Development of degradable pre-formed particle gel(DPPG)as temporary plugging agent for petroleum drilling and production

Temporary plugging agent(TPA)is widely used in many fields of petroleum reservoir drilling and production,such as temporary plugging while drilling and petroleum well stimulation by diverting in acidizing or fracturing operations.The commonly used TPA mainly includes hard particles,fibers,gels,and composite systems.However,current particles have many limitations in applications,such as insufficient plugging strength and slow degradation rate.In this paper,a degradable pre-formed particle gel(DPPG)was developed.Experimental results show that the DPPG has an excellent static swelling effect and self-degradation performance.With a decrease in the concentration of total monomers or cross-linker,the swelling volume of the synthesized DPPG gradually increases.However,the entire self-degradation time gradually decreases.The increase in 2-acrylamide-2-methylpropanesulfonic acid(AMPS)in the DPPG composition can significantly increase its swelling ratio and shorten the self-degradation time.Moreover,DPPG has excellent high-temperature resistance(150°C)and high-salinity resistance(200,000 mg/L NaCl).Core displacement results show that the DPPG has a perfect plugging effect in the porous media(the plugging pressure gradient was as high as 21.12 MPa),and the damage to the formation after degradation is incredibly minor.Therefore,the DPPG can be used as an up-and-coming TPA in oil fields.

Degradable preformed particle gel as temporary plugging agent for low-temperature unconventional petroleum reservoirs:Effect of molecular weight of the cross-linking agent

The development of unconventional petroleum resources has gradually become an important succession for increasing oil production.However,the related engineers and researchers are paying more and more attention to the application of temporary plugging agents(TPAs)for their efficient development.TPAs can expand the stimulated reservoir volume(SRV)and facilitate the flow of oil and gas to the bottom of the well.Particle-gels used as temporary plugging agents have the characteristics of the simple injection process,good deformation,high plugging strength,and complete self-degradation performance,which have been widely applied in recent years.In this paper,five samples of DPPG polymerized by different molecular weights of cross-linking agents were prepared.In addition,infrared spectroscopy analysis,differential calorimetry scanning(DSC)analysis,static particle gel swelling and degradation performance evaluation experiments,and dynamic temporary plugging performance experiments in cores were conducted at 34°C.Results show that as the molecular weight of the cross-linking agent(at 0.01 g)in the DPPG molecule decreased from 1,000 to 200 Da,the fewer cross-linking sites of DPPG,the looser the microscopic three-dimensional mesh structure formed.The swelling ratio increased from 7 to 33 times.However,the complete degradation time increased from 40 to 210 min.Moreover,the DSC results confirmed that the higher the molecular weight of the cross-linking agent,the worse is chemical stability and the more prone it to self-degradation.DPPG samples had good temporary plugging performance in reservoir cores.DPPGs prepared by the cross-linking agent with smaller molecular weight has a stronger swelling ratio,higher gel strength,and greater plugging strength in the core permeabilities.Moreover,the degraded DPPG is less damaging to the cores.However,their slower degradation rates take a slightly longer times to reach complete degradation.The results of this paper can provide new ideas and a theoretical basis for the development of particle gel-type temporary plugging agents(TPA)with controllable degradation time in low-temperature reservoirs.It can help to expand the application range of existing DPPG reservoir conditions.

大庆油田聚驱后油层无碱中相自适应堵调驱实验

大庆油田聚驱后弱碱复合驱扩大现场试验取得了聚驱后进一步提高采收率13.5百分点的较好效果,但体系中碱的存在导致管线、泵产生腐蚀、结垢和采出液出现严重乳化破乳难等问题。同时,由于优势渗流通道的存在,流度控制难,致使体系中聚合物质量浓度高达2500 mg/L。为解决上述问题并实现更大幅度提高采收率,需研发出适用于大庆油田聚驱后油层的高效中相微乳液驱油体系。通过对表面活性剂溶液的界面张力进行测量,初步筛选出能够达到超低界面张力的表面活性剂产品,然后进行中相微乳液体系水溶性评价,并开展了较为完善的油水相态评价,进一步确定中相微乳液体系的最佳盐度(盐的质量分数)及其与油水比的关系,从而研发出无碱中相微乳液配方,并加入预交联颗粒凝胶(PPG)组成无碱中相自适应堵调驱体系。岩心驱替实验结果表明,该体系聚驱后可进一步提高采收率23.3百分点,比常规弱碱复合驱多提高采收率10.1百分点,降低聚合物用量28%。研究成果为大幅提高大庆油田聚驱后油层的采收率提供了理论及实验支撑。

油田采出液中黏弹性颗粒驱油剂PPG的检测新方法

高效液相色谱法是目前检测油田采出液中聚合物含量的最简便灵敏的方法,但该方法只能对聚合物的总量进行检测。在实际应用中,为了提高驱油效率,常常会将部分水解聚丙烯酰胺HPAM和黏弹性颗粒驱油剂PPG进行复配使用,为了实现含有HPAM的油田采出液中PPG液相色谱的检测,提出了一种新的样品前处理方法,即利用HPAM和PPG结构上的差异,在样品中分别加入交联剂和破胶剂,使HPAM从溶液中沉淀出来,而PPG仍然保留在溶液中,以排除液相色谱检测PPG时HPAM的干扰。结果表明,样品中加入硝酸铝交联剂(硝酸铝、聚合物总量比=10:1)3 min后,加入破胶剂H_2O_2(H_2O_2、聚合物总量比=150:1),可以实现HPAM的完全沉淀,进而实现PPG的液相色谱检测。该方法具有很好的精确度和加标回收率,线性范围:10~200 mg/L,最低检测限为5 mg/L。

聚驱后B-PPG与HPAM非均相复合驱提高采收率技术

通过单填砂管流动实验中阻力系数的测量,对聚驱后支化预交联凝胶颗粒(B-PPG)与水解聚丙烯酰胺(HPAM)复配的非均相体系的封堵性能进行了评价,优选出了封堵能力最佳的BPPG、HPAM非均相体系;通过渗透率不同的双填砂管驱油实验和微观驱油实验,研究了聚驱后非均相体系的调剖与驱油能力。单管封堵实验结果表明:B-PPG与HPAM复配的非均相体系,能够对填砂管进行有效封堵,显著提高聚驱后填砂管阻力系数和残余阻力系数,HPAM与B-PPG按质量比例6∶4(干重)配制时封堵效果最好。双管调驱实验结果表明:非均相体系调驱能够明显改善聚驱后高渗管和低渗管的分流比,使剩余油动用程度较低的低渗管采收率大幅提高。微观实验表明:非均相体系提高聚驱后采收率方式主要靠增大驱替液的波及系数来实现。

B–PPG非均相复合体系对滤砂管通过性能实验研究——以胜利海上油田为例

非均相复合驱油技术是一种新型驱油技术,该驱油体系利用黏弹性颗粒驱油剂B–PPG的驱替性能,与聚合物复配之后扩大波及能力,叠加表面活性剂超低界面张力带来的洗油能力,从而获得最佳的驱油效果。本文针对胜利海上油田非均相复合驱,开展了I型、II型、III型三种型号B–PPG非均相复合体系通过低剪切滤砂管性能的实验。结果表明,I型B–PPG非均相复合体系在通过滤砂管时,未发生堵塞,黏度保留率和粒度保留率良好;II型B–PPG非均相复合体系通过滤砂管时,在高排量条件下黏度有一定的损失;III型B–PPG非均相复合体系在高排量条件下存在较大的堵塞风险,且黏度损失较大。

基于可视化实验和分形维数的B-PPG微观驱油特征研究

黏弹性颗粒驱油剂(B-PPG)调驱是高含水老油田进行剩余油挖潜、进一步提高采收率的高效驱替方式之一。结合可视化驱油实验和分形维数理论对B-PPG微观驱油特征进行研究,有助于增强其油藏适应性和矿场增油效果。结果表明,B-PPG驱相对于水驱分形维数更低、驱替前缘更均匀、突破时间更长,能够有效扩大波及范围;B-PPG驱提高采收率值随孔喉比的增大和配位数的减小而增大,即非均质性较强、连通关系较差时,B-PPG驱能够大幅改善水驱开发效果;B-PPG颗粒的粒径与孔喉结构之间存在匹配关系,对于配位数为3、孔喉比为3.0的可视化模型,50~70目的B-PPG驱突破时分形维数最小、提高采收率值最大,矿场实施B-PPG驱时应合理优选B-PPG粒径。

主客体包合超分子凝胶颗粒调剖剂的制备及性能评价

预交联凝胶颗粒(PPG)被广泛用于治理油藏水流优势窜流通道,起到稳油控水的效果。为了解决常规共价结构的PPG强度不足、剪切恢复性能差以及不耐盐的问题,以烯丙基-β-环糊精(烯丙基-β-CD、主体功能单体)、十六烷基二甲基烯丙基氯化铵(C16DMAAC、客体功能单体)、N,N’-亚甲基双丙烯酰胺(MBA、交联剂)和丙烯酰胺(AM)为主要原料,研制了一种具有剪切恢复性能的共价-非共价协同交联结构的主客体包合超分子凝胶颗粒(S-PPG)调剖剂。采用流变仪、激光粒度分析仪、光学显微镜系统探究了S-PPG的流变性能、膨胀性能和耐盐性能。结果表明,主客体单体的最佳加量为总单体物质的量的2.5%与2.5%的S-PPG在地层水中膨胀24 h后,质量分数为0.6%时的弹性模量为73 Pa,是常规PPG的3.04倍;屈服应力为120 Pa,剪切黏度损失率为39%,剪切恢复性能和屈服应力均为常规PPG的4倍左右;地层水中的膨胀倍数达23。此外,随着盐含量的增加,S-PPG的膨胀性能逐渐增强,在Na Cl质量浓度为1×10^(5)mg/L下的膨胀倍数达27.9,表现出优异的耐盐性能。本文研究为油藏深部调剖提供一种具有潜力的抗剪切S-PPG材料。

非均相复合驱油体系界面性质的影响因素

针对聚驱后油藏特点研发了黏弹性颗粒驱油剂(B-PPG)。文中研究了黏弹性颗粒驱油剂溶液与煤油间的界面张力和扩张流变性质,考察了盐度、二价离子和温度对体系界面张力及扩张流变参数的影响。结果表明,高浓度时,B-PPG通过烷基链的疏水作用形成了二维网络结构,提升了界面膜的强度,临界缔合浓度为1000mg/L。NaCl压缩双电层,增大了B-PPG分子的界面吸附量,界面张力显著降低;同时,由于分子间静电相互作用减弱,扩张弹性急剧降低,而扩散交换的加快导致扩张黏性降低。二价阳离子的加入,造成界面分子排列的紧密程度有所降低,界面张力略有升高。二价阳离子还可以增强B-PPG形成的聚集体结构,导致扩张弹性略有增大。升高温度,加速了B-PPG分子的热运动,扩散交换过程变快,界面膜强度降低。

Migration characteristics and profile control capabilities of preformed particle gel in porous media

Inspired by the viscoelastic displacement theory,a product called preformed particle gel(PPG)is developed as conformance control agent to enhance oil recovery and control excess water production.The migration law of PPG suspension in porous media is related to its deep profile control and displacement capability.Laboratory experiments indicate that PPG suspension has good viscosity increasing,and the apparent viscosity decreases with the increase of shear rate.PPG suspension is mainly elastic,and its network structure makes it have certain shear stability.PPG particles realize migration in porous media in the way of“accumulation and blockage/pressure increase/deformation and migration”.When the ratio of the PPG particle size to the pore throat diameter d ranges from 35.52 to 53.38,the particles can match through the porous medium.When the permeability difference of the parallel model is 5,PPG suspension has the highest profile improvement rate,69.10%.PPG suspension can adjust the planar heterogeneity,and increase the oil recovery rate by 20.75%.The PPG suspension can effectively start“cluster"、“film”and“blind end residual oil”,and has a high oil washing efficiency.The core NMR T2 spectrum shows that PPG suspension mainly reduces oil saturation in mesopores and macropores.After PPG flooding,the EOR capacity of small pores is the highest,39.11%.

粘弹性颗粒驱油剂的流变特性

粘弹性颗粒驱油剂B-PPG是一种全新的驱油剂,具有部分交联、部分支化的分子结构,分散于水中形成非均相的B-PPG悬浮液。采用稳态剪切和动态振荡实验,研究了不同质量分数、不同交联度的B-PPG在不同矿化度盐水中的流变特性,并分析其产生机理。结果表明,B-PPG悬浮液具有优异的粘弹性、耐盐性和增粘性。随着B-PPG交联度的增加,B-PPG悬浮液粘度呈下降趋势,B-PPG悬浮液粘性与弹性模量交点处频率(Fc)逐渐趋向低频;高矿化度使部分水解聚丙烯酰胺(HPAM)溶液的弹性减弱,而对B-PPG悬浮液模量影响较小,表明B-PPG较HPAM具有更优异的耐盐性;随着B-PPG质量分数的增大,B-PPG悬浮液线性粘弹区范围增大,且粘度明显增大,B-PPG悬浮液更加偏离牛顿流体,Fc值逐渐趋向低频;通过对其动态振荡曲线的线性拟合数据发现,B-PPG悬浮液表现出弱凝胶特性。

预交联聚合物凝胶颗粒分散体系的流变性能

采用HAAKERS600型流变仪、膜过滤实验及激光粒度仪和光学显微镜，研究了预交联聚合物凝胶颗粒分散体系的流变性能、封堵性能和颗粒的形态、大小。结果表明，预交联聚合物凝胶颗粒分散体系的表观黏度和弹性随溶胀时间的增加而上升；当溶胀时间为10～15d时，体系的表观黏度达到最大值；随剪切速率增加，体系的表观黏度降低，表现出明显的假塑性体系的性质，而且为非依时性体系。预交联聚合物凝胶颗粒的固体特性较明显，能够对1．2um的纤维素膜形成一定的封堵，且随溶胀时间增加，其封堵能力先增加后降低。预交联聚合物凝胶颗粒的粒径随溶胀时间的增加而增大，10d之内溶胀较快，10d之后粒径基本保持不变。溶胀后的预交联聚合物凝胶颗粒大小是溶胀前的几倍至十几倍。

预交联凝胶调驱剂的研究现状与应用进展

综述了预交联凝胶调驱剂的实验室合成研究和矿场应用进展,重点介绍了PPG性能改良(包括耐温耐盐性能、柔性弹性及小尺度智能材料及缓膨性能改良)及预交联凝胶调驱剂在高盐高温油藏、低温低盐砂岩厚油层、聚驱应用及复合使用弱凝胶封堵高渗区域和大裂缝中的应用。并对预交联凝胶调驱剂的发展方向进行了展望。参考文献48篇。

部分水解的预交联凝胶型聚丙烯酰胺的水化层结构

部分水解的预交联凝胶型聚丙烯酰胺在水溶液中的吸水溶胀能对油藏高渗透区域产生有效封堵,有利于提高驱油效率.分子模拟结果表明,凝胶颗粒的溶胀主要归因于侧链亲水基团在水溶液中的水化作用,这些带负电的亲水基团中心原子通过氢键和静电作用在其周围极化出一层排列规整、有序而紧密的水化层,并将水分子束缚其中;同时水化层内的水分子之间依赖氢键网络促进水化层的稳定.本文从微观结构、动力学和氢键等方面比较了各亲水基团中心原子的水化能力,发现—COO-官能团具有较强的束缚水分子的能力,对水化层的稳定有重要影响.

聚合物驱后油藏提高采收率技术研究

根据室内实验和现场试验效果分析了聚合物驱后油藏进一步提高原油采收率的技术潜力。室内驱油实验表明,聚合物+表面活性剂二元复合驱提高采收率为17.6%～20.1%,提高采收率幅度高于单一表面活性剂驱(3%左右)和单一聚合物驱(11%～15%),高于表面活性剂驱和聚合物驱二者之和,优于同等经济条件下聚合物驱的效果。孤岛中一区Ng3-6和孤东六区聚合物注入完成后接着实施二元复合驱,综合含水进一步下降,日产油量明显增加。聚合物溶液中加入粘弹性颗粒PPG(Preformed Particle Gel)后,体系从偏粘性转变为偏弹性,具有较强的剖面调整能力。2009年2月在聚合物驱转后续水驱多年的孤岛中一区Ng3单元实施聚合物+PPG驱,注入压力上升了1.4MPa,油层纵向非均质性明显改善,纵向各层吸水趋于均匀。

预交联聚合物凝胶颗粒对乳状液稳定性影响

用界面张力仪、表面粘弹性仪和Zeta电位仪测定了胜利孤东原油模拟油与含预交联聚合物凝胶颗粒溶液间的界面特性,并研究了预交联聚合物凝胶颗粒浓度对这些界面特性及乳状液稳定性的影响。结果表明,去离子水中加入预交联聚合物凝胶颗粒后,去离子水及模拟水与原油模拟油间的界面张力和界面剪切粘度及油滴表面的Zeta电位绝对值均增大,原油与预交联聚合物凝胶颗粒溶液间所形成的W/O型和O/W型乳状液稳定性均随聚合物凝胶颗粒浓度增加而增强。

非均相复合驱油体系设计与性能评价

为进一步提高聚驱后油藏采收率,针对聚驱后油藏非均质性强、剩余油普遍分布的特点,提出了非均相复合驱油体系。非均相复合驱油体系包括黏弹性颗粒驱油剂(PPG)、表面活性剂和聚合物。通过研究黏弹性颗粒驱油剂的溶胀能力、黏弹性、滤过能力和在岩心中运移性能,及其与表面活性剂、聚合物之间相互作用,得到了适合于胜利高温高盐油藏和聚合物驱后油藏的非均相复合驱油体系1000mg/L PPG+1000mg/L聚合物+0.3%胜利石油磺酸盐+0.1%非离子表面活性剂1709。结果表明,PPG可遇水溶胀,耐盐性能好,在油藏中具有封堵和运移性能,较单一聚合物能够更好地提高波及体积。在含水98%条件下注入0.3倍孔隙体积的非均相复合驱油体系,聚合物驱后提高采收率13.6%(OOIP)。该体系可应用于高温高盐油藏或聚合物驱后油藏大幅度提高采收率。

新型非均相复合驱油方法

利用流变仪、界面张力仪、激光粒度仪、微观驱油和驱油物理模拟等装置,通过实验筛选出了驱油用黏弹性颗粒驱油剂(PPG)样品,评价了其应用性能;研究了PPG与聚合物及表面活性剂间的相互作用规律,设计了非均相复合驱油体系,评价了其在胜利油田高温高盐、聚合物驱后油藏条件下的提高采收率效果。结果表明,驱油用PPG能够在多孔介质中运移并通过在孔喉处的堆积—堵塞—压力升高—变形通过来改变已形成的优势通道,具有比聚合物更强的扩大波及能力。PPG与聚合物复配后能够增强体系的黏度与黏弹性能,因而PPG与表面活性剂和聚合物组成的非均相复合驱油体系具有比聚合物驱更强的扩大波及体积能力和与复合驱相似的洗油能力。在双管模型渗透率级差为(1 000∶5 000)×10-3μm2时,在胜利油田高温高盐油藏条件下可提高采收率22.5%,在胜利油田孤岛中一区Ng3聚合物驱后的油藏条件下,可进一步提高采收率19.1%。

预交联凝胶颗粒调驱研究(英文)

针对延长油田地下交联凝胶调驱存在的问题,提出并开展了预交联凝胶颗粒性能评价及调驱实验研究。实验结果显示,选择的预交联颗粒具有良好的吸水膨胀性能,在延长油藏条件下(矿化度41 811 mg/L,温度80℃),15 d后颗粒粒径可膨胀至几百纳米,表明微球具有一定的耐温耐盐性;预交联颗粒对单管填砂模型具有较好的封堵效果,且能运移到模型深部,表明颗粒适合深部调驱的需要;颗粒具有良好的变形能力,且能够高强度封堵高渗透层,显示出良好的剖面改善能力;预交联颗粒可分别提高高、低渗管采收率16%、26%,使并联双管总采收率最终达到75%,表明高剩余油条件下,预交联颗粒能封堵高渗透层,从而有效启动低渗透层。

非离子表面活性剂Triton X-100与预交联凝胶颗粒的相互作用

研究了非离子表面活性剂Triton X-100在调堵剂预交联凝胶颗粒(PPG)上的吸附和脱附特性,其吸附等温线符合Langmuir型吸附,吸附在颗粒上的表面活性剂能够被后续注入水逐渐洗脱下来,仍然可以提高原油采收率。利用激光粒度仪研究了Triton X-100对PPG膨胀性的影响规律,发现吸附后PPG的粒径减小。稳态和动态流变性实验研究表明,随着Triton X-100浓度的增加,溶胀后的PPG逐渐表现出假塑性流体特征,储能模量逐渐降低,PPG的注入性和运移性得到提高。