Research on deepwater synthetic drilling fluid and its low temperature rheological properties

With the rapid development of deepwater drilling operations,more and more complex technical challenges have to be faced due to the rigorous conditions encountered.One of these challenges is that the drilling fluid used must had good rheological properties at low temperatures and high ability to inhibit hydrate formation.Synthetic drilling fluid has been widely applied to deepwater drilling operations due to its high penetration rate,excellent rheological properties,good ability to prevent hydrate formation,and high biodegradability.A synthetic drilling fluid formulation was developed in our laboratory.The rheological properties of this drilling fluid at low temperatures （0-20 °C） were tested with a 6-speed viscometer and its ability to inhibit hydrate formation was evaluated at 20 MPa CH 4 gas and 0 °C by differential scanning calorimetry （DSC）.Several factors influencing the low temperature rheological properties of this synthetic drilling fluid were studied in this paper.These included the viscosity of the base fluid,the amount of CEMU and organic clay,and the water volume fraction.

High temperature and high pressure rheological properties of high-density water-based drilling fluids for deep wells

To maintain tight control over rheological properties of high-density water-based drilling fluids, it is essential to understand the factors influencing the theology of water-based drilling fluids. This paper examines temperature effects on the rheological properties of two types of high-density water-based drilling fluids （fresh water-based and brine-based） under high temperature and high pressure （HTHP） with a Fann 50SL rheometer. On the basis of the water-based drilling fluid systems formulated in laboratory, this paper mainly describes the influences of different types and concentration of clay, the content of a colloid stabilizer named GHJ-1 and fluid density on the rheological parameters such as viscosity and shear stress. In addition, the effects of aging temperature and aging time of the drilling fluid on these parameters were also examined. Clay content and proportions for different densities of brine-based fluids were recommended to effectively regulate the rheological properties. Four theological models, the Bingham, power law, Casson and H-B models, were employed to fit the rheological parameters. It turns out that the H-B model was the best one to describe the rheological properties of the high-density drilling fluid under HTHP conditions and power law model produced the worst fit. In addition, a new mathematical model that describes the apparent viscosity as a function of temperature and pressure was established and has been applied on site.

Rheological properties of oil-based drilling fluids at high temperature and high pressure

The rheological properties of two kinds of oil-based drilling fluids with typically composition were studied at pressures up to 138 MPa and temperatures up to 204 ℃ using the RheoChan 7400 Rheometer.The experimental results show that the apparent viscosity,plastic viscosity and yield point decrease with the increase of temperature,and increase with the increase of pressure.The effect of pressure on the apparent viscosity,plastic viscosity and yield point is considerable at ambient temperature.However,this effect gradually reduces with the increase of temperature.The major factor influencing the rheological properties of oil-based drilling fluids is temperature instead of pressure in the deep sections of oil wells.On the basis of numerous experiments,the model for predict the apparent viscosity,plastic viscosity and yield point of oil-based drilling fluids at high temperature and pressure was established using the method of regressive analysis.It is confirmed that the calculated data are in good agreement with the measured data,and the correlation coefficients are more than 0.98.The model is convenient for use and suitable for the application in drilling operations.

Development and Performance Evaluation of a Deep Water Synthetic Based Drilling Fluid System

With the enhancement of environmental protection awareness, the requirements on drilling fluid are increasingly strict, and the use of ordinary oil-based drilling fluid has been strictly restricted. In order to solve the environmental protection and oil-gas reservoir protection problems of offshore oil drilling, a new synthetic basic drilling fluid system is developed. The basic formula is as follows: a basic fluid (80% Linear a-olefin + 20% Simulated seawater) + 2.5% nano organobentonite + 3.5% emulsifier RHJ-5# + 2.5% fluid loss agent SDJ-1 + 1.5% CaO + the right amount of oil wetting barite to adjust the density, and a multifunctional oil and gas formation protective agent YRZ has been developed. The performance was evaluated using a high-low-high-temperature rheometer, a high-temperature and high-pressure demulsification voltage tester, and a high-temperature and high-pressure dynamic fluid loss meter. The results show that the developed synthetic based drilling fluid has good rheological property, demulsification voltage ≥ 500 V, temperature resistance up to 160°C, high temperature and high pressure filtration loss < 3.5 mL. After adding 2% - 5% YRZ into the basic formula of synthetic based drilling fluid, the permeability recovery value exceeds 90% and the reservoir protection effect is excellent. The new synthetic deepwater drilling fluid is expected to have a good application prospect in offshore deepwater drilling.

BIODRILL S合成基钻井液在垦利区块首次应用

渤海油田垦利9-1区块地层岩性复杂,且存在断层带,钻井过程中易发生泥岩水化分散和砂岩层井眼缩径等问题,井壁垮塌风险极大。针对该区块地层岩性特点和技术难题并结合环保要求,制备了一种复合型封堵材料PFMOSHIELD,构建了BIODRILL S合成基钻井液体系。该体系流变性能良好,抗钙、抗岩屑污染达26%和15%,封堵性、沉降稳定性、润滑性优异,高温高压砂盘滤失量3.2 mL,静置7 d沉降因子为0.53,极压润滑系数0.082。BIODRILL S首次在渤海湾垦利9-1区块进行了现场应用,结果表明:该体系解决了垦利9-1区块泥页岩水化和砂岩层井眼缩径问题,垦利9-1北-3定向探井三开井段上部地层钻屑完整,钻屑达4~7 cm;井眼清洁性能良好,钻井液动塑比超过0.59 Pa/mPa·s,φ6和φ3读数均超过9,剪切稀释性强,提高了井眼净化效率,有效避免形成“岩屑床”;润滑性能优异,在大井斜段(55°、70°、67°)可实现直接起钻。

FLAT-PRO深水恒流变合成基钻井液及其应用

深水钻井面临低温、安全密度窗口窄、浅层气易形成气体水合物、井壁易失稳等技术难题,对深水钻井液提出了更高的要求。以Saraline 185V气制油为基油,通过优选乳化剂、有机土、降滤失剂及其他处理剂,构建了一套适合深水钻井的FLAT-PRO深水恒流变合成基钻井液体系。综合性能评价结果表明:该钻井液在4~65℃下流变性能稳定,具有恒流变特性,能有效保护储层,其渗透率恢复值大于90%,能抗10%海水、15%钻屑污染,易降解,满足环保要求。南海LS-A超深水井水深为1 699.3 m,预测主要目的层温度为34.6~36℃,φ508 mm套管鞋处的地层承压能力系数低于1.14,安全密度窗口窄,如何控制ECD值、预防井漏是该井的作业控点,因此选择密度为1.03 g/cm^3的FLAT-PRO钻井液开钻。钻进过程中,使用FSVIS调整流变性,维护黏度在50~70 s,动切力在8~15 Pa,φ6读数为7~15,φ_3读数为6~12,用2%PF-HFR控制滤失量,应用井段起下钻顺利,电测顺利,井径规则,没有出现任何复杂情况。应用结果表明,FALT-PRO深水恒流变合成基钻井液在不同温度下的流变性能稳定,抑制性好,润滑性强,能获得较低的ECD值,满足深水钻井的要求。

深水FLAT-PRO合成基钻井液体系研究及应用

为了解决深水钻井过程中安全密度窗口窄的技术难题,以低黏度气制油作为基液,对合成基钻井液乳化剂、润湿剂及流型调节剂等关键处理剂进行了研制和优化,构建了深水FLAT-PRO合成基钻井液体系。室内性能评价结果表明,新构建的FLAT-PRO合成基钻井液体系具有流变性好、动切力与Φ6受温度及压力影响小、抗污染能力强、沉降稳定性好等特点。目前新构建的深水FLAT-PRO合成基钻井液体系已在我国南海西部超深水井中取得成功应用,具有较好的推广应用价值。

FLAT-PRO合成基钻井液在南海东部超深水井的应用

随着石油勘探开发的不断深入,南海东部作业了荔湾22-1-1超深水井,该井作业水深达2619.35m,实测海底温度为1.9℃。由于水深的增加,相比常规深水井,钻井液作业面临海底温度低、作业窗口窄、隔水管段井眼清洁差、易井漏等作业风险。恒流变合成基钻井液是深水、超深水井常用的钻井液体系,FLAT-PRO合成基钻井液体系的黏度、切力受温度和压力的影响小,特别是动切力、静切力和低剪切速率黏度等参数在4~65.5℃下变化平稳,满足超深水作业的要求。本井在17-1/2"、12-1/4"井段使用了FLAT-PRO合成基钻井液体系,现场作业中体系恒流变性能稳定、携岩能力强、井眼清洁效果好、ECD值较低,起下钻及电测顺利,满足了窄安全密度窗口作业的要求。

MO-DRILL油基钻井液体系研究及在大位移井应用

为了满足东海油气田大位移井开发需求,研制了一套满足大位移井钻井要求的MO-DRILL油基钻井液体系。通过优选乳化剂、润湿剂及进行加量配比来保证油基钻井液的稳定性、开发流型调节剂来提高油基钻井液的低剪切速率粘度,提高动塑比,解决其携岩能力不足,易形成岩屑床等问题。研究结果表明,MO-DRILL油基钻井液体系具有流变易调控,低剪切速率粘度高,动塑比可调,抗温压能力强等特点,并具有较好的抗钻屑、海水污染能力,较好的储层保护性能。现场应用结果表明,MO-DRILL油基钻井液体系可满足复杂地层井、水平井安全高效作业要求。

准噶尔盆地中部永进油田超深井井壁稳定钻井液技术

永进油田位于准噶尔盆地中部Ⅲ区块,储层为侏罗系西山窑组,油气埋藏深,地质构造复杂。前期勘探中采用四开制井身结构,随后调整为三开制,二开及以下地层钻进过程中复杂情况频发,井壁稳定性差,钻完井时效低,且前期已完钻井储层污染严重,制约了永进油田勘探与开发进程。为此,基于对该区超深井钻井液技术难点的分析,制定了相应的稳定井壁技术对策,据此针对二开长裸眼井段,研选聚胺强抑制钻井液体系;针对三开复杂地层,研选合成基强封堵钻井液体系。两种钻井液体系经过评价实验与现场应用,均获良好结果。评价实验结果表明,两种钻井液体系均具备较强的抑制性能、封堵性能,针对三开复杂地层的合成基强封堵钻井液体系兼具储层保护性能。两种钻井液体系在永进油田9口井的现场试验应用结果表明:(1)两种钻井液体系辅以现场施工工艺,所形成的超深井井壁稳定钻井液技术切实可行,能够保证应用井在二开长裸眼井段及三开复杂地层钻进过程中井壁稳定,起下钻通畅,中完及完井作业顺利;(2)对比前期完钻的8口井,应用超深井井壁稳定钻井液技术顺利完钻的9口井,井身质量明显提高,钻井、完井时效显著提升(平均钻井周期缩短69.61%,平均完井周期缩短65.29%,平均机械钻速提高80.88%),取得了良好的优快钻井效果;(3)钻井液对储层的污染性小,取得了良好的储层保护效果,应用井完井试油获得稳定高产工业油气流,首次实现了对永进油田油气储量的有效动用。结论认为,井壁稳定钻井液技术在永进油田超深井钻井中的成功应用,为该区块的后续勘探开发提供了有力保障,对其他区块超深井或存在井壁失稳问题井的钻井液技术研究亦有参考意义。

合成基钻井液在油田钻井的应用进展

合成基钻井液具有类似油基钻井液的优良作业性能,同时具备生物毒性低,易于降解的优点,具有明显的环保优势,已在海洋钻井等环境敏感区域广泛应用。合成基钻井液经历了从第一代(酯、醚、聚α-烯烃、缩醛)到第二代(线性烷基苯、线性石蜡、线性α-烯烃、内烯烃)的发展历程,不同的钻井液体系均有各自的特点和优势,目前广泛应用的合成基钻井液主要以烯烃基和烷烃基为主。费托合成技术的发展带来了以Saraline 185V为代表的气制油钻井液基础液。气制油钻井液基础液具有黏度低、黏温性能好以及低毒的特点,是目前最先进的钻井液体系。

合成基钻井液的研究进展

综述了国内外合成基钻井液的种类及研究进展,阐述了影响合成基钻井液的主要影响因素。并且对合成基钻井液发展趋势及前景进行了展望,认为合成基钻井液的发展类型主要以生物类及气制油为主,为后续非常规油气田开发钻井液提供参考依据。

北部湾深层深井油基钻井液研究及现场应用

为了缩短钻井周期以及提高井壁稳定,油基钻井液的护壁防塌性能可通过加入封堵剂来优化。本文以纳米SiO_(2)、N-氨乙基-3-氨丙基三乙氧基硅烷和全氟辛基三甲氧基硅烷为原料制备一种纳米封堵剂,其粒径主要分布在10~200nm之间,其粒径较为集中,应用于钻井液中可降低泥饼渗透率,显著提高油基钻井液的封堵性能,降低滤失量,对储层渗透率影响较小。纳米封堵剂与油基钻井液具有良好的配伍性,提高油基钻井液的稳定性。本文研究的高性能油基钻井液成功应用于现场钻井,钻井过程中,纳米封堵剂的加入显著提高了起钻速度,缩短了现场钻井周期,封堵性能的提高使钻井液泥饼在裂缝和孔隙中进行有效封堵,井壁未出现掉块及剥落片。

低油水比油基钻井液体系研究

现阶段国内大量应用的油基钻井液体系油水比居高不下,且由于部分处理剂性能欠佳导致在钻井液体系中用量过大,两者叠加为降低油基钻井液体系综合成本带来极大困难。为此,提出了低油水比油基钻井液体系设计思路,并以此为指导研选了油基钻井液体系关键处理剂,通过配伍性实验构建了低油水比油基钻井液体系配方,并开展了现场应用。以保障在良好的乳化稳定性、流变性和较强的随钻封堵性基础上有效降低油水比为整体思路,研制了多活性点新型乳化剂,增加了分子内活性吸附基团的数量,在低油水比的情况下表现出良好的乳化稳定性和流变性;优选了具有良好增黏提切效果且可降低滤失量的有机土、具有良好降滤失效果的降滤失剂、具有改善流变性且提高乳化稳定性的流型调节剂,以3种处理剂为核心构建了低油水比油基钻井液体系;该体系在70/30的油水比条件下老化前后破乳电压>1000 V,在60/40的油水比条件下老化前后破乳电压>500 V,动塑比均>0.40,具有良好的乳化稳定性和流变性;低油水比油基钻井液体系在12口页岩水平井开展了现场应用,钻井液体系性能稳定、井眼净化效果良好,且乳化稳定性可控,大幅节约了基础油的用量,显著降低了油基钻井液体系的成本。

纳米流体和聚合物复合材料改善水基钻井液性能试验研究

通过试验研究对比了不同类型(氧化锌、二氧化钛、多壁碳纳米管、功能化多壁碳纳米管)不同质量分数(0.002 8%、0.014 3%、0.028%和0.143%)纳米流体对水基钻井液流变性能和滤失性能的影响,以及高温高压下聚合物复合材料对其性能的影响。试验结果表明,水基钻井液流变特性和过滤性能随着纳米流体浓度的增大而增大,其中功能化多壁碳纳米管(F-MWCNTs)纳米流体改善水基钻井液性能参数最好。同时在高温高压下,聚合物(ACN-co-VP)/沸石复合材料可以明显改善纳米流体水基钻井液的流变特性,如增大塑性黏度、屈服点、滤液体积,提高纳米水基钻井液热稳定性及钻井效率,降低对地层伤害程度。

钻井液用耐低温乳化剂的研制与性能评价

油基钻井液性能稳定,常应用于复杂地层开发,但在零下低温环境中存在黏度、切力上涨过快的问题。为解决这一问题,制备了一种耐低温高性能乳化剂ZF-SB,该乳化剂具有超低凝点(-33℃),解决了传统液体乳化剂零下低温无法流动的问题,可显著降低油水界面张力,由其配制的乳状液粒径在0.6~4.2μm之间,粒径分布窄,其破乳电压为1397V,有利于油基钻井液在低温条件下的稳定状态。另外,由耐低温乳化剂ZF-SB配制的油基钻井液在0℃以下仍具有良好的流变性,避免了油基钻井液由于低温增稠效应而造成井底当量循环密度(ECD值)高、井漏和压力控制难等问题。

加重剂对高密度白油基钻井液性能的影响

随着环保形势的日趋严峻,低毒性白油基钻井液在非常规油气藏钻井中逐渐得到广泛应用,而不同加重剂对白油基钻井液性能影响的系统研究较少。为此,本文在分析普通重晶石、微锰矿粉和毫微粉体3种加重剂粒径和形态的基础上,对比了3种加重剂单独加重以及微锰矿粉和普通重晶石复配加重形成的超高密度白油基钻井液的性能。结果表明:加重剂微观形态和粒径是钻井液性能差异的关键因素。当钻井液密度大于2.1g/cm^(3)时,微粉加重剂配制的高密度白油基钻井液流变性、润滑性和沉降稳定性优于普通重晶石,但中压失水量略高。按质量比1∶1将微锰矿粉与普通重晶石复配加重后,滤失量由6.0mL下降至3.6mL,弥补了微锰矿粉单一加重高密度白油基钻井液失水大的缺陷。重晶石和微粉加重剂复配加重是未来高密度油基钻井液、超高密度钻井液的发展方向。

高性能油基钻井液的研制及在彭页3HF井的应用

彭页3HF井为一口页岩气评价井，水平段长1150m，三开龙马溪组页岩黏土矿物含量高达30．05％，以伊利石和伊／蒙混层为主，且页岩微裂缝发育，对钻井液性能要求高。研制出了能增强油水两相乳化效果的大分子乳化剂和新型提切剂，新型提切剂通过电性作用可增强油水界面膜的强度，减少分散相的团聚几率，能与乳化剂协同增效，进一步提升体系乳化稳定性；结合优选的改性褐煤降滤失剂SMFLA-O和封堵剂SMRPA、SMFibre-O等，形成了一套高性能油基钻井液。该油基钻井液在该井三开钻进期间，塑性黏度为20～28mPa·S，动切力为10～15Pa，表现出低黏高切的流变性；破乳电压高，性能稳定；封堵防塌能力强，无剥落、掉块现象，且钻井液消耗量低；井眼清洁、无岩屑床，摩阻、扭矩低，无托压现象，确保了该井顺利完钻，累计进尺1815m。

具有恒流变特性的深水合成基钻井液

合成基钻井液(SBM)以其特有的环保性能及机械钻速高、井壁稳定性好等特点,已成为国际上海上油气钻探的常用钻井液体系。但是在深水钻探作业中,由于温度和压力对流变性的影响常导致井漏和当量循环密度(ECD)不易控制。为了解决该技术难题,近年来国外首先研制出一类新型的具有恒流变特性的合成基钻井液(CR-SBM),其流变性,特别是动切力、静切力和低剪切速率下的黏度等参数基本上不受温度压力的影响。阐述了该新型钻井液的典型组成及性能特点,对比了传统SBM和CR-SBM在不同温度、压力下的流变性、抗岩屑污染和毒性测试结果,并介绍了国外CR-SBM的现场应用情况。