A Research Progress of CO_(2)-Responsive Plugging Channeling Gels

In the heterogeneous reservoirs,CO_(2) flooding easily leads to CO_(2) gas channeling,which can seriously affect sweeping efficiency and reduce oil recovery.After thoroughly investigating the advantages and shortcomings of various CO_(2) plugging technologies,this paper focuses on the feasibility of improving conventional water-alternating gas(WAG)through CO_(2)-responsive gel materials.Based on the different chemical reaction mechanisms between the unique chemical structure and CO_(2),changes in the material’s physical and chemical properties can respond to CO_(2).The feasibility of utilizing these property changes for CO_(2)-responsive plugging is explored.Various CO_(2)-responsive gels and gel nanoparticles have been extensively researched in different fields,such as energy,medicine,and biology.This paper surveys the molecular structures,chemical compositions,response mechanisms,and changes of these CO_(2)-responsive gels,aiming to draw insights into the carbon dioxide-enhanced oil recovery(CO_(2)-EOR)field.Finally,the key issues and future development direction of CO_(2)-responsive plugging gels were analyzed.

CO_2-triggered gelation for mobility control and channeling blocking during CO_2 flooding processes

CO2 flooding is regarded as an important method for enhanced oil recovery （EOR） and greenhouse gas control. However, the heterogeneity prevalently dis- tributed in reservoirs inhibits the performance of this technology. The sweep efficiency can be significantly reduced especially in the presence of ＂thief zones＂. Hence, gas channeling blocking and mobility control are important technical issues for the success of CO2 injection. Normally, crosslinked gels have the potential to block gas channels, but the gelation time control poses challenges to this method. In this study, a new method for selectively blocking CO2 channeling is proposed, which is based on a type of CO2-sensitive gel system （modified polyacry- lamide-methenamine-resorcinol gel system） to form gel in situ. A CO2-sensitive gel system is when gelation or solidification will be triggered by CO2 in the reservoir to block gas channels. The CO2-sensitivity of the gel system was demonstrated in parallel bottle tests of gel in N2 and CO2 atmospheres. Sand pack flow experiments were con- ducted to investigate the shutoff capacity of the gel system under different conditions. The injectivity of the gel system was studied via viscosity measurements. The results indi- cate that this gel system was sensitive to CO2 and had good performance of channeling blocking in porous media. Advantageous viscosity-temperature characteristics were achieved in this work. The effectiveness for EOR in heterogeneous formations based on this gel system was demonstrated using displacement tests conducted in double sand packs. The experimental results can provide guideli- nes for the deployment of theCO2-sensitive gel system for field applications.

Importance of conformance control in reinforcing synergy of CO_(2) EOR and sequestration

Injecting CO2into hydrocarbon reservoirs can enhance the recovery of hydrocarbon resources,and simultaneously,CO2can be stored in the rese rvoirs,reducing considerable amount of carbon emissions in the atmosphere.However,injected CO_(2)tends to go through fractures,high-permeability channels and streaks present in reservoirs,resulting in inefficient hydrocarbon recovery coupled with low CO_(2)storage performance.Conformance treatments with CO_(2)-resistant crosslinked polymer gels were performed in this study to mitigate the CO_(2)channeling issue and promote the synergy between enhanced oil recovery(EOR) and subsurface sequestration of CO_(2).Based on a typical low-permeability CO_(2)-flooding reservoir in China,studies were performed to investigate the EOR and CO_(2)storage performance with and without conformance treatment.The effect of permeability contrast between the channels and rese rvoir matrices,treatment size,and plugging strength on the efficiency of oil recovery and CO_(2)storage was systematically investigated.The results indicated that after conformance treatments,the CO_(2)channeling problem was mitigated during CO_(2)flooding and storage.The injected CO_(2)was more effectively utilized to recover the hydrocarbons,and entered wider spectrum of pore spaces.Consequently,more CO_(2)was trapped underground.Pronounced factors on the synergy of EOR and CO_(2)storage were figured out.Compared with the treatment size,the CO_(2)storage efficiency was more sensitive to the plugging strength of the conformance treatment materials.This observation was important for conformance treatment design in CCUS-EOR projects.According to this study,the materials should reduce the channel permeability to make the channel/matrix permeability ratio below 30.The results demonstrate the importance of conformance treatment in maximizing the performance of CCUS-EOR process to achieve both oil recovery improvement and efficient carbon storage.This study provides guidelines for successful field applications of CO_(2)transport control in CO_(2)geo-utilization and storage.

Gas channeling control with an in-situ smart surfactant gel during water-alternating-CO_(2) enhanced oil recovery

Undesirable gas channeling always occurs along the high-permeability layers in heterogeneous oil reservoirs during water-alternating-CO_(2)(WAG)flooding,and conventional polymer gels used for blocking the“channeling”paths usually suffer from either low injectivity or poor gelation control.Herein,we for the first time developed an in-situ high-pressure CO_(2)-triggered gel system based on a smart surfactant,N-erucamidopropyl-N,N-dimethylamine(UC22AMPM),which was introduced into the aqueous slugs to control gas channeling inWAG processes.The water-like,low-viscosity UC22AMPM brine solution can be thickened by high-pressure CO_(2) owing to the formation of wormlike micelles(WLMs),as well as their growth and shear-induced structure buildup under shear flow.The thickening power can be further potentiated by the generation of denser WLMs resulting from either surfactant concentration augmentation or a certain range of heating,and can be impaired via pressurization above the critical pressure of CO_(2) because of its soaring solvent power.Core flooding tests using heterogeneous cores demonstrated that gas channeling was alleviated by plugging of high-capacity channels due to the in-situ gelation of UC22AMPM slugs upon their reaction with the pre-or post-injected CO_(2) slugs under shear flow,thereupon driving chase fluids into unrecovered low-permeability areas and producing an 8.0% higher oil recovery factor than the conventional WAG mode.This smart surfactant enabled high injectivity and satisfactory gelation control,attributable to low initial viscosity and the combined properties of one component and CO_(2)-triggered gelation,respectively.This work could provide a guide towards designing gels for reducing CO_(2) spillover and reinforcing the CO_(2) sequestration effect during CO_(2) enhanced oil recovery processes.

The influence of stocking levels,clone,fertilization,and weed control on surface CO_(2)efflux in a mid-rotation Pinus radiata D.Don plantation in Canterbury,New Zealand

Silvicultural practices applied in managed forest plantations may help counteract the effects of climate change by influencing soil surface CO_(2)efflux(Fs).Understanding the effects of silvicultural practices on Fs will provide unbiased estimates of carbon fluxes and allow better silvicultural decisions for carbon sequestration.Therefore,we assessed how Fs differed seasonally across silvicultural practices(i.e.,stocking levels,clone,fertilization and weed control treatments)and evaluated the effects of soil temperature(Ts)and soil volumetric water content(θv)on Fs across these practices for a mid-rotation(14 year-old)Pinus radiata plantation in the Canterbury region of New Zealand.There were significant differences in Fs(p<0.05)over the four seasons,three levels of stocking,and five clones.The effects of fertilization and weed control applied 12 years previously on Fs were insignificant.Annual estimate of Fs(mean±1 standard deviation)from the study site was 22.7±7.1 t ha^(-1)a^(-1)in the form of CO_(2)(6.2±2.1 t ha^(-1)a^(-1)in the form of C).Fs values were consistently higher in plots with 1250 stems ha^(-1)compared to 2500 stems ha^(-1),which may be related to a strong soil resource limitation because of the close spacing in the latter plantation.Significant differences in Fs across clones suggest that variations in carbon partitioning might explain their growth performance.Silvicultural treatments influenced Fs response to soil temperature(p<0.05),resulting in models explaining 28-49%of the total variance in Fs.These findings provide insights into how silvicultural management decisions may impact Fs in mid-rotation radiata pine plantations,contributing towards developing more precise and unbiased plantation carbon budgets.

跨临界CO_(2)循环系统控制优化策略的研究进展

控制策略作为跨临界CO_(2)循环系统的重要组成部分,是保证系统高效节能运行的关键。介绍了系统最优排气压力经验计算和泊金汉π定理的反馈控制、基于梯度追踪和极值寻优的实时在线控制以及基于神经网络的预测控制等,详细分析了系统控制策略的发展历程和未来发展趋势,并总结如下:离线控制建立简单、成本低,但易受到环境因素和系统部件变化的影响而导致控制性能降低;实时在线控制策略可以实时追踪系统最大能源效率对应的排气压力,但由于寻优过程费时较长,导致控制系统的收敛时间过长;模型预测控制系统可以实现实时优化和快速收敛,有着良好的发展前景。结合新能源汽车、建筑供暖、轨道交通、商超冷藏、军工等实际场景对跨临界CO_(2)循环系统控制策略的应用特点和未来发展趋势进行分析,进一步说明了提高控制策略的适用性是未来研究的重要方向,并分析将广义预测控制、强化学习等具有自适应属性的方法应用于跨临界CO_(2)循环系统控制策略的可行性,同时探讨了开发适用于大规模循环系统和储能系统控制策略在我国“双碳”背景下的重要意义。

CO_(2)驱硅酸凝胶封窜体系的制备与性能

开发易注入、可形成有效封堵的裂缝封窜技术,对于二氧化碳驱提高采收率技术具有重要意义。本文对硅酸乙酯进行改性提高其耐温性和不溶性,再乳化形成易注入的O/W乳液。考察了乳化剂类型和乳化剂用量对胶凝过程的影响。明确了pH值、温度和矿化度等因素对凝胶性能的影响,并通过人造岩心评价了该硅酸凝胶体系的封堵性能。结果表明,20%Span-80+80%Tween-80组成的复合乳化剂乳化效果最好,当乳化用量为1%时,乳化稳定性最好,粒径均一,易注入。当环境pH小于7时,可诱导乳液形成凝胶;随着温度的升高,成胶强度增强,但在150℃高温下,成胶强度下降。升高矿化度可加速凝胶的生成,但对凝胶强度影响较小。动力学分析表明,H+浓度是影响凝胶产生的关键因素,因此可在CO_(2)驱替酸性环境中,实现地层封堵。岩心实验结果显示,该凝胶颗粒可显著降低地层渗透率,封堵效果大于80%,可满足二氧化碳驱防气窜要求。

超临界CO_(2)管道止裂韧性预测模型研究

碳中和目标下,超临界态CO_(2)管道输送已成为碳捕集利用与封存(CCUS)技术发展的必然趋势。然而,目前超临界CO_(2)管道止裂控制体系尚未构建,管材止裂韧性难以预测,成为限制其广泛应用的瓶颈问题之一。针对该问题,通过归纳国内外相关文献及规范标准,对超临界CO_(2)管道止裂控制研究进展及最新标准体系进行了简要综述;在系统收集已开展CO_(2)管道全尺寸爆破试验信息及数据的基础上,对现有止裂韧性预测模型适用性进行了讨论,由此确定了CO_(2)管道止裂韧性预测模型修正形式,并对不同模型适用范围及预测结果进行了讨论。研究结果表明,建立的修正模型解决了传统止裂预测模型过于激进的问题,同时降低了DNV推荐方法的保守性。建议将修正模型与DNN预测方法相结合,以使管材韧性值处于止裂区域;同时开展高效准确的CO_(2)管道裂纹动态扩展数值模拟。所得结果可为我国CO_(2)管道止裂设计提供指导。

CO_(2)气调对不同品种哈密瓜采后品质特征的影响

以2个山东哈密瓜品种‘晓蜜25号’及‘玫珑’为材料,研究不同CO_(2)浓度气体调控(controlled atmosphere,CA)下不同品种哈密瓜的采后品质特征变化。结果表明:随着贮藏时间的延长,不同CO_(2)浓度处理能够有效延缓不同品种哈密瓜失重率的上升,保持果实的硬度,延缓可溶性固形物以及可滴定酸含量的下降,提高过氧化物酶和过氧化氢酶的活性,延缓丙二醛含量的上升,保持抗氧化能力并在贮藏结束时仍维持较好的品质。这些结果表明,采后维持CA条件有助于改善哈密瓜的品质,延长贮藏期。

润湿性对CO_(2)溶解封存的影响机制与调控方法研究进展

溶解封存是CO_(2)封存的重要机理,储层润湿性对其具有显著影响,但目前有关润湿性对CO_(2)溶解封存效率、封存安全性等的影响机制尚不明确。为此,在分析储层润湿性与渗流关系的基础上,全面综述了润湿性对CO_(2)溶解封存的影响机理,进而提出了优化储层润湿性的调控方法。研究结果表明:①储层岩石一般为亲水性,其润湿性主要受压力、温度、地层水矿化度和岩石表面粗糙度的影响,CO_(2)-水-岩作用及储层中的有机酸作用会降低储层的水润湿性,使其变为CO_(2)润湿,不利于CO_(2)的安全封存;②CO_(2)溶解封存过程包含溶解、扩散和对流3个关键步骤,其中对流起主要作用,能增强气体分子传输、改善气液接触效果以及提高溶解速率,从而提高CO_(2)的溶解量;③润湿性对CO_(2)迁移和溶解量具有重要影响,CO_(2)润湿储层孔隙中气体扩散强度更高、气液两相界面面积更大,使CO_(2)迁移距离和溶解度增加,但不利于安全封存,而水润湿性岩石可以降低CO_(2)流动性,从而减小CO_(2)泄漏风险;④表面活性剂对于优化润湿性具有显著作用,而纳米颗粒流体可以逆转有机酸对岩石表面的作用,将CO_(2)润湿转变为水润湿或弱水润湿。结论认为:①综合考虑CO_(2)溶解封存量与封存安全性,认为水润湿储层对于CO_(2)安全封存更为有利;②通过调控优化润湿性提高储层亲水性,可以降低CO_(2)的泄漏风险,提高封存能力,从而保证CO_(2)长期封存的稳定性和安全性。

复杂煤层CO_(2)-ECBM的地质主控因素评价及有利区优选

为了探索复杂地质条件下非均质性煤层CO_(2)-ECBM实施的可行性,以新景矿区15号煤层分叉合并区为例,首先利用测井约束波阻抗反演以及时深转换技术对煤层的空间分布特征进行精细刻画,随后结合本征相干与智能蚂蚁技术实现断裂的综合预测,并对CO_(2)-ECBM地质有利区评价参数(厚度、构造、封盖条件等)进行阐述。研究结果表明,从煤岩厚度角度出发,煤储层厚度越大,CO_(2)封存效果越好。15号煤层分叉区厚度较小且存在夹矸,煤泥系统的存在导致储层,不利于煤层气的采收与CO_(2)封存。15号煤层合并区煤岩厚度相较于分叉区大,地质构造相对简单,煤层气含量较高。从围岩封盖条件出发,15号煤层合并区顶底发育厚层泥岩与灰岩,透气性差,有利于气体大面积、长期有效保存,属于典型的封闭性构造环境。对地质构造来讲,缓倾斜煤层有助于减缓CO_(2)逸散速度,并使CO_(2)更均匀地扩散到整个煤层中,且断裂不发育地区储集效果最佳,逆断层发育地区的储集效果优于正断层发育地区,因此优选15号煤层合并区倾角小于10°、断裂不发育或逆断层发育区块作为CO_(2)-ECBM潜在实施有利区。研究有助于推动该技术在类似复杂煤层中的应用,为CO_(2)在复杂煤层中的封存和注采提供依据。

煤矿区固废矿化固定封存CO_(2)与减污降碳协同处置利用的研究进展

“双碳”战略目标对煤炭行业转型升级和绿色低碳发展提出了新要求。以煤为主的能源结构和煤炭高强度开发带来矿区固废占用土地空间、破坏生态环境和排放温室气体,已成为制约煤炭行业绿色低碳发展的突出问题之一。基于“利废固碳、从哪里来到哪里去”的理念,探寻煤矿区固废无害化、减量化、资源化、低碳化的处置新路径,创新发展矿区固废处置、采空区地下空间充分利用、CO_(2)捕集利用与封存(CCUS)相融合的关键技术,是“双碳”目标下我国矿区绿色低碳发展的紧迫需求。研究工作表明:煤矸石、粉煤灰、炉底渣和煤气化渣等矿区固废在矿山地下空间充填开采与沉陷治理、煤矿防灭火、建筑用材及农业等领域的资源化利用路径与处置技术已取得重要进展,为矿区固废固定封存CO_(2)研究提供了基础和启示,但矿区固废固定封存CO_(2)的工程化技术研究亟待加强;矿区固废矿化固定与封存CO_(2)潜力大、具有工程可行性,正在形成矿区固废处置-煤基CCUS-采空区充填新的技术体系;矿区固废与CO_(2)基气-液-固三相介质矿化强化、高效吸收与矿化固碳调控技术、地下空间矿化固碳充填与CO_(2)密闭封存、采空区充填固定封存CO_(2)潜力评价与碳去除量核算、采空区充填固定封存CO_(2)环境与安全性评价等将构成固废处置-煤基CCUS-采空区充填技术体系的核心内涵;矿区固废处置–煤基CCUS–采空区充填技术是未来实现“煤炭生产加工-矿区固废处置-高效矿化固碳与CO_(2)封存-地下空间充填与利用-矿区地面沉陷防治与生态修复”的无废矿山循环经济模式的关键,矿区固废+CO_(2)基地下充填与封闭功能材料研发是重要突破口。矿区固废处置、煤基CCUS、采空区充填与地下空间利用、矿区生态修复保护等融合技术研发应用为绿色低碳型矿山建设提供了新的发展思路。

跨临界CO_(2)热泵空间应用研究展望

随着中国深空探测事业的发展,建立月球基地成为未来载人航天活动的趋势,采用基于跨临界CO_(2)热泵的热控系统可以实现高效散热,具备降低辐射器面积和热控系统重量的应用潜力。对跨临界CO_(2)热泵空间应用具备的优势进行了总结,包括实现辐射器高效散热、热泵系统更高性能系数、压缩机体积更小等。同时指出了跨临界CO_(2)热泵空间应用存在的难题,包括现有热力学模型无法适应空间应用、热泵在低/微重力下油气分离效率低等。基于现存的难题,提出了未来的研究重点,以指导跨临界CO_(2)热泵的后续研究及空间应用。

具有高传质和亲和表面的NH_(2)-UIO-66基疏水多孔液体用于增强CO_(2)光还原

增加光催化剂表面的CO_(2)浓度有助于提高光催化还原CO_(2)的反应动力学速率。然而,CO_(2)在水相中的低溶解度和较差的传质严重阻碍了CO_(2)在活性位点的吸附和转化。在本工作中,将疏水性液体端长链(PDMS)接枝到金属有机骨架(NH_(2)-UIO-66)的氨基位点上,合成了具有强疏水性的多孔液体光催化剂(NH_(2)-UIO-66 PL)。研究发现,具有永久孔隙率的NH_(2)-UIO-66 PL能够使大量CO_(2)富集在多孔液体的空腔中,便于CO_(2)的快速运输并扩散到光催化剂表面。通过接枝疏水性PDMS形成具有高正电位的CO_(2)亲和表面和活化还原反应的关键中间体,从而形成更强的电子富集Zr活性位点,增强整体的光还原CO_(2)能力。NH_(2)-UIO-66 PL的CO产率为24.70μmol·g^(-1)·h^(-1),CH_(4)产率为7.93μmol·g^(-1)·h^(-1),分别是亲水性NH_(2)-UIO-66的2.3倍和2.7倍。这项研究提供了一种新颖的疏水性多孔液体的设计,为高CO_(2)吸附和还原提供了工业应用的可能性。

高盐低渗透油藏CO_(2)泡沫微观尺度耐盐性及调驱效果

针对高盐低渗透油藏CO_(2)驱存在的气窜问题,以长庆油田H3区块为研究对象,构建SiO_(2)纳米颗粒强化CO_(2)泡沫体系,从泡沫流变性、气液界面张力、气泡液膜厚度与渗透性、泡沫微观结构4个方面评价泡沫体系耐盐性;通过开展SiO_(2)纳米颗粒强化CO_(2)泡沫体系并联岩心调驱实验,研究该体系调驱效果。根据实验结果,在油藏条件下,构建出配方为质量分数0.20%(OW-1)+0.30%(OW-4)+0.05%(SiO_(2))纳米颗粒强化CO_(2)泡沫体系,该泡沫体系的综合指数为36834 mL·min;该泡沫体系的微观尺度耐盐性评价结果表明,矿化度46357 mg/L与矿化度500 mg/L的配液相比,泡沫流变性更好,气液界面张力在10 MPa时仅增加1 mN/m,液膜渗透性增加了0.14 cm/s,但仍具有良好的泡沫骨架结构,该泡沫体系具有良好的耐盐性。此外,在并联岩心渗透率级差为15.55的条件下,该SiO_(2)纳米颗粒强化CO_(2)泡沫体系对岩心剖面改善率达到了97.28%,采收率显著提升,展现出良好的调驱能力。

致密油藏注CO_(2)防窜体系研究进展

致密油藏注CO_(2)不仅可以实现增压、混溶、降黏等目的,也是CO_(2)就地埋存和高效利用的重要途径。受CO_(2)与原油流度差异,特别是储层非均质性的影响,致密油藏注CO_(2)极易沿优势通道(裂缝)窜逸,因此,CO_(2)防窜是实现CO_(2)埋存和高效排驱的关键。通过对致密油注CO_(2)防窜体系的国内外研究动态进行综述,对比评述了凝胶、聚合物、泡沫、表面活性剂的防窜机理,重点概述了CO_(2)响应性表面活性剂的类型、CO_(2)响应特征及智能暂堵机制,在此基础上对致密油注CO_(2)防窜体系的应用前景进行了展望。依据现阶段CO_(2)响应性表面活性剂在CO_(2)防窜体系的应用,提出了CO_(2)响应性表面活性剂在CO_(2)防窜体系的重点研究方向:①设计和研发具备超临界CO_(2)可溶性,开关乳液、囊泡、凝胶、“蠕虫状”胶束自组装及原油触发解组装3方面特点的CO_(2)响应性表面活性剂;②CO_(2)响应性表面活性剂在致密储层的渗流规律、对裂缝的封堵机制、原油触发的解堵机理等系列科学问题亟需系统性探讨和深入研究。

超临界CO_(2)管道与天然气管道断裂行为

管道止裂控制的核心是其止裂韧性的预测,针对早期天然气管道建立的经典止裂预测方法对于超临界CO_(2)管道不再适用,揭示导致此现状的原因需理清二者断裂行为间的差异。对现有天然气管道裂纹动态扩展模拟方法进行修正,使其适用于超临界CO_(2)管道;基于爆破试验对修正后的超临界CO_(2)管道裂纹动态扩展模拟方法进行验证,借助经验证后的数值模拟方法对超临界CO_(2)管道与天然气管道裂纹扩展过程中管内压力分布规律、裂纹扩展长度、裂纹扩展速度等断裂行为进行系统对比。结果表明,两管道裂尖后压力分布差异是导致天然气管道止裂控制方法对超临界CO_(2)管道不再适用的主要原因,相较于天然气管道,超临界CO_(2)管道更不易止裂,断裂后果更为严重,揭示了超临界CO_(2)管道与天然气管道断裂行为差异。

致密油藏CO_(2)驱响应性防气窜体系的制备及性能

以3-二甲胺基丙胺(NNDP)和油酸为原料,制备了具有叔胺结构的CO_(2)响应性单体N,N-二甲基油酸酰胺丙基叔胺(DOAPA),将其与阴离子表面活性剂对甲苯磺酸钠(SPTS)复配,构建了具有CO_(2)响应性的蠕虫状胶束(CO_(2)-TWMS)。通过考察CO_(2)-TWMS与CO_(2)接触前后的电导率、化学结构和微观形貌变化表征了体系的响应性,结合其表面活性变化及致密基质/裂缝双重介质CO_(2)驱替与CO_(2)-TWMS防气窜过程中的压力和采收率变化,揭示了CO_(2)-TWMS防气窜性能与机制。结果表明,当n(SPTS)∶n(DOAPA)=1∶1时,CO_(2)-TWMS的黏度最大(4125 mPa·s)。CO_(2)和N2能够刺激CO_(2)-TWMS电导率在0.90~1.95 mS/cm之间可逆变化,诱导微观形貌在蠕虫状胶束和球形胶束间转换。此外,CO_(2)能够将CO_(2)-TWMS临界胶束浓度(CMC)从0.63 mmol/L(未通入CO_(2))降至0.25 mmol/L,最低表面张力从30.2 mN/m(未通入CO_(2))降至29.1 mN/m,CO_(2)-TWMS在气液界面的吸附效率和效能增强,有利于胶束的形成。在致密基质/裂缝双重介质中,CO_(2)诱导蠕虫状胶束形成,增大驱替过程中的压力,扩大CO_(2)驱替波及率,采收率提高22.6%。

基于二维蛭石纳米片混合基质膜分离CO_(2)/CH_(4)性能研究

本研究以聚醚-聚酰胺嵌段共聚物(Pebax)为高分子膜基质,二维蛭石纳米片(VMT)为填充剂,制备不同填充量的混合基质膜(Pebax-VMT MMMs)。利用蛭石纳米片的结构以及其在混合基质膜内的排列方式,为CO_(2)构筑传输通道,同时提高膜对CO_(2)/CH_(4)的分离性能。通过对Pebax-VMT MMMs的表征和气体分离特性进行研究,结果表明,填充VMT后混合基质膜在CO_(2)/CH_(4)体系中的分离效果明显增强。当VMT填充量为5 wt%时,Pebax-VMT MMMs表现出了最优的CO_(2)分离性能,CO_(2)的渗透量为489.31 Barrer, CO_(2)/CH_(4)的选择性为39.96,与纯Pebax膜相比,CO_(2)渗透量增加98.3%,同时CO_(2)/CH_(4)的选择性增加84.2%。

CO_(2)驱油用增稠剂体系研究现状及展望

CO_(2)驱油技术(CO_(2)-EOR)能够在提高原油采收率的同时,将部分CO_(2)封存于地质体中,是一项“双赢”的技术。但由于原油与CO_(2)之间黏度相差较大以及油藏的非均质性,CO_(2)驱油过程极易发生气窜,气窜后CO_(2)驱油产量明显降低,在CO_(2)中加入增稠剂提高CO_(2)黏度是解决气窜问题最直接有效的方法。综述了目前国内外用于增稠CO_(2)的聚合物,即含氟类、硅氧烷类、碳氢类以及含氧烃类聚合物,对现有聚合物CO_(2)增稠剂的研究效果和其优缺点进行了对比分析。分析认为,在增稠CO_(2)提高CO_(2)驱油效率的研究和现场应用中,首选碳氢类和含氧烃类聚合物CO_(2)增稠剂,并总结得出有效的聚合物增稠剂应具备亲CO_(2)疏水基团和增稠基团、无规聚合、平均分子量为6000~15000的分子结构。目前尚未有兼具有效、经济和环保的CO_(2)增稠剂产品,因此设计和合成价格更便宜、无氟、无毒、环保、高可溶性的CO_(2)增稠剂是未来的研究方向。