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 of a High Temperature and High Pressure Oil-Based Drilling Fluid Emulsion Stability Tester

When drilling deep wells and ultra-deep wells, the downhole high temperature and high pressure environment will affect the emulsion stability of oil-based drilling fluids. Moreover, neither the demulsification voltage method nor the centrifugal method currently used to evaluate the stability of oil-based drilling fluids can reflect the emulsification stability of drilling fluids under high temperature and high pressure on site. Therefore, a high-temperature and high-pressure oil-based drilling fluid emulsion stability evaluation instrument is studied, which is mainly composed of a high-temperature autoclave body, a test electrode, a temperature control system, a pressure control system, and a test system. The stability test results of the instrument show that the instrument can achieve stable testing and the test data has high reliability. This instrument is used to analyze the factors affecting the emulsion stability of oil-based drilling fluids. The experimental results show that under the same conditions, the higher the stirring speed, the better the emulsion stability of the drilling fluid;the longer the stirring time, the better the emulsion stability of the drilling fluid;the greater the oil-water ratio, the better the emulsion stability of the drilling fluid. And the test results of the emulsification stability of oil-based drilling fluids at high temperature and high pressure show that under the same pressure, as the temperature rises, the emulsion stability of oil-based drilling fluids is significantly reduced;at the same temperature, the With the increase in pressure, the emulsion stability of oil-based drilling fluids is in a downward trend, but the decline is not large. Relatively speaking, the influence of temperature on the emulsion stability of oil-based drilling fluids is greater than that of pressure.

Study on a Polyamine-Based Anti-Collapse Drilling Fluid System

In complex strata, oil-based drilling fluid is the preferred drilling fluid system, but its preparation cost is high, and there are hidden safety risks. Therefore, the new progress of high-performance anti-collapse water-based drilling fluid at home and abroad is analyzed. It is difficult to prevent and control the well collapse. Once the well wall instability problem occurs, it will often bring huge economic losses to the enterprises, and the underground safety accidents will occur. In order to ensure the stability of the well wall and improve the downhole safety, the key treatment agent of water-based collapse drilling fluid is selected, the anti-collapse drilling fluid system is formulated, the evaluation method of drilling fluid prevention performance is established, and a set of water-based drilling fluid system suitable for easy to collapse strata in China is selected to ensure the downhole safety. The development trend of high performance anti-collapse water-based drilling fluid is expected to provide a reference for the research of high performance anti-collapse water-based drilling fluid system and key treatment agent.

一种抗超高温配位键合型低聚物降黏剂

针对高密度水基钻井液高温增稠引发的滤失量大、ECD与内耗高、流动性下降甚至完全丧失难题,在AAAMPS聚有机酸降黏剂分子中引入富含大量邻苯二酚基团的单宁酸,采用自由基聚合法研制了一种抗超高温配位键合型低聚物降黏剂AA-AMPS-TA,并通过正交实验明确了PAAT的最优合成条件。表征并评价了PAAT的降黏性能,结果表明:引入TA后,PAAT的红外光谱出现了源于酚羟基的分子内氢键吸收峰,且因其分子结构中引入了大量苯酚基团,显著提升了热稳定性,分解温度接近500℃;PAAT可降低低浓度膨润土浆和7%膨润土+8%高岭土的高浓度混合黏土浆黏度,在高密度水基钻井液体系中降黏率达26.5%,240℃热滚后降黏率达44.4%。采用Zeta电位与粒径分析验证了PAAT的吸附降黏机理,并在蓬深101井中现场应用,控制了井浆高温下黏度、切力增涨,降黏效果良好。

无黏土水基钻井液用超支化聚合物降滤失剂的合成及性能评价

在高温条件下,聚丙烯酰胺类降滤失剂分子易发生降解,导致降滤失效果大幅下降。为此,通过超支化单体季戊四醇三烯丙基醚(APE)与2-丙烯酰胺-2-甲基丙磺酸(AMPS)、丙烯酰胺(AM)、对苯乙烯磺酸钠(SSS)共聚合成了一种耐高温的超支化聚合物降滤失剂JHPAS,以JHPAS为基础配制了一种新型的无黏土水基钻井液,分析其降滤失机理,评价其在高温、高盐条件下的流变性能和降滤失性能。结果表明:JHPAS具有很好的热稳定性,在水溶液中可形成网络结构,在无黏土水基钻井液中吸附于超细CaCO 3表面形成致密滤饼,并堵塞滤饼上的孔隙,进一步降低钻井液滤失量;构筑的无黏土水基钻井液在200℃老化16 h、饱和氯化钠盐水的条件下仍具有稳定的流变性和良好的降滤失性能,API滤失量和高温高压滤失量分别为5.5 mL和7.6 mL。研究成果有助于推动超支化聚合物在深层、超深层油藏钻井液中的研究与应用。

高温下水基钻井液核心组分微观行为分析

水基钻井液在高温下性能调控难度大,主要与核心胶体粒子的分散状态有关,而水基钻井液成分复杂,单一组分与多组分间受高温作用性能变化规律不同,对胶体粒子的分散状态均有影响。针对水基钻井液核心组分,通过高温高压流变性测试获得了膨润土胶体剪切应力-温度曲线,并测试了不同温度下胶体颗粒粒度分布,分析了黏土矿物胶体粒子在室温~220℃范围内的分散、絮凝与聚结状态及形成机制,同时利用SEM测试和黏土矿物晶层结构分析,从微观角度揭示了富含镁多孔纤维状黏土矿物胶体的高温稳定机理,此外,基于对高温热滚前后流变性和滤失量等性能变化的分析,从黏土矿物结构特征和聚合物断链、吸附特性等角度揭示膨润土/复配黏土矿物与聚合物类处理剂在高温下的互相作用机理,结合实验结果,明确了低浓度膨润土与海泡石复配胶体具有明显的高温稳定优势,为超高温水基钻井液的构建提供了理论支撑。

抗超高温220℃聚合物水基钻井液技术

我国深层油气资源丰富,其高效开发对保障国家能源安全具有重大意义。钻井液是深部地层钻探的关键,但目前常规聚合物钻井液的抗温能力普遍低于220℃,且盐会大幅降低钻井液性能,钻探过程中往往由于钻井液失效引发安全事故,对深层油气开发造成重大损失。针对钻井液高温高盐条件下性能恶化的难题,合成了具有协同作用的抗高温两性离子聚合物和抗高温阴离子聚合物,通过高强度的网架结构调控钻井液流变性;合成抗超高温高效封堵剂来提高钻井液封堵性能和滤失性能,封堵泥饼和砂床,阻止压力传递。以抗高温两性离子聚合物、抗高温阴离子聚合物和抗超高温高效封堵剂为核心处理剂,构建了一套抗超高温220℃的聚合物水基钻井液体系,并评价了该钻井液的性能。实验结果表明,该钻井液具有良好的流变滤失性、沉降稳定性、封堵性和润滑性,其高温高压滤失量仅为9.6 mL,高温高压下仍保持黏度和切力稳定,直立老化72 h沉降因子仅为0.5113,砂床侵入深度仅为6 mm,老化后润滑系数和泥饼黏滞系数分别为0.1224和0.0875。该钻井液具有良好的抗温性能和稳定性,对深部油气的开发具有重要意义。

一种抗高温梳型两性离子聚合物降黏剂

针对深井超深井钻井中高密度水基钻井液黏度高、易高温增稠等流变性调控难题,以对苯乙烯磺酸钠盐、2-丙烯酰胺基-2-甲基丙磺酸、2-烯丙基-2-甲基氯化铵、烯丙基聚氧乙烯醚为单体,合成了一种抗高温梳型两性离子聚合物降黏剂ZT-1。采用红外光谱表征了降黏剂的分子结构,验证梳型两性离子聚合物合成的成功,采用热重分析表征了降黏剂的热稳定性,其分解温度达250℃。ZT-1具有良好的抗高温耐盐钙降黏分散性能,抗温240℃,可抗饱和盐,抗2%氯化钙;ZT-1加量为0.3%时,老化温度为200℃,在评价浆中的降黏率可达77.7%,在高密度(2.4 g/cm^(3))水基钻井液体系中表观黏度的降低率达33%,塑性黏度的降低率达14%,动切力降低率达67%。ZT-1性能优于阴离子降黏剂磺化丹宁以及常规线性两性离子聚合物降黏剂XY-27和ADS共聚物,这种梳型两性离子聚合物降黏剂在超高温超高密度钻井液中具有良好的应用前景。

微米刚性氧化石墨烯颗粒的制备及协同堵漏性能评价

泸州区块深层页岩气地层微米级裂缝发育,且偶有天然裂缝存在,结构面节理特征弱,钻井过程中,容易造成滤液侵入地层,引起井壁坍塌,亟待研制一款能抗压抗高温的微米尺度刚性封堵剂,既能应对微米裂缝带来的威胁,又可以与大片径堵漏剂有很好的协同堵漏作用。采用改进Hummers法制备氧化石墨烯(GO)水凝胶,经超长时间高温真空干燥之后,将其粉碎,获得了一种刚性氧化石墨烯颗粒(GO-RP)。这种颗粒属于氧化石墨烯纳米片的多重叠加,用超声波无法使之分散,单体能够承受215℃以下的温度。采用可驱替式堵漏仪评价这种颗粒的协同堵漏性能,实验结果表明,GO-RP可在压力作用下不断地冲进裂缝孔隙进行填充,搭配混合堵漏剂,尤其是带有柔性纤维的材料,能够形成更致密的承压封堵层,承压能力高达9 MPa,降漏失率提升了约70百分点。将封堵剂GO-RP加入水基钻井液中,可使钻井液漏失量显著降低,同时,在高温下仍能保持较好的摩擦性能和抗压能力。这种刚性氧化石墨烯颗粒封堵剂在钻井堵漏领域有良好的应用前景。

水平井类油基高性能水基钻井液性能评价

页岩油气水平井钻井难度大,面临着井壁失稳、摩阻大、井眼清洁难度大等问题,常规水基钻井液作业施工困难,通常使用油基钻井液作业,但是油基钻井液成本高,废弃泥浆和钻屑处理环保压力大,研究和开发能够替代油基钻井液的强抑制类油基高性能水基钻井液迫在眉睫。室内根据页岩水平井特征,构建了一套类油基高性能水基钻井液,并开展了全套性能评价,结果表明该体系具有良好的防塌、润滑和携岩性能,在页岩油气具有广阔的应用前景。

抗高温白油基钻井液体系构建及评价

油基钻井液是近年来在我国页岩气钻井现场广泛应用的一种作业流体,具有抗高温、抗盐钙侵、有利于井壁稳定、润滑性好和对油气层损害程度小等优点。本文通过对核心处理剂主乳化剂、辅乳化剂等进行优选及性能评价,同时对有机土、降滤失剂、润湿剂等白油基钻井液体系中的关键处理剂进行优选评价,得出一套体系,抗温度达200℃,长时间高温稳定性良好,72 h老化时间性能稳定,有良好的乳化稳定性能,可抗15%地层水污染。

葡萄提取物作为环保型降滤失剂的室内研究与评价

本文针对现有的天然材料降滤失剂抗温能力不足的问题,我们寻找了一种抗高温的绿色材料—葡萄提取物(GE),并首次评价了GE的降滤失性能及降滤失机理。首先利用傅里叶变换红外光谱(FT-IR)表征了GE的结构,热重实验(TGA)表明了其具有较好的热稳定性。随后通过中压滤失和高温高压滤失实验评价了GE在高温条件下对基浆降滤失性的影响,并利用Zeta电位、粒径分布、扫描电镜(SEM)实验分析了GE的降滤失机理。实验结果表明,170℃老化16h后,含有3%GE基浆的中压(API)滤失量为12.8mL,小于15mL,120℃高温高压(HTHP)滤失量为24.0mL,优于常用降滤失剂羧甲基淀粉(CMS)、聚阴离子纤维素(PAC)和国外聚合物降滤失剂Driscal,与磺酸盐共聚物(DSP-2)的降滤失效果相当。GE具有优异的降滤失性能主要通过氢键作用和静电作用强烈吸附在膨润土表面,增加了膨润土的zeta电位绝对值,提高了膨润土在高温下的电稳定性,使得膨润土高温不易聚结,减小了膨润土的粒径,更好地促进了膨润土的分散,且滤饼表面光滑。GE分子结构含有苯并六元杂环,这种结构使得分子链刚性强,在高温条件下不易发生蜷曲变形,使其在高温170℃下保持了优异的降滤失性能。此外,GE的生物毒性EC50为133690mg/L,大于30000mg/L,GE的生物降解性BOD5/CODcr为32.75%,大于5%,表明了它是无毒且易生物降解。

抗高温低密度水泥浆体系研究与应用

为解决低密度水泥浆高温强度低、减轻材料承压能力不高、低密度水泥浆配浆困难等难题,研制了低密度增强材料DRA-2S、优选了耐压105 MPa的高性能空心玻璃微珠、聚羧酸分散剂DRS-2S及其他配套抗高温水泥外加剂,开发了抗高温低密度固井水泥浆体系。研究结果表明,该水泥浆能够满足循环温度150℃、井底静止温度180℃、耐压105 MPa的固井要求,顶部127℃静胶凝13.3 h起强度,24 h抗压强度12.4 MPa。开发的抗高温低密度水泥浆在西南油气田高温探井ZJ2井Ф127 mm尾管固井成功应用,固井质量合格率96.7%,为西南油气田高温易漏失复杂深井勘探开发提供了固井技术支撑。

油基钻井液用耐高温碳酸钙-聚氨酯核壳型微球井壁强化剂

为了提高油基钻井液的封堵性能,以氯化钙、碳酸钠、谷氨酸、2,4-甲苯二异氰酸酯、二月桂酸二丁基锡等为原料,通过水热法制备了刚柔并济的核壳型碳酸钙-聚氨酯井壁强化剂。通过测定流变参数、破乳电压、滤失量和侵入深度等,考察井壁强化剂加量对基浆流变性、稳定性和封堵性的影响。将井壁强化剂与钛酸钾纤维、海泡石、硅藻土和氧化沥青等材料复配,研究了复配井壁强化剂对油基钻井液润湿性、流变性、稳定性、封堵性和耐温性等的影响。结果表明,井壁强化剂以耐高温且具备一定形变能力的聚氨酯为壳、碳酸钙球为核,微球粒径约2μm;对基浆流变性和稳定性的影响较小,可显著提高基浆的封堵性能;加量为2.5%~3.0%时可实现良好的封堵效果,破乳电压为525~542 V、侵入深度为0.6 cm。最优配方的复配井壁强化剂可显著提高油基钻井液的润湿性;对基浆流变性的影响较小,有利于基浆稳定性的提升,破乳电压提高至637 V。复配井壁强化剂各组分发挥协同效应,可以针对不同孔隙的裂缝进行有效封堵,表现出较好的降滤失性能。在常温下的滤失量和侵入深度分别为1.0 mL和0.2 cm。在经过180℃高温老化8 h后,复配井壁强化剂依旧保持较好的降滤失性能,滤失量和侵入深度分别为3.3 mL和0.3 cm,抗高温性能较好。核壳型井壁强化剂的聚氨酯软壳利于微球进入诱导裂缝的最前端,碳酸钙硬核能促进应力的分散,防止裂缝的进一步延伸,实现对井壁裂缝的有效封堵,同时能与钻井液保持良好的配伍性,封堵性能优异。

抗高温抗盐水基降滤失剂的合成与性能评价

针对现有水基钻井液用降滤失剂抗高温和抗盐能力不足的问题,提出以腐植酸钠(Na Hm)、N,N-二甲基丙烯酰胺(NNDMA)、二甲基二烯丙基氯化铵(DMAAC)、对苯乙烯磺酸钠(SSS)为单体,过硫酸铵为引发剂,通过水溶液自由基聚合制备了一种抗高温抗盐降滤失剂。采用正交实验确定最佳反应条件:m(Na Hm∶NNDMA∶DMDAAC∶SSS)=2∶6∶2∶2,单体浓度30%,引发剂加量1.0%,反应温度65℃。利用红外光谱、热失重、核磁共振氢谱及环境扫描电镜对产物进行了结构表征和分析,证明四元聚合物制备成功,并通过抗高温、抗盐性能评价以及和市面常用产品对比,实验发现所合成的降滤失剂具有良好的抗高温抗盐性能,230℃老化16 h后,中压滤失量为5 m L,高温高压滤失量为22 m L,抗Na Cl 25%,抗Ca Cl21.5%,在高温高盐水基钻井液中具有广阔的应用前景。

水基钻井液用抗高温耐盐降滤失剂的制备与性能评价

针对深井和超深井钻探中水基钻井液在高温高盐环境下性能衰减的问题,通过自由基聚合法合成了一种新型抗高温耐盐降滤失剂。通过引入2-丙烯酰胺-2-甲基丙磺酸、丙烯酰胺和对苯乙烯磺酸钠作为单体,并使用N,N'-亚甲基双丙烯酰胺作为交联剂,优化了聚合条件。结果表明,在最优单体浓度2.0 mol·L^(-1)、最优单体配比n(AMPS)∶n(AM)=4∶1和最佳反应温度80℃的条件下,合成的降滤失剂HTSR展现出优异的降滤失性能,其降滤失率达到75.2%,并在200℃的高温条件下保持了较低的滤失量(7.8 mL)。此外,HTSR在8%NaCl溶液中的滤失量仅为8.6 mL,表现出良好的抗盐性能。热重分析结果显示,HTSR在270℃之前的质量损失较小,具有出色的热稳定性。红外光谱分析进一步证实了其化学结构的正确性。研究成果为高温高盐环境下水基钻井液的降滤失剂设计提供了新的思路,对提高深井和超深井钻探的钻井液性能具有重要意义。

低密度强封堵抗硫油基钻井液在高含硫井的应用

川东北高含硫区块储层飞仙关组具有地层压力系数低、硫化氢含硫高、渗透性强等地质特点。为了解决该区块在水平段钻井过程中存在的易卡易漏、硫化氢含量高、小井眼携砂不良等井下难题,本文通过室内实验,优选了低密度强封堵抗硫油基钻井液配方,并对其性能进行了分析评价。实验结果表明,该体系具有流变性能好、封堵性强、除硫效果好等特点。现场应用结果表明,该体系表现出良好的携砂、防漏防卡、防硫除硫效果,密度最低达到1.00g·cm^(-3),高温沉降稳定性好,井壁稳定,未发生硫化氢伤害事故。该体系能很好地满足高含硫区块的安全快速钻井要求,可为高含硫井的安全高效开发提供参考。

钻井液用环保抑制剂的合成及其性能评价

钻井过程中,泥页岩黏土含量高,易出现水化膨胀,造成井眼缩径、起下钻困难以及井壁失稳等复杂问题。为了解决上述问题,本文通过季铵盐改性聚精氨酸制备一种抗高温环保抑制剂(ZY-H),通过线性膨胀实验、热滚回收率、膨润土层间距测试等方法评价其抑制性能。实验表明,抑制剂(ZY-H)显著降低黏土水化膨胀,提高露头岩的滚动回收率,具有良好的抗高温性能,且与钻井液具有良好的配伍性能。另外,从生物毒性和生物降解性分析,表明抑制剂(ZY-H)具有良好的环境友好性能。

塔里木油田富源井区深井超深井抗240℃高温钻井液体系研究

深井超深井的勘探开发已逐渐成为油气开发的主要对象,钻井液是深层超深层钻完井工程的核心技术,是钻井成功的关键之一。本文通过分析塔科1井的技术难点,对水基钻井液的降滤失剂、沥青封堵剂、抗高温抑制剂以及抗高温颗粒封堵剂进行了优选,形成了一套抗240℃高温的水基钻井液体系;并对钻井液体系进行评价。实验结果表明,钻井液体系在240℃高温下具有良好的流变性和降滤失剂性能,满足塔里木油田深井超深的钻井需求。