Effect of nanocomposite pour point depressant EVAL/CNT on flow properties of waxy crude oil

The nanocomposite EVAL-CNT was produced by chemical grafting in the solution system through the esterification of ethylene-vinyl alcohol copolymer (EVAL) and carboxylated multi-walled carbon nanotubes (O-MWCNT), and its structural properties were characterized. The improvement of the rheological properties of the waxy oil system by the novel pour point depressant was investigated using macroscopic rheological measurements and microscopic observations. The results showed that EVAL-CNT nanocomposite pour point depressant (PPD) could significantly reduce the pour point and improve the low temperature fluidity of crude oil and had better performance than EVAL-GO at the same addition level. The best effect was achieved at the dosing concentration of 400 ppm, which reduced the pour point by 13 ℃ and the low-temperature viscosity by 85.4%. The nanocomposites dispersed in the oil phase influenced the precipitation and crystallization of wax molecules through heterogeneous crystallization templates, which led to the increase of wax crystal size and compact structure and changed the wax crystal morphology, which had a better effect on the rheological properties of waxy oil.

Rheological Properties of Waxy Crude at a Low Temperature in the Presence of Pour Point Depressants

Pour point depressants （PPD） are used to improve the theology of waxy crude. The affect of various factors on the theological properties, and the thermal characteristics of waxy crude treated by PPD have been investigated. The conclusions are as follows： PPD can reduce the pour point and abnormal point of waxy crude, broaden the temperature range of Newtonian fluid of waxy crude, and lower greatly the viscosity of non-Newtonian fluid of waxy crude. The influence of reheating and high-rate shear on the effect of PPD mainly depends on their temperature. When the reheating temperature is more than the abnormal point of crude by 10℃, the reheating process has little effect on the modification effect of PPD. However, when the reheating temperature is below the abnormal point of crude, the reheating process will reduce the modification effect of PPD. When temperature is above the abnormal point of crude, the high-rate shear has little effect on the modification effect of PPD. At a temperature range where a lot of wax is precipitating, high-rate shear will greatly reduce the modification effect of PPD.

Synthesis of comb bipolymers and their pour point depressing properties

A bipolymer maleic anhydride-methyl acrylate （MAMA） was synthesized from maleic anhydride and methyl acrylate based on molecular design.MAMA further reacted with oleylamine or octadecyl alcohol to generate two comb polymers called Oleamide-MAMA （NMAMA） and OctadecanolMAMA （OMAMA）,respectively.The structure of both the polymers was confirmed by their infrared spectral analysis （IR）,gel permeation chromatography analysis （GPC） and differential scanning calorimeter （DSC）.Moreover,the pour point depressing （PPD） properties of these comb polymers were examined experimentally.Experimental results showed that besides the molecular weight and concentration of the polymers,the length of side chains and the number of functional groups also had great influence on the pour point depressing performance.The π bonds and hydrogen bonds between depressants were the key factors for improving the pour point depressing properties.These results suggest that both OMAMA and NMAMA are potential pour point depressants for industry.

Shengyang Oilfeild──The Top Rank of High Pour Point Oil in The World

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Synthesis of new EVA graft copolymer and its pour point depressant performance evaluation for Daqing crude oil

EVA was widely used as the pour point depressant for waxy oil.In order to improve its effect,some graft copolymerization methods should be used to modify EVA's property.EVA has long side chains and nitrogen polar groups to enforce its adaptability and effect of waxy oil.The pure amine,maleicanhydride and their reaction product were tested using infrared spectra and the NMR spectral.The results show that when the modified EVA is added into oil,the wax deposits not only on the main chain but also on the side chains.And the polar groups have the function to avoid and resist the wax crystals connection each other to form the net.Using the reaction product of maleicanhydride and high carbonic amine(C12,C16,C18 amine) as the graft component,the toluene as the solvent and BPO as the initiator,the series of new EVA graft copolymer with special side chains are prepared under controlled condition.A series of cylmaleimide exist indeed in modified EVA and the highest grafted percentage is 18.8%.EVA-16,the new graft copolymer,is better than EVA about 3 ℃ more in depressant the pour-point of Daqing waxy crude oil.

Efficiency of Amphoteric Surfactants as Flow Improvers and Pour Point Depressants

Some amphoteric surfactants (N-Decyl-N-benzyl-N-methylglycine(AB) and N-Dodecyl-N-benzyl-N-methylglycine(CD) were prepared in the laboratory. The physicochemical chemical characteristics were investigated. The adsorption behavior of these surfactants at oil/air interface was investigated by measuring the surface tension and interfacial tension as function of concentration. Surface properties, in particular the critical micelle concentration (CMC), the maximum surface excess (ΓCMC) and the minimum surface area (AMIN) were measured. It is found that the surface and thermodynamic properties of the prepared surfactants depend on their hydrocarbon chain length. Also it is found that there is a good relation between surface properties of the additive and their efficiency in depressing the pour point. The mechanism of the depressants action has been suggested according the adsorption of each additive. Adsorption of the additive on the surface of the wax particles inhibits their growth and alters the crystal habits through micelle core. As the results the surface and thermodynamic parameters confirm the suggested mechanism and the decreasing of pour point. This is resulted in a multilayer, more isotropic wax crystal, and thus only a fixed amount of wax separates at any given temperatures. The results were discussed in terms of adsorption isotherm.

Relationship between the Composition of Polymer of n-Alkyl Substituted Acrylate and Vinyl Amine and Their Performance on Pour Point Depression

Polymer of n-alkyl substituted acrylate (PA) with the alkyl side chains C16- 30 were synthesized.Their crystallinity, solubility and effect on pour point depression were studied. Results showed that only carbon atoms located far away from polar groups of PA pour point depressants participated in crystallization.When the number of carbon atoms that participated in crystallization is about three fourths of the average carbon number of wax in crude, the effect of PA is the best. The molecular weight distribution of PA pour point depressant has little influence on the effect of pour point depression, and the average molecular weight of PA in the range of (1.5- 2.2)× 104 shows the best effect. The introduction of polar groups into the molecule of PA can improve its performance. However, a too high content of polar groups in PA would cause deterioration, and even lead to loss of PA's performance for pour point depression.

Study on Application of Pour Point Depressant for Diesel Fuel

Taking into account the actual crude slate processed at the refinery, it is necessary to make reasonable combination and blending of crude oils. In order to cope with high wax content in diesel fuel it is proposed to appropriately regulate the refining process scheme and add additives to refined products. This measure after being applied in the production practice has brought about good results and has met the needs of commercial production.

Effect of nanocomposite as pour point depressant on the cold flow properties and crystallization behavior of diesel fuel

The high effective nano-hybrid pour point depressant(PPD)has attracted extensive attention for its po-tential application in improving the cold flow properties of diesel fuel.In this paper,the nano-hybrid PPD was prepared by melt-blending method using three different alkyl chain lengths(i.e.,tetradecyl,hexade-cyl,and octodecyl)of n-alkyl methacrylate-maleic anhydride copolymers(R 1 MC-MA,R 1=C_(14),C_(16),C_(18))and SiO_(2)nanoparticles.The effect of those nano-hybrid PPDs on the cold filter plugging point(CFPP)and solidifying point(SP)depressing of diesel fuel were studied.Results indicated that nano-hybrid PPD showed much better performance on diesel fuel.The diesel fuel treated with 0.2 wt%C_(14)MC-MA/SiO_(2)nano-hybrid PPD exhibited the best depression in CFPP and SP by 6℃ and 18℃,respectively,which higher than that of single C 14 MC-MA.Viscosity-temperature curves and polarized optical microscopy were conducted to explore the performance mechanism;and results presented that nano-hybrid PPD of C_(14)MC-MA/SiO_(2)could effectively lower the low-temperature viscosity,and modify the crystallization behavior and crystal morphology of diesel.Therefore,the cold flow properties of diesel were significantly improved.

An experimental study of diesel fuel cloud and pour point reduction using different additives

An experimental study was conducted to investigate the effects of four different additives on pour point and cloud point temperatures of a diesel fuel.Sample mixtures were prepared in different volumetric percentages of four different additives(Ethanol,Toluene,n-Heptane and Xylene)and diesel fuel mixture.Pour point and cloud point temperatures of the blends were measured using standard ASTM D2500 and ASTM D97-96a methods,respectively.Introducing the additives to the diesel fuel did not lead to a significant reduction in cloud point temperature of the fuel.In fact,the greatest obtained reduction in cloud point temperature was achieved using 20 vol%or more of Toluene-diesel fuel mixtures.Although cloud points did not change significantly,even the slightest amounts of additives caused a high reduction in the pour point temperature of the fuel.Ethanol was the most effective additive in lowering the pour point temperature of the fuel.A 20%ethanol-fuel mixture caused nearly a 30
reduction in the fuel pour point temperature.Therefore,knowing that none of the additives has a significant effect on cloud point temperature,while the greatest reduction in pour point temperature is achieved using ethanol even in low Vol%s,it can be concluded that the most efficient additive among these four additives to alter cold flow properties of a certain diesel fuel is Ethanol.

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。

高含蜡原油聚烯烃降凝防蜡剂的合成及性能评价

以丙烯酸十八酯(ODA)、十八烯(ODE)和苯乙烯(SM)为单体合成三元共聚物P(ODA-co-ODE-co-SM),以其为主剂合成了聚烯烃降凝防蜡剂POOS,对三元共聚物的合成条件进行了优化,并对加剂前后原油流变性、析蜡特性、微观形态以及降凝防蜡效果进行了评价。结果表明,三元共聚物最优的合成工艺条件为n(ODA)∶n(ODE)∶n(SM)=5∶3∶2、引发剂过氧化苯甲酰含量(以丙烯酸十八酯、十八烯和苯乙烯总质量为基准,下同)为5‰、反应温度70℃、反应时间8h。当POOS质量浓度为200mg/L时,原油流变性与未加POOS原油相比变化明显,15℃下加剂前后屈服应力为50.30和2.95 Pa,屈服应力降幅为94%,析蜡温度由31.33℃降至24.94℃,凝点由25℃降至15℃,加剂后冷指测试防蜡率为88.00%,环道测试防蜡率为83.70%,蜡晶形态由针状转变为圆状结晶,加剂后蜡晶析出分布不均匀,多个微小蜡晶聚集析出形成单个聚集体,POOS的加入有效改善了蜡晶分散形态,抑制网状结构形成,显著改善了原油低温流动效果。

含氟羧酸酯-马来酸酐原油降凝剂的合成及性能研究

为了改善海上原油管输流动效果,以甲基全氟烷基乙基羧酸酯(GMA)和马来酸酐(MA)为单体、偶氮二异丁腈为引发剂合成聚(甲基全氟烷基乙基羧酸酯-马来酸酐)(GM),以其为主剂与乙烯-乙酸乙烯酯共聚物(EVA)复配形成含氟羧酸酯-马来酸酐原油降凝剂,并对GM合成条件、降凝剂降凝效果影响因素、加剂前后原油流变性和微观形态进行评价分析。结果表明,GM合成优化工艺条件为:GMA与MA摩尔比为5∶1、引发剂质量分数为0.6%、反应温度为75℃、反应时间为8 h;GM与EVA间存在协同作用,当w(GM)∶w(EVA)=6∶4、加剂量为400 mg/L时,原油凝点为5.5℃,降凝幅度为13℃;在温度为10℃时,加剂前后原油黏度从562.9 mPa·s降至93.1 mPa·s,降黏率达83.5%,原油屈服值从986.6 Pa降低至68.02 Pa,屈服值下降率达93.1%;加剂前后蜡晶形态由棒针状大聚集体堆叠变为小聚集体分散,加剂对改善原油低温流动状态具有明显效果。

基于不同孔径和酸性分子筛的催化剂异构反应差异性研究

分别以2种不同孔径和酸性的一维十元环结构分子筛ZIP-1(小孔)和BCM-168(大孔)为酸性组分制备了2种贵金属临氢异构化催化剂A200和B350,采用微型反应装置考察其对正十六烷的异构化反应性能,并对其产物进行倾点与收率的计算以模拟实际油品的切割效果。结果表明,孔径较大且Bronsted酸强度较弱的BCM-168分子筛制备的B350催化剂对正十六烷的异构化选择性更好,且在高转化率下A200与B350的选择性差距增大。通过对正十六烷异构产物进行模拟切割,发现2种催化剂反应产物的组成结构不同,B350催化剂异构化产物支化度更高。在实际油品评价中,通过分析产物烃组成与碳数分布,发现B350催化剂使烷烃断键生成碳数较接近的产物;而由孔径较小且Br?nsted酸强度较高的ZIP-1分子筛制备的A200催化剂,易促进烷烃多次裂解生成碳数较少的短链烷烃。同时发现,催化剂的过度异构化会使产物裂解为沸点较低的组分,使得目的产物大分子异构烃类收率降低。

PHD-112∕PHU-301催化剂级配生产国Ⅵ低凝柴油的首次工业应用

为灵活调整柴汽比,在兼顾冬季多产石脑油的同时生产低凝柴油,中国石油玉门油田炼油化工总厂柴油加氢改质装置选用中国石油石油化工研究院研制的新一代加氢精制催化剂PHD-112与新一代加氢裂化催化剂PHU-301级配生产国Ⅵ低凝柴油。此为该催化剂级配的首次工业应用。装置稳定运行3个月后开展了标定工作,结果表明:采用PHD-112 PHU-301催化剂级配处理催化裂化柴油、焦化石脑油和直馏柴油组成的混合原料,在标定工况下原料油经处理后硫质量分数由4260μg g降至3.6μg g,氮质量分数从96μg g降低至0.32μg g,多环芳烃质量分数降低至6.2%,十六烷指数提高1.6,凝点降至-28℃,冷滤点降至-20℃,同时增产石脑油10百分点左右(相对进料量)。说明PHD-112 PHU-301催化剂级配的使用性能良好,具有优异的脱硫、脱氮性能以及降凝和增产石脑油的能力,能够满足柴油加氢改质装置生产国Ⅵ低凝柴油的需求。

注CO_(2)改善河南双河油田低渗储层注水能力机理研究

针对双河油田低渗储层注水能力差、注水水质不达标和高凝原油蜡沉积等问题,通过自主设计的水-CO_(2)储层注入能力评价装置,开展流动性实验、CO_(2)驱油实验,结合岩心扫描电镜等测试手段,明确双河低渗储层注水能力差的主要机制,探索CO_(2)改善低渗储层注入能力的主要机理。结果表明,产出水中的悬浮颗粒和油中蜡晶等组分的沉积可导致孔隙堵塞,从而降低储层的注水能力。CO_(2)对产出水中无机悬浮颗粒及岩石碱性矿物、碳酸盐岩矿物有明显溶蚀作用,是显著提高储层注水能力的主要机理。CO_(2)可溶解在岩石表面的原油蜡质组分沉积,有效改善储层注水能力。同时,CO_(2)驱提高采收率效果明显,采收率提高13.01%~21.51%,后续水驱进一步提高5.40%~6.04%。研究表明:注CO_(2)可显著改善双河油田低渗储层注入能力,为CO_(2)增注驱油技术在现场应用提供理论支撑。

基于不同工艺的高凝原油脱水技术实验研究

为了研究不同脱水工艺对高凝原油的处理效果,以巴彦油田高凝原油为研究对象,对自然沉降脱水、热化学脱水、电化学脱水、高频脉冲脱水、超声波脱水及微波脱水等脱水工艺效果进行实验研究,通过实验数据可得,BC-018K破乳剂对巴彦原油脱水效果最佳,最佳加药量为120 mg/L。在60℃温度和加药量120 mg/L条件下,针对含水率≤20%的巴彦原油,应用热化学沉降脱水至合格时间为2 h;应用电场强度≥1000 V/cm的电化学脱水工艺时,脱水合格时间为20 min;应用频率为2.5 kHz、脉宽比为80的高频脉冲脱水工艺时,脱水合格时间为40 min;应用频率20 kHz、功率60 W、超声作用时间30 s的超声波脱水工艺时,脱水合格时间为1 h;微波脱水与热化学沉降脱水效果相当;脱水效果由好到差的顺序为电化学脱水,高频脉冲脱水,超声波脱水,热化学沉降脱水和微波脱水,自然沉降;针对巴彦油田的高凝原油,应优先选用电化学脱水工艺。

风电齿轮油在齿轮箱内运行状态分析

为评价某风场国产齿轮油的使用性能,文中对4台不同风机中的齿轮油样品进行检测,包括运动黏度、黏度指数、倾点、酸值和微量元素等指标,分析该国产齿轮油在不同运行时间下各个指标的变化情况。结果表明:在风电齿轮箱运行期间,齿轮油的运动黏度未发生明显变化,仍能形成稳定的油膜保证齿轮箱的正常运行;黏度指数及倾点变化较小,齿轮油低温性能无明显变化;齿轮油的磨斑直径指标无劣化趋势,油品能够在齿轮表面形成保护层,使齿轮间有效啮合;酸值在运行期间无明显变化,齿轮油没有发生明显的氧化;齿轮油中的微量元素无异常增加的情况,风电齿轮箱无异常磨损。以上结果表明,各项检测指标均满足要求,该国产齿轮油满足该风场风电齿轮箱的使用需求。

基于专利计量的中美低温流动改进剂技术发展现状及关键技术分析

低温流动改进剂是一种广泛应用于能源行业的化学添加剂,旨在改善燃料在低温环境下的流动性能。笔者基于专利文献计量的方法,对中美两国低温流动改进剂的发展现状和关键技术进行了分析。研究发现,中美两国在低温流动改进剂领域都取得了显著的研究成果,但存在一些差异。美国在低温流动改进剂的研究方面更加注重基础理论和实验研究,而中国则更加注重应用技术和工程实践。通过对专利文献的分析,笔者总结了中美两国低温流动改进剂的关键技术,并提出了未来发展的建议。