Application and prospects of spatial information technology in CO_(2)sequestration monitoring

This paper systematically reviews the current applications of various spatial information technologies in CO_(2)sequestration monitoring,analyzes the challenges faced by spatial information technologies in CO_(2)sequestration monitoring,and prospects the development of spatial information technologies in CO_(2)sequestration monitoring.Currently,the spatial information technologies applied in CO_(2)sequestration monitoring mainly include five categories:eddy covariance method,remote sensing technology,geographic information system,Internet of Things technology,and global navigation satellite system.These technologies are involved in three aspects:monitoring data acquisition,positioning and data transmission,and data management and decision support.Challenges faced by the spatial information technologies in CO_(2)sequestration monitoring include:selecting spatial information technologies that match different monitoring purposes,different platforms,and different monitoring sites;establishing effective data storage and computing capabilities to cope with the broad sources and large volumes of monitoring data;and promoting collaborative operations by interacting and validating spatial information technologies with mature monitoring technologies.In the future,it is necessary to establish methods and standards for designing spatial information technology monitoring schemes,develop collaborative application methods for cross-scale monitoring technologies,integrate spatial information technologies with artificial intelligence and high-performance computing technologies,and accelerate the application of spatial information technologies in carbon sequestration projects in China.

An Integrated Framework for Geothermal Energy Storage with CO_(2)Sequestration and Utilization

Subsurface geothermal energy storage has greater potential than other energy storage strategies in terms of capacity scale and time duration.Carbon dioxide(CO_(2))is regarded as a potential medium for energy storage due to its superior thermal properties.Moreover,the use of CO_(2)plumes for geothermal energy storage mitigates the greenhouse effect by storing CO_(2)in geological bodies.In this work,an integrated framework is proposed for synergistic geothermal energy storage and CO_(2)sequestration and utilization.Within this framework,CO_(2)is first injected into geothermal layers for energy accumulation.The resultant high-energy CO_(2)is then introduced into a target oil reservoir for CO_(2)utilization and geothermal energy storage.As a result,CO_(2)is sequestrated in the geological oil reservoir body.The results show that,as high-energy CO_(2)is injected,the average temperature of the whole target reservoir is greatly increased.With the assistance of geothermal energy,the geological utilization efficiency of CO_(2)is higher,resulting in a 10.1%increase in oil displacement efficiency.According to a storage-potential assessment of the simulated CO_(2)site,110 years after the CO_(2)injection,the utilization efficiency of the geological body will be as high as 91.2%,and the final injection quantity of the CO_(2)in the site will be as high as 9.529×10^(8)t.After 1000 years sequestration,the supercritical phase dominates in CO_(2)sequestration,followed by the liquid phase and then the mineralized phase.In addition,CO_(2)sequestration accounting for dissolution trapping increases significantly due to the presence of residual oil.More importantly,CO_(2)exhibits excellent performance in storing geothermal energy on a large scale;for example,the total energy stored in the studied geological body can provide the yearly energy supply for over 3.5×10^(7) normal households.Application of this integrated approach holds great significance for large-scale geothermal energy storage and the achievement of carbon neutrality.

Grading Evaluation and Ranking of CO_(2) Sequestration Capacity in Place(CSCIP) in China’s Major Oil Basins:Theoretical,Effective,Practical and CCUS-EOR

Because it is necessary to focus on differences in regional oil reservoirs and determine the priority of the CCUSEOR(Carbon capture,utilization,and storage-enhanced oil recovery) deployment under China’s net-zero CO_(2) emission target,systematic and regional evaluations of CO_(2) sequestration capacity in major oil basins are needed considering the geofluid properties―carbon sequestration capacity in place(CSCIP)―where the ’in place’ indicates actual geological formation conditions underground,e.g.,formation temperature and pressure.Therefore,physical properties of geofluids at different depths with different geologic temperatures and pressure conditions are considered for the CO_(2) sequestration capacity evaluation in place,including shallow(800–2000 m),medium(2000–3500 m),deep(3500–4500 m) and ultra-deep(4500–8000 m) depth intervals.A modified evaluation model with four grading levels is proposed,combining the P-V-T equations of state(EOS) and evaluation equations of the Carbon Sequestration Leadership Forum(CSLF),including theoretical,effective,practical,and CCUS-EOR CSCIP,which is more consistent with geofluid physical properties underground,to make the grading evaluation and ranking of the CSCIP in China’s major oil basins.Then,the grading CSCIP of 29 major oil basins in China was evaluated based on the petroleum resources evaluation results of the Ministry of Natural Resources of China(MNRC) during China’s 13th Five-Year Plan period.According to the grading evaluation results,suggestions for China’s CCUS-EOR prospective regions are given as follows:shallow oil fields of the Songliao Basin in Northeast China,shallow–medium oil fields of the Bohai Bay Basin in East China,medium oil fields of the Zhungeer Basin in West China,and medium oil fields of the Ordos Basin in Central China;all are potential areas for the CCUS-EOR geological sequestration in China’s onshore oil basins.In addition,in China’s offshore oil basins,shallow–medium oil fields of the Bohai Sea and shallow oil fields of the Pearl River Mouth Basin have potential for CCUS-EOR geological sequestration.

Differences in CO_(2)-Water-Rock Chemical Reactions among ’Sweet Spot’ Reservoirs:Implications for Carbon Sequestration

The Lucaogou Formation,located in the Jimsar Sag,Junggar Basin,NW China,has great potential for shale oil resources.In the process of CO_(2)-EOR(CO_(2) enhance oil recovery),mineral dissolution,precipitation and transformation,leading to the local corrosion or blockage of reservoirs,have a significant influence on recovery.In this study,a combination of high-temperature and high-pressure laboratory experiments and coupled temperature/fluid-chemistry multifield numerical simulations are used to investigate CO_(2)-water-rock reactions under various reservoir conditions in the upper and lower ’sweet spots’,to reveal the mechanisms underlying CO_(2)-induced mineral dissolution,precipitation and transformation.In addition,we quantitatively calculated the evolution of porosity over geological timescales;compared and analyzed the variability of CO_(2) transformation in the reservoir under a variety of temperature,lithology and solution conditions;and identified the main factors controlling CO_(2)-water-rock reactions,the types of mineral transformation occurring during long-term CO_(2) sequestration and effective carbon sequestration minerals.The results demonstrate that the main minerals undergoing dissolution under the influence of supercritical CO_(2) are feldspars,while the main minerals undergoing precipitation include carbonate rock minerals,clay minerals and quartz.Feldspar minerals,especially the initially abundant plagioclase in the formation,directly affects total carbon sequestration,feldspar-rich clastic rocks therefore having considerable sequestration potential.

A Novel Process of CO_(2) Reduction and CO_(2) Sequestration Through an Innovative Accelerated Carbonation Technique

The efiect of an innovative accelerated carbonation curing technique was evaluated on concrete containing natural zeolite powder and fine aggregate as partial replacement to alleviate the CO_(2) emission up to a certain extent from the concrete production industry and improve sequestration of CO_(2) into the concrete matrix in a stable form.An accelerated carbonation curing was accomplished by subjecting the concrete specimens to 0.5 and 0.75 M concentrations of sodium bicarbonate(NaHCO_(3)) solutions up to a curing age of 180 days after the initial 28 days of normal water curing.Tests for carbonation depth,pH value,compressive strength,calcium carbonate(CaCO_(3))content,X-ray difiraction,and thermogravimetric(TGA)analyses and Fourier transform infrared spectroscopy(FTIR)were performed to measure the extent of carbonation.The obtained results showed an increment in average compressive strength for the zeolite concrete(ZLC)mixes exposed to accelerated carbonation curing.The ZLC mixes exposed to increasing NaHCO_(3) solution concentration and exposure period exhibited greater carbonation depth and decreased pH at each depth interval indicating higher CO_(2) sequestration within the concrete matrix.The results obtained from the microstructural analysis(XRD,TGA,and FTIR)and CaCO_(3) content measurements confirm that the higher amount of CaCO_(3) formation provides a clear indication of the carbonation enhancement and CO_(2) sequestration within the concrete matrix and in turn contributing to the global warming reduction.

三河尖关闭煤矿煤层CO_(2)封存潜力研究

关闭煤矿煤层CO_(2)地质封存是CO_(2)封存的重要方式之一,也是短期内实现碳减排指标的有效手段之一。以江苏省徐州市三河尖关闭煤矿为例,分析了已采7号煤和9号煤的煤岩煤质特征,统计了剩余煤炭资源储量,运用模糊综合评价法,选取了稳定系数、上覆岩层性质、地质构造复杂程度、地下水指标、封存煤层压温比、封存煤层深厚比、封存煤层渗透率、采空塌陷程度和其他因素等9个主要影响因素指标对7号煤和9号煤封存CO_(2)稳定性进行评价,建立关闭煤矿煤层CO_(2)封存评价方法并评估CO_(2)封存潜力。结果表明,三河尖关闭煤矿7号煤和9号煤剩余储量较大,CO_(2)封存稳定性综合评价结果分别为86.209和87.698,评价等级均为较稳定,封存潜力较高。根据建立的关闭煤矿煤层CO_(2)封存评价方法,计算获得三河尖关闭煤矿7号和9号煤层CO_(2)理论封存量分别为207.6 Mt和80.9 Mt,并据此划分封存有利区为有利区、较有利区和不利区3个等级。研究可为关闭煤矿煤层CO_(2)封存研究提供基础依据。

煤中超临界CO_(2)解吸滞后机理及其对地质封存启示

将CO_(2)注入不可采煤层地质封存既是降低温室气体效应最理想选择之一,也是煤炭工业降低CO_(2)排放、实现低碳化可持续发展的必由之路,然而,煤层CO_(2)地质封存悬而未决的关键问题是:“注入煤层中的CO_(2)到底能否长期停留而安全封存?”。鉴于此,在弄清煤体CO_(2)解吸滞后规律的基础上,揭示超临界CO_(2)解吸滞后机理,建立煤层CO_(2)地质封存量化模型,探讨利用解吸滞后实现煤层CO_(2)长期安全封存。研究表明:煤中超临界态CO_(2)解吸滞后程度大于亚临界态CO_(2),在超临界阶段,吸附与解吸等温线形成近似“平行线”的稳定滞后特征;解吸滞后的本质原因是煤中微纳米级亲水性孔隙形成弯液面、产生强大毛细压力、渗吸液态水、截断并固定超临界CO_(2)流体、最终形成了CO_(2)残余封存,例如,煤中直径40~10 nm圆柱形无机孔隙可产生7.30~29.12 MPa毛细压力,足以封堵超临界态CO_(2);以九里山煤样解吸等温线数据为例,采用基于煤层CO_(2)解吸滞后的地质封存量化模型,评估出900~1500 m深部二1煤层封存总量稳定在35~37 m^(3)/t,其中,吸附封存约占80%,残余封存约占15%,而结构封存仅占5%;解吸滞后启示应尽可能采取措施提高煤层残余封存CO_(2)比例,原因是毛细堵塞的残余封存CO_(2)较围岩密封的游离和吸附CO_(2)更安全且没有泄露风险,煤层灰分、水分、孔隙尺寸和形貌等物性参数是影响残余封存效率的主要因素。

CO_(2)驱油封存泄漏风险管理系统及应用研究

CO_(2)驱油封存技术在提高原油采收率的同时能实现大规模CO_(2)封存。然而,驱油封存过程伴随着多种CO_(2)泄漏风险。针对以往CO_(2)泄漏风险管理系统的缺乏,特别是缺少基于在线监测的管理系统,难以支撑动态的风险管理,研究基于CO_(2)驱油封存泄漏风险管理体系的构建,开发了集成多环境实时风险识别和评估、多空间风险预测、多层级风险预警和全过程风险控制的动态CO_(2)泄漏风险管理系统,并应用于鄂尔多斯盆地延长石油CO_(2)驱油封存示范项目。案例应用研究表明,所开发的CO_(2)泄漏风险管理系统可以全空间动态识别CO_(2)驱油封存过程的各种泄漏风险,有效支撑泄漏风险的动态管理,为CO_(2)驱油封存项目提供全面及时的安全保障。

南川常压海相页岩气注CO_(2)吞吐提高采收率工程实践

当前研究实验和模拟论证了注CO_(2)吞吐提高页岩气采收率的理论可行性,然而其实际工程效果尚未得到现场试验的验证。为此,基于四川盆地南川常压海相页岩气藏地质赋存及生产特征,开展了页岩等温吸附和CO_(2)—CH_(4)竞争吸附机理研究,实施了国内首次常压海相页岩气衰减井CO_(2)吞吐现场试验,并提出了构建成套技术体系的攻关方向。研究结果表明:①气井生产到后期进入低压低产阶段,表现出地层能量不足的特征,是提高气井采出程度的重要阶段;②常压页岩的CH_(4)和CO_(2)吸附能力明显高于低压或高压页岩,采用CO_(2)提采更具可行性和必要性;③相同条件下的常压、高压和低压3组页岩样品均表现出对CO_(2)的吸附量大于对CH_(4)的吸附量,且对气体的吸附能力依次为南川(常压海相)页岩>长宁(高压海相)页岩>延长(低压陆相)页岩;④试验井注CO_(2)吞吐增产效果明显,页岩气单井预测最终可采储量(EUR)从0.75×10^(8) m^(3)上升到0.90×10^(8) m^(3),单井控制储量5.186×10^(8) m^(3),预计采收率提高了2.9%。结论认为:①实施的国内首次常压海相页岩气衰减井注CO_(2)吞吐试验取得突破性进展,为我国页岩气井提高采收率技术研发与应用提供了重要借鉴与参考;②亟需开展页岩气衰减井CO_(2)提采资源潜力与时机评估、提采效果定量评价与工艺优化等研究,并形成页岩气衰减井注CO_(2)吞吐提高采收率成套关键技术及标准体系。

枯竭油气藏储集库储热供暖耦合CO_(2)封存性能分析

利用枯竭油气藏储存热能并封存CO_(2),既可解决太阳能跨季节储热难题,又可扩大可再生能源供暖占比,同时还可提高CO_(2)地质封存的经济性。提出了枯竭油气藏储热供暖耦合CO_(2)封存的新方案,以CO_(2)作为循环工质,夏季吸收太阳热量储存于油气藏背斜构造中,而冬季取出供暖,建立了储释能过程的数学模型,重点分析了枯竭油气藏储能系统热工性能和CO_(2)封存性能。结果表明:(1)新方案储能系统热工性能优异。单井平均采热功率4808.95 kW,每个采暖季可有效利用的平均储热量49859.21 GJ,平均能量储存密度28984.23 kJ/m^(3)。(2)CO_(2)密度对温度敏感的特性降低了热损失,提高了系统效率。枯竭油气藏储能系统平均能量回收效率95.84%,平均热回收效率83.66%。(3)储能加速了CO_(2)溶解。储释能过程中周期性的注入和采出工作气导致气液界面反复膨胀收缩,增加了气水接触面积,提高了传质动力,加速了CO_(2)在水中的溶解。对比储能模式和仅CO_(2)封存模式,CO_(2)溶解比例增量由0.26%上升至2.22%。枯竭油气藏储热供暖耦合CO_(2)封存新方案既有优异的热工性能,又加速了CO_(2)的地质封存,是一种高值化的枯竭油气藏利用和可再生能源供暖方案,具有大规模推广应用的潜力。

碱激发矿渣基泡沫混凝土的制备及其封存CO_(2)可行性研究

随着工业化进程的不断推进,工业固体废弃物的排放量逐年增加,以工业固废为主要原料制备泡沫混凝土并将其用于CO_(2)封存,对实现工业固废的资源化利用和CO_(2)的经济、高效封存具有重要意义。本文以高炉矿渣为原料,选用NaOH为碱激发剂,硬脂酸钠为稳泡剂,十二烷基硫酸钠(C12H25NAO4S,SDS)为发泡剂,制备了高孔隙的泡沫混凝土。探究了不同NaOH用量对矿渣基泡沫混凝土综合性能及封存CO_(2)性能的影响。实验结果表明,随着NaOH用量的增加,泡沫混凝土的干密度逐渐增加,抗压强度先增大后减小。泡沫混凝土的内部孔隙分布不均匀,孔隙率大。SEM结果表明,当NaOH用量过高时泡沫发生破裂连通。XRD结果表明,矿渣基泡沫混凝土水化产物主要是C—S—H凝胶和Ht物相,Ht物相的层状结构使得材料的孔壁不够致密,从而影响材料的力学性能。TGA结果表明,碳化过程中水化产物有效吸收CO_(2)转化成以CaCO3为主的碳酸盐,NaOH用量12%时,CO_(2)的封存量最高为89.74 kg/m^(3)。

采空区碳封存条件下CO_(2)-水界面特性及溶解传质规律

采空区CO_(2)封存作为解决煤炭行业碳排放难题的重要负碳技术储备,在采空区废弃资源二次利用、CO_(2)封存等方面具有广泛的应用前景。利用原位界面张力测定仪开展了不同温压、地层水矿化度及阳离子溶液类型对CO_(2)地层水系统的界面张力(IFT)影响规律实验,明晰了CO_(2)注入含水碎胀煤岩体中的气液界面扩散效应,并将基于统计缔合理论结合兰纳−琼斯势能模型的状态方程(SAFT-LJ状态方程)与密度梯度理论(DGT)结合预测了IFT理论值;利用自主研发的地质封存地化反应模拟实验平台对相同条件下的CO_(2)溶解性进行了探究实验,得到了采空区储层环境下CO_(2)溶解度变化特征,采用D-S模型计算了对应CO_(2)溶解度理论值。实验结果表明:环境温度一定时,采空区储层压力与IFT呈线性负相关关系,储层温度升高,IFT相应增加,但变化幅度较小;温压条件一定时,矿化度与IFT存在正相关性,且在本实验范围内,低压、高温、高矿化度会促使IFT升高;CO_(2)−盐溶液之间的IFT呈现出随着阳离子价态升高而增大的现象(K^(+)<Na^(+)<Ca^(2+)<Mg^(2+));采空区储层压力与CO_(2)溶解度呈正相关关系,当温度为25℃、纯水条件下,压力由0.5 MPa增至2.5 MPa,对应CO_(2)溶解度由0.1627 mol/kg升至0.7141 mol/kg;CO_(2)溶解度随着温度与矿化度的升高而降低;相同质量分数下,一价阳离子溶液(NaCl、KCl)比二价阳离子溶液(CaCl_(2)、MgCl_(2))可溶解更多的CO_(2)。注入采空区中的游离相CO_(2)克服界面张力通过扩散溶解传质作用打破了采空区地层的地球化学平衡,通过明确环境温压条件、采空区水环境对IFT及CO_(2)溶解度的影响规律,阐明CO_(2)地层水气液界面效应及溶解传质机理,以期为采空区CO_(2)封存安全性及封存量评估提供理论基础。

准噶尔盆地吉木萨尔凹陷页岩油藏注CO_(2)吞吐提高采收率机理

页岩油藏的成功开发在缓解我国能源紧缺的问题上发挥了重要作用,但衰竭式开发采收率较低,传统提高采收率的措施难以有效增产,因此明确页岩油藏注CO_(2)提高采收率的机理,对于探索页岩油的开发技术具有重要意义。为此,以准噶尔盆地吉木萨尔凹陷页岩油藏为例,开展了一系列注CO_(2)实验并结合流体注入能力和油气组分传质评价实验,揭示了注CO_(2)吞吐提高采收率的机理,并明确了注CO_(2)吞吐的埋存形式、埋存效率与其生产动态之间的耦合关系。研究结果表明:①CO_(2)的注入能力是水的7.77倍、N2的1.18倍;增加注入压力,促进CO_(2)与原油之间的相互作用,能有效提高CO_(2)的注入能力。②CO_(2)对原油物性的改善能力显著强于N2,在CO_(2)—原油组分传质的协同作用下,注CO_(2)吞吐的采收率比N2高6.84%。③原油膨胀和黏度降低是注CO_(2)吞吐前期提高采收率的主要机制,而后期主要通过CO_(2)对原油轻质烃类组分置换、萃取进一步实现了采收率的提高,混相压力(MMP)是注CO_(2)吞吐的阈值压力。④注CO_(2)吞吐过程中,埋存率从最初的77.77%持续降低到7.14%,不同形式CO_(2)的埋存比例具有动态变化的特征,但主要以游离态和溶解态埋存为主。结论认为,吉木萨尔凹陷页岩油藏注CO_(2)吞吐在提高采收率的同时实现了CO_(2)的埋存,实验结果为研究国内相似页岩油藏注CO_(2)吞吐提采—埋存效率提供理论支撑和经验借鉴。

人工裂缝参数对CO_(2)-ESGR中CO_(2)封存和CH_(4)开采的影响

目的页岩储层中的裂缝系统对CH_(4)产量和CO_(2)封存量有着重要的影响,不同的储层地质特征有其对应的最优压裂方案。对鄂尔多斯盆地延长组页岩储层人工裂缝参数对CO_(2)封存和CH_(4)开采的影响进行分析。方法基于鄂尔多斯盆地延长组页岩储层地质条件建立了页岩基质-裂缝双孔双渗均质模型,分析CO_(2)增强页岩气开采技术(CO_(2)-ESGR)中人工裂缝半长、裂缝宽度、裂缝高度、裂缝间距和裂缝数量对CO_(2)封存量和CH_(4)产量的影响。结果CO_(2)封存量和CH_(4)产量与裂缝半长、裂缝宽度和裂缝高度呈正相关,其中裂缝宽度的影响最大,从5 mm增加到25 mm时,最多可使CO_(2)封存量和CH_(4)产量分别增加112.69%和87.11%。裂缝间距和裂缝数量增加可提高CO_(2)封存量和CH_(4)产量,但水平井长度相同时裂缝数量增加对CO_(2)封存量和CH_(4)产量的影响幅度远大于裂缝间距,当裂缝数量从2条增加到6条,最多可使CO_(2)封存量和CH_(4)产量分别增加151.92%和137.81%。结论在开发过程中,合理增加人工裂缝的半长、高度、宽度和数量,可以实现高效CO_(2)封存和CH_(4)开采。

细粒砂矿物成分及粒径配比对CO_(2)水合物合成特性影响的实验研究

在冻土层中用水合物法封存CO_(2)是一种具有潜力和前景的CO_(2)封存技术。为探究地层性质对CO_(2)封存的影响,在初始压力5.5 MPa、温度1.27℃的条件下,在不同细粒砂矿物成分及粒径配比的影响下进行了CO_(2)水合物合成实验,对实验过程中CO_(2)水合物生成过程的压力-温度变化、CO_(2)水合物平均生成速率、CO_(2)耗气量和相饱和度等进行了分析。结果表明,细粒砂与粗粒砂粒径配比(各组分质量比,下同)为1.0:2.0时的CO_(2)水合物平均生成速率最小(12.60 mmol/min),随着粗粒砂比例的增大,比表面积减少,CO_(2)水合物平均生成速率变慢。蒙脱石黏土不利于CO_(2)水合物生成,粉砂组(含细粒砂与粗粒砂)CO_(2)水合物平均生成速率高于粉砂质黏土组(含细粒砂和蒙脱石黏土),且粉砂组实验更容易实现高的水合物饱和度和CO_(2)耗气量,因此在矿物成分含细粒砂与粗粒砂的区域更适合进行CO_(2)封存。细粒砂与粗粒砂或黏土矿物粒径配比为1.0:0.5时的CO_(2)耗气量分别为0.86 mol、0.77 mol,随着粗粒砂和黏土矿物比例的增大,水合物相饱和度和CO_(2)耗气量均逐渐减小,细粒砂与粗粒砂或黏土矿物粒径配比为1.0:0.5时是适合水合物法封存CO_(2)的比例。

CO_(2)驱分层注气工艺管柱适用性分析及展望

目前,我国现场应用的注气管柱多为笼统注气管柱、同心双管分层注气管柱及偏心投捞分层注气管柱,该类管柱存在着分层数受限、测调效率低、测调精度差及适应性差等问题,难以满足CO_(2)驱油田的精细、高效开发需求。针对这一现象,在现有成熟分层注水管柱的基础上,设计了液控分层注气管柱、测调一体分层注气管柱、有缆智能分层注气管柱,并对这3种分层注气管柱进行了技术适应性分析和实施难点分析,分析发现:所设计的3种分层注气管柱各有优势,配套井下气体流量计的研制既是设计管柱的主要实施难点也是实现精细化注气的关键。最后,对各类流量测量技术进行了技术特性及研究难度分析,并对井下气体流量计的设计选型提出了建议和展望。

化子坪长6储层长岩心CO_(2)驱替实验及数值模拟评价

二氧化碳驱提高石油采收率(CO_(2)-EOR)在我国大部分低渗透、低孔隙度油藏中的应用越来越重要。鉴于国家净零排放目标,在采用二氧化碳驱提高采收率时,二氧化碳封存是另一个重要考虑因素。针对低渗油藏,开展天然岩心长岩心CO_(2)驱替试验,并利用TOGA(TOUGH Oil,Gas,Aqueous)软件建立岩心尺度数值模型开展模型的识别与验证,对模型的有效性及物性参数进行敏感性分析,结果表明,1)根据出口气油比可将二氧化碳驱油与封存划分为未见气(0~100)、极少量气(100~1 000)、气体突破(1 000~10 000)、大量气窜(>10000)四个不同阶段;2)孔隙度、渗透率及非均质性对模拟结果影响较大,在后续实际场地模型中应予以重点关注。研究结果可为实际场地规模模型提供参数依据。

扩散作用控制下CO_(2)矿化封存实验及模拟研究

玄武岩地层由于富含钙、镁、铁等二价金属元素,能够通过高效的矿化反应将注入的CO_(2)转化为碳酸盐岩,实现CO_(2)安全有效的永久封存。但围绕CO_(2)矿化封存机制的研究尚不完善,多数研究忽略了扩散作用对CO_(2)矿化机制的影响。通过试管填充及烧杯平铺实验,开展了不同矿物、不同粒径及不同反应时间下的CO_(2)-水-岩反应,并对反应后岩样开展多维度分析,包括拉曼光谱、无机碳含量以及SEM-EDS等,从而阐明了扩散作用在CO_(2)矿化封存中的重要性以及扩散作用控制下CO_(2)矿化产物的时空演变规律。同时,通过TOUGHREACT建立了扩散作用控制的试管填充实验的数值模拟模型,并通过与物理实验结果拟合,确保数值模拟模型的准确性。在此基础上,开展了更多影响因素的作用规律研究,并为物理实验现象提供机理解释。结合物理实验及数值模拟结果表明:①在不存在扩散作用的烧杯平铺实验中,反应14 d后无矿化产物,28 d后仅有微量菱镁矿生成。②相反,在扩散作用控制下的试管填充实验中,橄榄石填充管中的主要的沉淀物是菱镁矿,天然玄武岩填充管中的沉淀物以方解石、菱铁矿为主,菱镁矿为辅。在相同矿物粒径、相同反应时间下,天然玄武岩中CO_(2)矿化速率远小于橄榄石,这是由于橄榄石与玄武岩其他组成矿物相比溶解速度最快。③在橄榄石或玄武岩填充管中,碳酸盐沉淀物沿填充管均呈非均匀分布。通过数值模拟解释了造成这一现象的根本原因,即在扩散作用控制下,填充床中H+、DIC(Dissolved Inorganic Carbon)以及二价金属阳离子存在浓度梯度,且浓度梯度方向不同。④矿物比表面积对CO_(2)-水-岩反应有显著影响,不仅影响矿化效率而且影响矿化产物空间分布,并最终影响反应后多孔介质孔隙度分布。⑤与压力相比,温度对CO_(2)矿化的影响更大;当温度从65℃升高到85℃时,方解石、菱铁矿及碳酸盐沉淀总量明显增加,但从85℃升高100℃,仅菱镁矿沉淀量增加明显。压力对方解石沉淀的形成影响较小,而对菱镁矿及菱铁矿的形成几乎没有影响。

CO_(2)地质利用与封存中碳迁移及其相态分布规律

CO_(2)地质利用与封存技术是“双碳”战略下重要的碳减排手段,前人的研究多集中于地质利用方面,而对地层的碳封存潜力尤其是CO_(2)矿化潜力的定量评价存在不足。为此,通过程序开发手段,将闪蒸计算加入开源的反应溶质运移模拟软件中,利用改进后的软件建立了松辽盆地大情字井油田H59区块的三维地质模型,通过历史拟合注采过程校正模型地层参数,最后采用校正后模型量化表征了不同注入阶段及注采结束后CO_(2)迁移与相态转化的时空演化过程。研究结果表明:①在油藏CO_(2)混相驱条件下,CO_(2)在注入井端的小范围内呈现气相,在接触到油相前缘后,CO_(2)受浮力影响减弱,在垂向上逐渐趋于均匀分布,并向开采井端均匀推进;②气水同注阶段与注气阶段均有超过70%注入的CO_(2)溶解于油相,但气水同注阶段溶解于水相的CO_(2)含量明显增加;③注采结束后的相态演化特征表现为溶解水相CO_(2)逐渐转变为矿物相,而溶解油相CO_(2)存在转变为游离态气相的趋势;④注采结束后,主要矿化过程为绿泥石及铁白云石溶解产生铁、钙离子,与碳酸根离子结合构成方解石和菱铁矿等沉淀矿物(固碳矿物),而主要溶解矿物有钾长石、钙蒙脱石、铁白云石及绿泥石。结论认为,基于现场实测数据,利用嵌入闪蒸计算的CO_(2)地质利用与封存组分模拟软件,提高了对CO_(2)迁移及分布相态规律的进一步认识,研究结果对实现注CO_(2)高效提高采收率与封存具有重要指导意义。

CO_(2)封存井筒密封性及强化方法

考虑CO_(2)封存井筒的实际服役环境,基于有限元方法建立了含水泥腐蚀层的井筒屏障模型,模拟了水泥塞-地层界面微环隙发育过程,厘清了流体驱动下微环隙扩展机制及主控因素,提出了井筒密封性强化方法。模拟结果表明:超临界CO_(2)聚积会引起水泥胶结面应力改变,当界面处应力由压应力转为拉应力,且应力值高于界面胶结强度时,井筒便会产生微环隙;若水泥腐蚀后腐蚀层刚度、界面胶结强度下降,则井筒密封能力下降;膨胀性添加剂可提高胶结面初始压应力,进而增强井筒密封性。当水泥塞膨胀率为0.5‰时,微环隙扩展压力上升43.7%,微环隙长度下降了42.7%,井筒密封性得到显著增强。