Synthesis and evaluation of an oil-soluble viscosity reducer for heavy oil

To reduce the viscosity of highly-viscous oil of the Tahe oilfield （Xinjiang,China）,an oilsoluble polybasic copolymer viscosity reducer for heavy oil was synthesized using the orthogonal method.The optimum reaction conditions are obtained as follows：under the protection of nitrogen,a reaction time of 9 h,monomer mole ratio of reaction materials of 3：2：2 （The monomers are 2-propenoic acid,docosyl ester,maleic anhydride and styrene,respectively）,initiator amount of 0.8% （mass percent of the sum of all the monomers） and reaction temperature of 80 oC.This synthesized viscosity reducer is more effective than commercial viscosity reducers.The rate of viscosity reduction reached 95.5% at 50 oC.Infrared spectra （IR） and interfacial tensions of heavy oil with and without viscosity reducer were investigated to understand the viscosity reduction mechanism.When viscosity reducer is added,the molecules of the viscosity reducer are inserted amongst the molecules of crude oil,altering the original intermolecular structure of crude oil and weakening its ability to form hydrogen bonds with hydroxyl or carboxyl groups,so the viscosity of crude oil is reduced.Field tests of the newly developed oil-soluble viscosity reducer was carried out in the Tahe Oilfield,and the results showed that 44.5% less light oil was needed to dilute the heavy oil to achieve the needed viscosity.

Study on Viscosity Reducing and Oil Displacement Agent for Water-Flooding Heavy Oil Reservoir

In the process of water-flooding development of heavy oil reservoir,due to the high viscosity and oil-water mobility ratio of heavy oil,there are some problems such as poor fluidity,high residual oil saturation and low recovery efficiency,which seriously restrict the efficient development of heavy oil.The molecular structure characteristics of asphaltenes and resins in heavy oil were analyzed.Based on the three most concerned properties of chemical agents,including the emulsification performance,the interface performance and the oil washing performance,three chemical oil displacement agents for heavy oil reservoirs were developed,and the structure of the chemical agents were characterized by high resolution mass spectrometry.The performance evaluation of chemical agents and core displacement experiments show that there is no obvious correlation between the properties of chemical agents,including interfacial tension,emulsifying ability and oil washing ability.For heavy oil reservoirs,the emulsification and viscosity reduction performance of chemical agents was more important than the oil washing capacity,and the oil washing capacity was more important than the interface performance.Viscosity reduction performance was the key parameter of oil displacement agent suitable for heavy oil reservoir.The composite binary system consisting of the viscosity reducer and the polymer had better oil recovery than using viscosity reducer alone.

The Viscosity-reducing Mechanism of Organic Wax Additive on CRMA

CRMA was prepared by mixing PG 64-22 asphalt with crumb rubber powder of 40 mesh size and 18% by weight of the asphalt. Sasobit, a typical organic wax additive, was selected and added into CRMA. A series of tests, namely, brookfield viscosity, environmental scanning electron microscope（ESEM）, component test, differential scanning calorimeter（DSC）, fourier transform infrared spectroscopy （FTIR） and nuclear magnetic resonance （NMR） were conducted on CRMA with and without organic wax additive, and microcosmic appearance, component content and molecular structure of various asphalt binders were obtained. The test results indicate that the addition of Sasobit~ into CRMA can effectively change the contents of components： the content of asphaltenes increases relatively, while saturates decreases. In addition, the interaction between various components of CRMA is weakened, and the state of equilibrium between the dispersant and dispersed phase is changed at the same time. That is why the viscosity decreases after the organic wax additive is added into CRMA.

Rheology of typical emulsifiers and effects on stability of emulsion explosives

Structure of emulsifiers or functionality and molecular weight determines its rheology, emulsification and stability of emulsion explosives. Rheology of typical emulsifiers was studied by automatic rheometer. Relations between rheology and structural properties of typical emulsifiers were analyzed. Experimental results show that viscosity of emulsifiers didn＇ t change with shear rate at room temperature and appeared properties of Newtonian fluid. Viscosity of different component emulsifiers declines with temperature in different modes. The change of strain doesn＇ t affect modu- lus of emulsifiers. Loss modulus increases linearly with the increase of frequency in oscillation and storage modulus does non-linearly. The higher the temperature is, the lower change amplitude of loss modulus with frequency will be. The emulsifiers with imide and amide functionality for emulsion explosives have better shear properties at high temperature and better shapingness and stability at room temperature than other emulsifiers with ester and Sorbin Monoleate （SMO） functionality.

Hydrophobic and Magnetic Reduced Graphene Oxide Nanocomposite for Emulsified Oil Removal

Magnetic reduced graphene oxide(MRGO) nanocomposite was prepared by the chemical coprecipitation method and applied as adsorbent for removing emulsified oil from oily wastewater. SEM, TEM, XRD, FT-IR, VSM and other analytical methods were utilized to characterize the prepared MRGO. The adsorption performance of MRGO was evaluated under different initial adsorbate concentration, MRGO dosage, temperature, and pH value of the solution. The adsorption kinetics and isotherms were investigated. In addition, the MRGO repeatability was also tested. It was found that almost 65%of emulsified oil were removed by MRGO in the first 15 min. The MRGO adsorption capacity and efficiency for removal of adsorbate reached 335.85 mg/g and 92.52% within 60 min, respectively. The adsorption capacity reduced with an increasing MRGO dosage, while increased with the increase of emulsified oil concentration. The adsorption performance of MRGO in the alkaline environment was lower than that in the acidic environment. The adsorption data could well fit to the pseudosecondorder model. The Langmuir model could well describe the isotherm data. The MRGO adsorption capacity was still more than 236.1 mg/g at the sixth regeneration cycle.

稠油乳化黏度测量曲线与乳液特性的关系

稠油化学驱过程中降黏剂浓度对稠油乳化影响明显,通过测量不同浓度降黏剂的稠油乳状液黏度-时间曲线,以黏度、降黏率为指标分析了黏度曲线与乳液特性的关系。结果表明,当降黏剂的浓度远大于临界乳化浓度时,形成稳定O/W乳状液,黏度低、降黏率大于95%。当降黏剂的浓度大于临界乳化浓度时,形成O/W乳状液,而后随着表面活性剂向油相的迁移,油滴聚并、分层。当降黏剂的浓度与临界乳化浓度相当时,乳状液油O/W转化为W/O,黏度大幅度提高。当降黏剂的浓度小于临界乳化浓度时,只能形成W/O乳状液。

热复合驱中热、降黏剂、气体对原油黏度的影响

为了研究热、降黏剂、气体单独对原油黏度影响,以黏度、降黏率为指标,通过高温高压流变仪研究了复合驱中热、降黏剂、气体对原油黏度的影响规律。结果表明,升高温度是降低原油黏度的最有效方式,在一定压力范围内,N2对降低原油黏度起负作用,CO_(2)对降低原油黏度起正作用,降黏剂与CO_(2)可协同作用降低原油黏度。

抗220℃高温两性离子聚合物降黏剂的制备与性能

针对当前高温高密度水基钻井液流变性调控难题,基于分子结构优化设计和单体优选,制备了新型抗高温两性离子聚合物降黏剂HP-THIN。通过正交实验与单因素实验相结合的方法,对HP-THIN的制备条件进行了优化。采用红外光谱仪、乌氏黏度计和热重分析仪等分别对HP-THIN的分子结构、热稳定性以及相对分子质量进行表征和测定,研究了HP-THIN在220℃超高温条件下对淡水浆、盐水浆、含钙浆和高密度复合盐水浆等不同类型钻井液基浆的降黏性能。在室温下,测试了HP-THIN对基浆黏土颗粒吸附能力、Zeta电位和粒径的影响,并与国内外同类产品(Polythin和xy-27)进行了对比。结果表明,合成降黏剂HP-THIN的反应温度为60℃,反应时间为3 h,引发剂用量和链转移剂用量均为反应单体总量的1%,单体总质量分数为30%;单体AM、AA、AMPS、PTM物质的量比为1.9∶7.5∶2.1∶1。该聚合物的分子结构中含有设计官能团,其黏均相对分子质量约为8211,且具有较好的热稳定性。220℃老化后,HP-THIN在最优加量(0.3%)下对淡水基浆、盐水基浆、含钙基浆和高密度复合盐水基浆的降黏率分别达86%、72%、73%和51%,HP-THIN对不同类型钻井液基浆的高温降黏效果均优于国内外同类产品,相对于xy-27和Polythin,降黏剂HP-THIN对基浆黏土吸附能力强、Zeta电位绝对值大、黏土颗粒尺寸小,可以更好地消除黏土颗粒间网状结构,降低钻井液黏度,具有良好的应用前景。

纳米N-A降黏剂的制备及性能评价

针对普通纳米降黏剂对特稠油降黏效果差、洗油效率低等问题,制备了纳米N-A降黏剂,采用FTIR,TEM等方法表征了降黏剂的微观结构,考察了降黏剂的降黏效果、界面张力以及洗油效率。实验结果表明,纳米N-A降黏剂组成为:50%(w)纳米二氧化硅溶胶+40%(w)分散剂EB-1+4.2%(w)表面修饰剂+5.8%(w)增效剂。该降黏剂分散性能良好,粒径分布在20~60 nm之间,在降黏剂含量为1%(w)、油水质量比为7∶3、200℃,矿化度为0,8829.26 mg/L条件下老化48 h,特稠油降黏后黏度分别为6280,7213 mPa·s,降黏率分别达到83.77%,81.36%,降黏性能保持率分别为96.80%,95.39%。50℃下静置90 d后降黏性能保持率大于90%,可降低油水界面张力至0.076 mN/m,乳化液滴最大粒径9.5μm,洗油效率为30.9%,相对普通降黏剂,驱油效率提高22.3百分点。

表面活性剂对水驱普通稠油油藏的乳化驱油机理

为了研究乳化降黏驱油剂对不同渗透率的水驱普通稠油油藏的驱油效率和孔隙尺度增效机理,选取了烷基酚聚氧乙烯醚(J1)、α-烯基磺酸盐类表面活性剂(J2)、十二烷基羟磺基甜菜碱(J3)、J3与烷基酚聚氧乙烯醚羧酸盐复配表面活性剂(J4)作为驱油剂,开展了4种驱油剂一维驱油和微观驱油模拟实验,明确了乳化降黏驱油剂在孔隙尺度的致效机理。结果表明,降低界面张力对提高驱油效率的作用大于提高乳化降黏率。在油藏条件下,乳化降黏驱油剂需要依靠乳化降黏和降低界面张力的协同增效作用,才能大幅提高驱油效率。乳化降黏驱油剂的乳化能力越强、油水界面张力越低,驱油效率增幅越大。当化学剂乳化降黏率达到95%时,油水界面张力从10^(-1)mN/m每降低1个数量级,化学剂在高渗透和低渗透岩心中的驱油效率依次提高约10.0%和7.8%。乳化降黏驱油剂注入初期通过降低界面张力,使得高渗透岩心和低渗透岩心中的驱替压力分别为水驱注入压力的1/2和1/3,从而提高注入能力。注入后期大块的原油被乳化形成大量不同尺寸的油滴,增强原油流动性,提高驱油效率。乳化形成的界面相对稳定的稠油油滴,能暂堵岩石的喉道和大块稠油与岩石颗粒形成的通道。油滴的暂堵叠加效应,使高渗透和低渗透岩心的驱替压差分别为水驱压差的5.2倍和32.3倍,大幅提高了注入压力,从而扩大平面波及面积。降黏驱油剂驱油实现了提高驱油效率的同时扩大波及范围。研究结果为水驱稠油开发用驱油剂的研发提供参考,为大幅提高水驱普通稠油采收率奠定基础。

稠油化学复合冷采技术研究与应用

我国稠油储量可观,其中60%的是深层稠油,而主流的蒸汽吞吐等热采技术采收率不足20%;稠油资源开发潜力极大,积极探索新的开采方式以提高采收率是石油领域高质量发展的必然选择。本文着重阐述稠油化学复合冷采技术体系构建及其现场应用,为中深层稠油的新型绿色低成本接替技术发展提供有效方案。在分析稠油组分的基础上,细致剖析稠油结构致黏机理,包括化学降黏机理、降低启动压力梯度机理、提高驱油效果机理在内的提高采收率机理,以丰富理论认识。面向工程应用亟需,从水溶性降黏剂分子设计与合成、自组装调堵剂研发两方面出发,突破稠油绿色化学驱油体系。基于发展的稠油化学复合冷采技术,完成了3个稠油油田示范工程应用,在提高产油量、控制含水率方面取得了良好成效。进一步梳理了分子采油理论与技术、渗流理论与数值模拟技术等方面的后续发展要点,以为深层稠油的绿色高效开发接替技术研究、稠油化学复合冷采技术推广应用研究等提供启发和参考。

黏重黑土条件下马铃薯收获机挖掘装置设计与试验

针对东北地区黏重黑土条件下马铃薯收获机工作阻力大、挖掘铲寿命短、挖掘质量难以保证等问题,将双行升运链式马铃薯收获机挖掘装置改进并设计一种分离式防堵马铃薯挖掘装置。采用理论分析研究方法,解析马铃薯收获机关键部件挖掘铲挖掘过程,探明影响马铃薯收获机挖掘铲工作阻力的主要影响因素;结合黏重黑土条件下马铃薯收获的农艺要求,以行驶速度、铲面铲宽和铲面倾斜角度为试验因素,以挖掘铲最大工作阻力和土壤最大压缩力为试验指标,进行多因素正交仿真试验,设计得出,挖掘铲在保证良好碎土效果且不造成马铃薯损伤的最佳参数,即行驶速度1.11 m·s^(-1),铲面铲宽150 mm,铲面倾斜角度30°时,挖掘铲最大工作阻力为566 N,土壤最大压缩力为152 N。田间验证试验表明,各项指标达到要求且均优于改进前整片式挖掘铲马铃薯收获机。

分离多环芳烃用于超稠油掺稀降黏的研究

针对炼油厂催化裂化柴油大量过剩和芳烃含量过高等问题,结合稠油掺稀降黏开采掺稀比高、稀油资源紧缺的现状,从催化裂化柴油中萃取分离多环芳烃,用于超稠油掺稀降黏研究。对多环芳烃萃取进行正交试验,在筛选出的最佳操作条件(萃取温度为45℃、萃取时间为5 min、相分离时间为5.5 min和剂油体积比为1.4)下,多环芳烃产品收率为29.87%、芳烃质量分数高达99.07%。在掺稀比均为0.10时,多环芳烃和塔河稀油的掺稀降黏量率分别为94.20%和68.58%。拟合计算结果表明,多环芳烃用量仅为塔河稀油的16.32%时,即可达到塔河油田稠油掺稀降黏要求。以塔河油田稠油自喷井为例,当稠油含水率分别为0,30%和50%时,掺入多环芳烃相对掺入稀油的单井日产油增长率分别达到115.90%,84.57%,62.20%。

克拉玛依油砂沥青油溶性降黏剂的制备及性能评价

以甲基丙烯酸十八酯、N-苄基马来酰亚胺和丙烯酰胺为原料合成了针对于克拉玛依油砂沥青的新型油溶性共聚降粘剂。对单体配比、引发剂用量、反应温度等影响条件进行了优化,探究了降黏剂用量和温度等因素对降黏效果的影响。确定了该降黏剂的聚合反应条件为:聚合单体摩尔比为10∶4∶3,引发剂用量为单体总质量的1.0%,反应温度为85℃。在降黏剂添加量1000 mg·kg^(-1),反应温度50℃,反应时间60 min时降黏效果最好,在此条件下的降黏率为35.7%。

油基钻井液乳化剂的制备与性能评价

钻井液乳化剂是油井钻探中的重要化学品之一,其性能评价对于钻井工程的成功进行具有重要意义。优秀的乳化剂能确保钻井液的稳定性和流变性能。在选择乳化剂时,应充分考虑其理化性能和体系综合性能,以确保钻井工程的成功进行。本研究以植物油酸、二乙烯三胺、马来酸酐为主要原料,制备了6种乳化剂产品,并对其进行理化性能评价和体系综合性能评价。实验结果显示,乳化剂PF-MOEMUL1、PF-MOCOAT1、PF-MOEMUL2、PF-MOCOAT2满足所有指标要求,在理化性能评价和体系综合性能评价的关键指标上有良好的性能,为钻井工程提供可靠的保证。而乳化剂PF-MOEMUL3、PF-MOCOAT3在倾点和塑性黏度方面未能达到指标要求。可能导致乳液不稳定、流变性能不佳等问题,从而影响钻井工程的顺利进行。通过对钻井液乳化剂的性能评价,对乳化剂的选择和应用提供了有效的参考指导。

稠油化学降黏剂研究进展与发展趋势

在双碳背景下,以热采为主的稠油开采技术如何经济、高效、绿色地提高稠油采收率是研究者关注的重点问题。实现稠油油藏的商业开采,其本质是降低稠油黏度,提高流动能力。文章系统分析了稠油的致黏机理以及各类降黏剂的降黏机理,总结了乳化降黏剂、油溶性降黏剂、纳米降黏剂的合成工艺,评价了不同降黏剂的优势与不足。并对降黏剂发展趋势进行讨论与展望。对现有化学降黏剂的梳理有助于新型降黏剂体系的开发,提高稠油油藏开采效率。

深层稠油油藏降黏泡沫驱驱油特征及机理研究

降黏泡沫驱结合了降黏剂乳化降黏和泡沫选择性封堵的优势,可进一步提高开发后期深层稠油油藏的采收率。通过室内实验,根据降黏泡沫剂的降黏效果、起泡性能、泡沫稳定性,优选出合适的降黏泡沫剂浓度;通过单岩心驱替实验对比不同驱替方式下降黏泡沫驱驱油特征以及开采效果,通过并联岩心实验研究不同渗透率级差下降黏泡沫的分流能力,明确降黏泡沫驱提高采收率机理。结果表明:降黏泡沫驱过程中,降黏剂可以促进稠油乳化降黏,泡沫可以有效封堵大孔喉,同时抑制氮气窜流。二者结合有效提高波及系数和洗油效率,提高驱替压差,降低含水率。降黏泡沫驱可以在降黏泡沫剂驱的基础上进一步提高13%的采收率。非均质条件下,降黏泡沫驱可以有效降低高渗透岩心窜流,迫使流体转向进入低渗透岩心发挥乳化降黏作用,扩大波及范围的同时提高了洗油效率。降黏泡沫驱技术能显著提高深层低渗透稠油油藏的采收率,其优化了油流分布,增强乳化与减少稠油黏度,为深层稠油高效开发提供了有效策略。

英雄滩油田深层稠油油藏降粘剂驱探索与研究

针对英雄滩油田大35-斜20块地层能量弱、油稠、低渗、敏感等因素影响,常规注水开发效果不佳;表现为注水压力高、储量动用不均衡,水驱效率低,油井易敏感高含水等问题,LPA降粘剂比实验室筛选的降粘剂A6B3具有一定的水相增粘与降低流度比的功能,进行构建LPA降粘剂体系,评价了降粘剂性能,通过并联填砂管岩心驱替实验与微观可视化驱油实验,研究了LPA降粘剂驱与普通降粘剂提高采收率的能力。实验结果表示:在实验温度70℃条件下,油水比为3∶7,LPA体系与大35-斜20块原油形成了较为稳定的乳状液,且降粘率最高达到98.2%。LPA降粘剂的采收率增值为6.67%,高于普通降粘剂的2.18%。在现场试验中,试验井组累油600余吨,投入产出比为1∶1.52,为该区块的稠油油藏降粘驱提供较好的经验。

稠油油溶性降黏剂的作用机理及其应用进展

稠油各类开采技术中,物理降黏具有工艺简单、适应性好等优点,但存在生产成本高、稀油资源短缺等不足;化学降黏具有见效快、能耗低等优点,却存在处理工艺复杂等短板。油溶性降黏剂技术结合了物理降黏与化学降黏的优点,具有添加量少、效果好、成本低及后处理简单等诸多优势。该文介绍了稠油高黏度的原因;分析了油溶性降黏剂的降黏机理;总结了各类油溶性降黏剂的合成工艺;分析了不同类型降黏剂的优点与不足。相较于二元和三元油溶性降黏剂,四元油溶性降黏剂的多种极性基团能够更好地与稠油中的大分子相互作用并破坏胶质、沥青质的层状结构,进而大幅度降低稠油黏度;降黏剂的复合及复配使用可增强降黏效果。对油溶性降黏剂的发展趋势进行了展望,认为还需从分子层面进一步对降黏机理开展深入研究、从绿色环保的角度优化降黏剂合成工艺,以上问题的解决将有助于高效油溶性降黏剂分子的设计、制备与广泛应用。