) of 119.25×10^(6) t.With the largest scale and the highest technical control capacity(accounting for 61%of the total technical control capacity),the Jinjie-Yulin saline aquifer zone is an important prospect area for the geological storage of CO_(2) in the saline aquifers of the Qian-5 member in the study area.

Investigation of gravity influence on EOR and CO_(2) geological storage based on pore-scale simulation

Gravity assistance is a critical factor influencing CO_(2)-Oil mixing and miscible flow during EOR and CO_(2)geological storage.Based on the Navier-Stokes equation,component mass conservation equation,and fluid property-composition relationship,a mathematical model for pore-scale CO_(2) injection in oilsaturated porous media was developed in this study.The model can reflect the effects of gravity assistance,component diffusion,fluid density variation,and velocity change on EOR and CO_(2) storage.For nonhomogeneous porous media,the gravity influence and large density difference help to minimize the velocity difference between the main flow path and the surrounding area,thus improving the oil recovery and CO_(2) storage.Large CO_(2) injection angles and oil-CO_(2) density differences can increase the oil recovery by 22.6% and 4.2%,respectively,and increase CO_(2) storage by 37.9% and 4.7%,respectively.Component diffusion facilitates the transportation of the oil components from the low-velocity region to the main flow path,thereby reducing the oil/CO_(2) concentration difference within the porous media.Component diffusion can increase oil recovery and CO_(2) storage by 5.7% and 6.9%,respectively.In addition,combined with the component diffusion,a low CO_(2) injection rate creates a more uniform spatial distribution of the oil/CO_(2) component,resulting in increases of 9.5% oil recovery and 15.7% CO_(2) storage,respectively.This study provides theoretical support for improving the geological CO_(2) storage and EOR processes.

Geomechanical modeling of CO2 geological storage:A review

This paper focuses on the progress in geomechanical modeling associated with carbon dioxide(CO2)geological storage.The detailed review of some geomechanical aspects,including numerical methods,stress analysis,ground deformation,fault reactivation,induced seismicity and crack propagation,is presented.It is indicated that although all the processes involved are not fully understood,integration of all available data,such as ground survey,geological conditions,microseismicity and ground level deformation,has led to many new insights into the rock mechanical response to CO2injection.The review also shows that in geomechanical modeling,continuum modeling methods are predominant compared with discontinuum methods.It is recommended to develop continuum-discontinuum numerical methods since they are more convenient for geomechanical modeling of CO2geological storage,especially for fracture propagation simulation.The Mohr-Coulomb criterion is widely used in prediction of rock mass mechanical behavior.It would be better to use a criterion considering the effect of the intermediate principal stress on rock mechanical behavior,especially for the stability analysis of deeply seated rock engineering.Some challenges related to geomechanical modeling of CO2geological storage are also discussed.

Potential assessment of CO_(2)geological storage based on injection scenario simulation:A case study in eastern Junggar Basin

Carbon Capture and Storage(CCS)is one of the effective means to deal with global warming,and saline aquifer storage is considered to be the most promising storage method.Junggar Basin,located in the northern part of Xinjiang and with a large distribution area of saline aquifer,is an effective carbon storage site.Based on well logging data and 2D seismic data,a 3D heterogeneous geological model of the Cretaceous Donggou Formation reservoir near D7 well was constructed,and dynamic simulations under two scenarios of single-well injection and multi-well injection were carried out to explore the storage potential and CO2 storage mechanism of deep saline aquifer with real geological conditions in this study.The results show that within 100 km^(2)of the saline aquifer of Donggou Formation in the vicinity of D7 well,the theoretical static CO_(2)storage is 71.967×106 tons(P50)①,and the maximum dynamic CO_(2)storage is 145.295×106 tons(Case2).The heterogeneity of saline aquifer has a great influence on the spatial distribution of CO_(2)in the reservoir.The multi-well injection scenario is conducive to the efficient utilization of reservoir space and safer for storage.Based on the results from theoretical static calculation and the dynamic simulation,the effective coefficient of CO_(2)storage in deep saline aquifer in the eastern part of Xinjiang is recommended to be 4.9%.This study can be applied to the engineering practice of CO_(2)sequestration in the deep saline aquifer in Xinjiang.

Simulation Study on the Migration Range of CO_(2) in the Offshore Saline Aquifer

The geological storage of carbon dioxide(CO_(2)) is a crucial technology for mitigating climate change. Offshore deep saline aquifers have elicited increased attention due to their remarkable potential for storing CO_(2). During long-term storage, CO_(2) migration in a deep saline aquifer needs special attention to prevent it from reaching risk points and leading to security issues. In this paper, a mechanism model is established according to the geological characteristics of saline aquifers in an offshore sedimentary basin in China. The CO_(2) migration over 100 years is simulated considering geological changes such as permeability, dip angle, thickness, and salinity. The effects of injection conditions on the CO_(2) migration range are also investigated. Results reveal that the migration range of CO_(2) in the injection period exceeds 70%, even if the postinjection period's duration is five times longer than that of the injection period. As the values of the above geological parameters increase, the migration range of CO_(2) increases, and permeability has a particularly substantial influence. Moreover, the influences of injection rate and well type are considerable. At high injection rates, CO_(2) has a greater likelihood of displacing brine in a piston-like scheme. CO_(2) injected by long horizontal wells migrates farther compared with that injected by vertical wells. In general, the plane migration range is within 3 000 m, although variations in the reservoir and injection parameters of the studied offshore saline aquifers are considered. This paper can offer references for the site selection and injection well deployment of CO_(2) saline aquifer storage. According to the studied offshore aquifers, a distance of at least 3 000 m from potential leakage points, such as spill points, active faults, and old abandoned wells, must be maintained.

Characterization of Depleted Hydrocarbon Reservoir AA-01 of KOKA Field in the Niger Delta Basin for Sustainable Sub-Sea Carbon Dioxide Storage

This study characterized the AA-01 depleted hydrocarbon reservoir in the KOKA field, Niger Delta, using a multidimensional approach. This investigation involved data validation analysis, evaluation of site suitability for CO_(2) storage, and compositional simulation of hydrocarbon components. The primary objective was to determine the initial components and behavior of the hydrocarbon system required to optimize the injection of CO_(2) and accompanying impurities, establishing a robust basis for subsequent sequestration efforts in the six wells in the depleted KOKA AA-01 reservoir. The process, simulated using industry software such as ECLIPSE, PVTi, SCAL, and Petrel, included a compositional fluid analysis to confirm the pressure volume temperature(PVT) hydrocarbon phases and components. This involved performing a material balance on the quality of the measured data and matching the initial reservoir pressure with the supplied data source. The compositional PVT analysis adopted the Peng–Robinson equation of state to model fluid flow in porous media and estimate the necessary number of phases and components to describe the system accurately. Results from this investigation indicate that the KOKA AA-01 reservoir is suitable for CO_(2)sequestration. This conclusion is based on the reservoir's good quality, evidenced by an average porosity of 0.21 and permeability of 1 111.0 mD, a measured lithological depth of 9 300 ft, and characteristic reservoir – seal properties correlated from well logs. The study confirmed that volumetric behavior predictions are directly linked to compositional behavior predictions, which are essential during reservoir initialization and data quality checks. Additionally, it highlighted that a safe design for CO_(2) storage relies on accurately representing multiphase behaviour across wide-ranging pressure–temperature–composition conditions.

CO_(2)storage with enhanced gas recovery(CSEGR):A review of experimental and numerical studies

CO_(2)emission mitigation is one of the most critical research frontiers.As a promising option of carbon capture,utilization and storage(CCUS),CO_(2)storage with enhanced gas recovery(CSEGR)can reduce CO_(2)emission by sequestrating it into gas reservoirs and simultaneously enhance natural gas production.Over the past decades,the displacement behaviour of CO_(2)—natural gas has been extensively studied and demonstrated to play a key role on both CO_(2)geologic storage and gas recovery performance.This work thoroughly and critically reviews the experimental and numerical simulation studies of CO_(2)displacing natural gas,along with both CSEGR research and demonstration projects at various scales.The physical property difference between CO_(2)and natural gas,especially density and viscosity,lays the foundation of CSEGR.Previous experiments on displacement behaviour and dispersion characteristics of CO_(2)/natural gas revealed the fundamental mixing characteristics in porous media,which is one key factor of gas recovery efficiency and warrants further study.Preliminary numerical simulations demonstrated that it is technically and economically feasible to apply CSEGR in depleted gas reservoirs.However,CO_(2)preferential flow pathways are easy to form(due to reservoir heterogeneity)and thus adversely compromise CSEGR performance.This preferential flow can be slowed down by connate or injected water.Additionally,the optimization of CO_(2)injection strategies is essential for improving gas recovery and CO_(2)storage,which needs further study.The successful K12—B pilot project provides insightful field-scale knowledge and experience,which paves a good foundation for commercial application.More experiments,simulations,research and demonstration projects are needed to facilitate the maturation of the CSEGR technology.

The geomechanics of Shenhua carbon dioxide capture and storage(CCS) demonstration project in Ordos Basin,China

Carbon dioxide(CO2) capture and storage(CCS) is considered widely as one of promising options for CO2emissions reduction,especially for those countries with coal-dominant energy mix like China.Injecting and storing a huge volume of CO2in deep formations are likely to cause a series of geomechanical issues,including ground surface uplift,damage of caprock integrity,and fault reactivation.The Shenhua CCS demonstration project in Ordos Basin,China,is the first and the largest full-chain saline aquifer storage project of CO2in Asia.The injection started in 2010 and ended in 2015.during which totally 0.3 million tonnes(Mt) CO2was injected.The project is unique in which CO2was injected into 18 sandstone formations simultaneously and the overlying coal seams will be mined after the injection stopped in 2015.Hence,intense geomechanical studies and monitoring works have been conducted in recent years,including possible damage resulting from the temperature difference between injected CO2and formations,injection induced stress and deformation change,potential failure mode and safety factor,interaction between coal mining and CO2geological storage,determination of injection pressure limit,and surface monitoring by the interferometric synthetic aperture radar(InSAR) technology.In this paper,we first described the background and its geological conditions of the Shenhua CCS demonstration project.Then,we gave an introduction to the coupled thermo-hydro-mechano-chemical(THMC) processes in CO2geological storage,and mapped the key geomechanical issues into the THMC processes accordingly.Next,we proposed a generalized geomechanical research flowchart for CO2geological storage projects.After that,we addressed and discussed some typical geomechanical issues,including design of injection pressure limit.CO2injection induced near-field damage,and interaction between CO2geological storage and coal mining,in the Shenhua CCS demonstration project.Finally,we concluded some insights to this CCS project.

海洋CO_(2)地质封存研究进展与发展趋势

CO_(2)捕集、利用和封存是中国实现“双碳”目标的核心技术,也是全球研究的热点。CO_(2)地质封存是其中的关键环节,特别是海洋CO_(2)地质封存是今后的重点发展方向。以国内外海洋CO_(2)地质封存的发展历程为基础,结合典型CO_(2)海洋封存示范项目案例,系统梳理了国内外海洋CO_(2)地质封存理论研究进展,分析了CO_(2)在井筒流动、相变与传热、CO_(2)流体运移与储层物性参数展布规律、海洋地质封存机制及封存潜力、地质封存盖层完整性及安全性评估等方面的研究现状。认识到中国目前对海底地质结构中CO_(2)注入过程的多相态转化、溶解、捕获传质特征及动力学特性认识尚浅,对海洋封存机制及不同封存机制之间的相互作用机理尚不明确,未来应开展海洋CO_(2)动态地质封存空间重构机制研究,解决地质封存相态转化及流体动态迁移机理等关键科学问题,揭示海洋CO_(2)地质封存机制的相互作用机理,形成适用于中国海洋地质封存CO_(2)高效注入和增效封存方法。

CO_(2)−荷载耦合作用下煤体细观统计损伤本构模型及验证

CO_(2)吸附会对煤体产生损伤劣化作用进而降低其稳定性,对CO_(2)封存的长期安全性提出挑战,明确CO_(2)劣化作用并建立本构模型至关重要。采用损伤力学理论和统计理论推导出能够综合反映CO_(2)吸附和荷载耦合作用下煤体总损伤变量的计算公式,并重点考虑了压密段的影响,分段建立了CO_(2)作用下煤体的细观统计损伤本构方程,明确了模型各参数的确定方法。最后通过CT扫描实验系统、MTS 816实验系统确定了本构模型参数,并采用自主研制的气−固耦合实验系统对不同CO_(2)压力下煤体进行了单轴压缩实验,验证了模型的合理性。研究结果表明:①基于CT扫描获取的裂隙率和运用Weibull分布理论分别定义了吸附和受载作用下的损伤变量,结合损伤理论进一步得到二者耦合作用下的总损伤变量,并建立了细观统计损伤本构模型;②基于CT扫描技术的裂隙三维重构真实反映了CO_(2)作用前后裂隙扩展特征,CO_(2)压力越高,裂隙扩展越充分,煤样三维裂隙参数和损伤变量越大,所形成的空间裂隙网络越复杂;③CO_(2)对煤体力学性质劣化作用显著,煤体的抗压强度与弹性模量随CO_(2)压力增加分别降低了49.78%和22.63%,CO_(2)对煤体的溶胀效应、塑化效应和气楔效应的综合作用导致了力学参数的降低;④建立的CO_(2)作用下煤体细观统计损伤模型理论曲线与单轴实验曲线具有较高的吻合度,说明损伤本构模型能够较好地反映出CO_(2)对煤体力学特性的损伤劣化作用,体现了损伤本构模型及模型参数确定方法的合理性与适用性。

纳米SiO_(2)强化CO_(2)地质封存页岩盖层封堵能力机制试验

页岩为CO_(2)盐水层地质封存常见盖层岩石类型,强化盖层封堵能力有利于提高CO_(2)地质埋存量和安全性。为探究随CO_(2)混注纳米SiO_(2)(SNPs)强化盖层封堵能力的有效性和可行性,对CO_(2)地质封存页岩盖层样品开展原地条件下的超临界CO_(2)酸蚀反应试验,基础组为页岩样品-地层水、对照组为页岩样品-地层水+超临界CO_(2)、优化组为页岩样品-地层水+SNPs+超临界CO_(2),并采用核磁共振测试、场发射扫描电镜可视化观测、X射线衍射测试和岩石力学试验,探究CO_(2)酸蚀反应前后的页岩孔隙结构、表面形貌、矿物成分及力学性质特征。结果表明:优化组的大孔孔隙分量及孔隙度和渗透率增大幅度低于对照组;与对照组相比,优化组黏土矿物与碳酸盐岩矿物相对含量损失少,表明随CO_(2)混注SNPs可使岩样内部酸蚀作用减弱;SNPs在岩石端面吸附聚集或进入岩心孔喉,可使优化组页岩样品力学性能损伤程度降低;随CO_(2)混注SNPs有利于强化CO_(2)盐水层地质封存盖层封堵能力。

CO_(2)原位矿化选址关键参数及其封存潜力评估研究进展

温室气体特别是二氧化碳的大量排放,是导致全球变暖的主要原因之一。根据国际能源署的报道,碳捕集利用和封存(CCUS)技术是缓解全球气候变化的重要措施之一,约占累计碳减排量的15%。原位矿化封存技术基于快速CO_(2)矿化机制,以镁铁质岩石和超镁铁质岩石(玄武岩、橄榄岩等)地层为碳封存位点,利用CO_(2)与富含Ca、Mg元素矿物的矿化反应,转变为稳定的碳酸盐,从而达到永久且高效封存CO_(2)的目的。冰岛和美国的中试项目已经证明了该技术的可行性,但中国尚未进行相关示范项目。本文介绍了原位矿化封存技术的机理、CO_(2)封存潜力的评估手段及其面临的风险与挑战,讨论了已开展的案例项目及其技术细节,梳理了实施该技术所必需的选址关键参数(包括源-汇距离、矿物类型、注入性、封闭性等),并基于目前研究对其前景进行展望,以期提高我国对原位矿化技术的认识和重视,为推动该领域进一步发展提供理论指导。

不同超临界CO_(2)浸蚀时间后冲击煤体能量演化与破坏特征

在未采煤层封存CO_(2)时,注入的CO_(2)受高温高压影响会处于超临界态,影响煤层稳定性。为研究超临界CO_(2)浸蚀后煤体受扰动影响引起的能量耗散与破坏特征,基于自主研发的高压气体吸附/解吸试验系统对煤体开展不同超临界CO_(2)浸蚀时间(0、2、4、6 d)的吸附试验,利用分离式霍普金森压杆试验系统对超临界CO_(2)作用后的煤体开展冲击压缩试验,并结合高速摄像仪拍摄了冲击过程,分析了冲击煤体的能量耗散规律,阐明了煤体的破坏裂纹演化与破碎分形特征。研究结果表明:相同冲击荷载下,不同超临界CO_(2)浸蚀时间后煤样的应力-应变曲线变化趋势类似,可划分为弹性能量耗散、塑性能量耗散和峰后能量耗散3个阶段。随超临界CO_(2)浸蚀时间增长,煤样吸能能力减弱,冲击煤样表面裂纹数量增多,裂纹网络及扩展方向逐渐复杂,煤样破碎更加剧烈,破碎粒径减小,破碎形态更加复杂,最后确定了不同浸蚀时间后煤样破碎分形维数与耗能密度的线性相关关系。研究结果对于开展注CO_(2)强化深部煤层气开采工程探索具有一定的理论意义。

超临界CO_(2)作用下无烟煤孔隙结构演化时间效应规律

CO_(2)地质封存技术是实现减排和废弃矿井资源再利用的有效技术之一,但煤层孔隙结构在CO_(2)注入后的变化具有时间效应,其演化规律将直接影响CO_(2)地质封存潜力。为了探索作用时间增加后煤层孔隙结构变化的真实情况,提高CO_(2)地质封存量计算精度,通过对重庆市南桐矿区无烟煤进行超临界CO_(2)吸附实验、低温氮气吸附实验、X射线衍射测试、核磁共振测试、扫描电镜测试等实验,研究了不同超临界CO_(2)作用时间对该区域内煤样孔隙结构的演化规律。研究结果表明:①超临界CO_(2)作用后煤样孔隙度的变化主要发生在7 d内,处理7 d后煤样孔隙度增加了3.20%,7~14 d内煤样孔隙度仅增加了0.05%;②随作用时间增加,煤样孔隙的比表面积增加但变化量逐渐减小,7 d内日均增长19.74%~24.50%,7~14 d内日均增长2.37%~4.60%,其变化规律近似呈对数函数关系;③超临界CO_(2)与煤产生的化学反应引起矿物质的溶解,增大了煤体的表面粗糙度,表征煤样粗糙度的分形维数随着作用时间的增加持续增大;④超临界CO_(2)作用后能有效改变煤样的孔隙度及表面形貌,为CO_(2)吸附提供了更多吸附点位,超临界CO_(2)对孔隙结构的改造效果在7 d内比较明显。结论认为,超临界CO_(2)作用下无烟煤孔隙结构的变化随作用时间增加最终会趋于稳定,研究结果可为无烟煤储层CO_(2)地质封存潜力评价提供理论指导。

二氧化碳地质封存与利用新进展

为了推动碳减排,实现碳中和目标,分析研究了CO_(2)捕集、利用与封存(CCUS)技术进展,提出了存在问题和发展方向。研究表明:全球CCUS产业发展迅速,截至2023年底,全球大型CCUS项目数量达到392个,比2022年增加了一倍,已初步具备商业化运营的技术条件。CO_(2)封存与利用研究应用不断取得新进展:①CO_(2)地质封存体表征和建模采用表征体元(REV)技术,将微观尺度的属性应用于宏观尺度的地质模型,用应变张量数据进行封存体动态表征和监测。综合应用地球化学成像、微地震、地温以及大气监测技术方法进行封存体泄漏监测。建立不同沉积类型储层模拟技术,模拟封存体内不同CO_(2)羽流迁移情景和封存潜力。②大数据和人工智能广泛应用于CCUS。建立了基于深度学习和耦合地质力学的CO_(2)封存风险快速评估代理模型。用机器学习预测或评估剩余油区CO_(2)提高采收率和封存效率。③CO_(2)驱油新技术及应用新领域取得新进展。发展了CO_(2)驱与低矿化度水驱交替注入、CO_(2)微纳米气泡驱油、CO_(2)加增黏剂驱油和CO_(2)泡沫驱油等技术,应用于矿场试验取得良好效果。CO_(2)驱油领域从中-低渗透砂岩油藏、致密砂岩油藏拓展到残余油带、页岩油藏及天然气藏。CCUS也面临长期封存安全性、经济性、技术不确定性等问题和挑战,需要进一步完善法律、法规,开展多学科研究与技术创新,加强国际合作,大力发展CO_(2)地质封存与利用新技术,保障CO_(2)长期封存安全性,提高商业运营经济性。

双碳愿景下CCUS提高油气采收率技术

二氧化碳(CO_(2))捕集与封存技术(CCS)是实现“双碳”目标的一项重大技术,如何运用CCS技术实现碳减排,成为全球关注的热点问题。因地质体具有良好的封闭性和巨大的封存潜力,CO_(2)地质封存成为碳封存的首选方式。单纯的地质封存项目成本高昂,不适宜开展大规模推广;油气藏注CO_(2)提高采收率技术在全球范围内已经较为成熟,其目的主要是提高油气采收率。将这两者相结合,大幅度提高油气采收率的同时,可实现CO_(2)长久安全封存,节约碳封存成本。在对CO_(2)地质封存与油气藏注CO_(2)提高采收率技术的作用机理与发展现状进行阐述的基础上,提出“双碳”愿景下中国油气工业应大力发展二氧化碳捕集、利用及封存(CCUS)提高油气采收率技术,实现CO_(2)绿色资源化利用,达到既实现CO_(2)的地质封存又提高油气采收率双赢的目的。指出目前的技术瓶颈及进一步发展的方向,特别是随着油气勘探开发领域向非常规、难采储量油气藏发展,中国大力发展CCUS提高油气采收率技术更具重要性和迫切性,并且具有广阔的应用前景,对于中国顺利实现“双碳”目标,保障国家能源安全及可持续高质量发展具有重要意义。

基于高干度泡沫实验的非均质咸水层CO_(2)封存能力分析

CO_(2)咸水层封存是实现“碳中和”目标的一项重要技术手段。高干度泡沫不仅能更好地控制CO_(2)流度而且还能适应地层的非均质性,明显提高了咸水层的空间利用效率。为探究高干度CO_(2)泡沫在非均质咸水层中的调剖效果与CO_(2)封存能力,利用自行设计的高温高压驱替实验装置,进行了不同渗透率级差的并联岩心CO_(2)泡沫驱室内实验研究,分析了驱替过程中岩心的气液产出情况与CO_(2)饱和度的变化规律,指出了不同渗透率级差非均质岩心模型的碳封存效果与机理。研究结果表明:①与CO_(2)气驱相比高干度泡沫驱用于CO_(2)咸水层埋存具有更大优势,当岩心渗透率级差介于2.6~10.8时,泡沫均能有效封堵高渗透岩心,使阻力因子维持在36左右,增大了驱替压差与低渗透岩心的产气、产液速度;②岩心中气相饱和度与渗透率存在一定关系,当岩心的渗透率小于2450 mD时,最高气相饱和度随渗透率增加而增大,当渗透率超过2450 mD时,岩心最高气相饱和度在80%左右;③采用高干度泡沫驱可以有效扩大岩心中CO_(2)封存量,渗透率级差为4时,泡沫驱的CO_(2)封存体积较气驱增长219%,当渗透率级差扩大至10.8,CO_(2)封存量能始终维持在较高水平。结论认为,咸水层条件下CO_(2)泡沫驱替实验探究了CO_(2)封存能力变化,提供了非均质储层提高碳封存效率的实验认识,可为非均质咸水层中CO_(2)的地质封存技术优化提供参考和借鉴。

不同地质体中CO_(2)封存研究进展

碳捕集、利用与封存(CCUS)技术是降低二氧化碳(CO_(2))排放、缓解气候变化问题的重要措施。作为CCUS技术的重要组成部分,CO_(2)地质封存是我国能源工业领域实现碳中和目标的“兜底”技术。常见的CO_(2)封存地质体包括深部咸水层、枯竭油气藏、深部不可采煤层和玄武岩等,不同地质体中CO_(2)的封存过程及其机理存在差异。综述了不同地质体中的CO_(2)封存机理、国际国内CO_(2)封存的主要工程实例以及不同地质体中CO_(2)封存潜力的计算方法,并对CO_(2)地质封存的前景进行了展望。

CO_(2)捕集、利用和封存在能源行业的应用:全球案例分析和启示

为了实现中国21世纪中叶达到碳中和,大规模应用CO_(2)捕获、利用和封存(CCUS)技术可以减少能源行业的温室气体排放。通过对国内外CCUS技术、项目的调研,得出了关于未来CCUS部署的3个见解,这些见解有助于能源行业实现转型。首先,碳源浓度较低导致碳捕集效率低,从而导致碳捕集的经济成本较高的问题是目前CCUS项目无法商业化的主要因素,在发展当前的碳捕集技术,提高捕集效率和降低捕集成本的同时也应大力研究空气捕集技术,尤其是在工艺设计和新型吸附材料研发方面,争取实现弯道超车;其次,CO_(2)在油气藏和咸水层的封存与利用应当作为CCUS技术研究的重点,逐步实现大规模推广,并在技术升级和体系完善的基础上推广CO_(2)增强地热、煤层气等其他耦合技术;最后,应当在当前国际上较成熟的碳政策的基础上研究适合中国的激励政策,建立有效的法律法规。论文总结了当前CCUS的关键挑战,并为未来的CCUS研究方向提供了指导方向。