656 2016 8 PETROLEUM EXPLORATION AND DEVELOPMENT Vol.43 No.4 文章编号 :1000-0747(2016)04-0656-06 DOI: 10.11698/PED.2016.04.20 采用海泡石纳米颗粒控制膨润土基钻井液性能 AL-MALKI Needaa, POURAFSHARY Peyman, AL-HADRAMI Hamoud, ABDO Jamil (Sultan Qaboos University) 摘要 : 提出在膨润土基钻井液中添加海泡石纳米颗粒来控制其性能, 并通过实验研究了不同温度压力条件下海泡石纳米颗粒对膨润土基钻井液流变性 滤失性等性能的影响 测量了添加海泡石纳米颗粒前后膨润土基钻井液在不同温度压力条件下的塑性黏度 动切力和滤失量, 并在储集层温度压力条件下对添加海泡石纳米颗粒前后的膨润土基钻井液进行了岩心驱替实验, 对比了钻井液的滤失量及对地层的伤害程度 结果表明 : 添加海泡石纳米颗粒可以提高清水和盐水膨润土基钻井液的塑性黏度和动切力 ; 海泡石纳米颗粒可以在较大的温度和压力范围内特别是高温高压条件下保持钻井液流变性的稳定 ; 储集层温度压力条件下, 海泡石纳米颗粒降低了钻井液的滤失量, 抑制了砂岩岩心渗透率降低 海泡石纳米颗粒是一种理想的膨润土基钻井液添加剂 图 13 表 3 参 12 关键词 : 膨润土基钻井液 ; 钻井液性能 ; 高温高压 ; 海泡石 ; 纳米颗粒 中图分类号 :TE256.7 文献标识码 :A Controlling bentonite-based drilling mud properties using sepiolite nanoparticles AL-MALKI Needaa, POURAFSHARY Peyman, AL-HADRAMI Hamoud, ABDO Jamil (Sultan Qaboos University, Muscat Governorate, Sultanate of Oman) Abstract: Sepiolite nanoparticles were added to the bentonite-based drilling mud to control its properties, and the effects of sepiolite nanoparticles on rheological properties and filtration loss of the bentonite-based drilling mud at different temperature and pressure conditions were studied by experiments. For the bentonite-based drilling muds with and without sepiolite nanoparticles, plastic viscosity, yield point, and fluid loss were measured at different temperature and pressure conditions, the core flooding experiments were also conducted at reservoir pressure and temperatures, and fluid loss and formation damage were measured. The results show that: sepiolite nanoparticles can be used to improve the plastic viscosity and yield point of saline and fresh bentonite-based drilling mud; the bentonite-based drilling mud with sepiolite nanoparticles shows a great stability of rheological properties over a wide range of temperature and pressure, especially at high temperatures and pressures; sepiolite nanoparticles reduce the fluid loss and the permeability reduction at reservoir pressure and temperatures. Sepiolite nanoparticles are an ideal additive for bentonite-based drilling mud. Key words: bentonite-based drilling mud; drilling fluid property; high temperature-high pressure; sepoiolite; nanoparticles 0 [1] 200 [2] [3-4] ALTUN G [3] 1~100 nm [5] [6-7] [8] [9] [10] CAI J [7] 3~10 nm H 27.64 Mg 8 O 45.82 Si 12 X 1 50 nm 1 3
2016 8 AL-MALKI Needaa 657 图 1 海泡石纳米颗粒扫描电镜照片 1 1 600 ml +50 g 600 ml +50 g +2% NaCl 1 FANN Instrument Company 表 1 不同钻井液中膨润土 海泡石纳米颗粒加量 /g /% /g /% 1 1.35 0.2 0 0 2 4.60 0.7 0 0 3 8.80 1.3 0 0 4 13.50 2.0 0 0 5 17.00 2.5 0 0 6 0 0 1.35 0.2 7 0 0 4.60 0.7 8 0 0 8.80 1.3 9 0 0 13.50 2.0 10 0 0 17.00 2.5 11 1.35 0.2 0 0 12 4.60 0.7 0 0 13 8.80 1.3 0 0 14 13.50 2.0 0 0 15 0 0 1.35 0.2 16 0 0 4.60 0.7 17 0 0 8.80 1.3 18 0 0 13.50 2.0 2 2 OFITE HTHP +7.9% +6.1% +1.4% ph 10 3 3 Berea +7.5% +2% NaCl +7.5% +1.3% +2% NaCl Berea [11] 2 Berea VINCI Technologies 10.35 MPa 1 500 psi 0.5 ml/min 1.04 MPa 150 psi 6 h 6 h 60 表 2 岩心尺寸 孔隙度和渗透率 / / / / mm mm 10 3 μm 2 /ml % 1 76.42 37.92 36.57 11.35 13.16 2 78.30 37.92 48.82 12.47 14.11 2 2.1 实验 1 2 3
658 Vol. 43 No.4 图 2 加入海泡石纳米颗粒对钻井液塑性黏度的影响 36% 5 图 5 加入滤失控制剂对含海泡石纳米颗粒钻井液滤失量的影响 图 3 加入海泡石纳米颗粒对钻井液动切力的影响 2% NaCl ARIEH S [12] 4 0.69 MPa 100 psi 图 4 添加海泡石纳米颗粒对钻井液滤失量的影响 2.2 实验 2 6 7 50~180 3.45~41.37 MPa 6 7 0~135 mpa s 0~74.2 Pa 35 mpa s 7.1~14.2 Pa 6 7 15~40 mpa s 0~14.2 Pa 2.3 实验 3 8 60 10.35 MPa 15%
2016 8 AL-MALKI Needaa 659 图 6 温度对添加海泡石纳米颗粒前后膨润土基钻井液流变性的影响 图 7 压力对添加海泡石纳米颗粒前后膨润土钻井液流变性的影响 9 10 11 12 13
660 Vol. 43 石油勘探与开发 石油工程 No.4 米颗粒的膨润土基钻井液引起的砂岩渗透率降低量要 低 23.4% 显著减轻了地层伤害 图8 储集层温度压力条件下添加海泡石纳米颗粒前后 含盐膨润土基钻井液的滤失量对比 大量侵入地层 由表 3 可知 添加海泡石纳米颗粒的膨润土基钻 井液引起的砂岩岩心渗透率降低量比不添加海泡石纳 图 10 图 11 图 12 图9 驱替实验前岩心样品扫描电镜照片 不添加海泡石纳米颗粒的膨润土钻井液驱替后的注入端岩心扫描电镜照片 添加海泡石纳米颗粒的膨润土钻井液驱替后的注入端岩心扫描电镜照片 不添加海泡石纳米颗粒的膨润土钻井液驱替后的出口端岩心扫描电镜照片
2016 8 AL-MALKI Needaa 661 图 13 添加海泡石纳米颗粒的膨润土钻井液驱替后的出口端岩心扫描电镜照片 表 3 添加海泡石纳米颗粒前后膨润土基钻井液引起的砂岩岩心渗透率降低量对比 3 / / 10 3 μm 2 10 3 μm 2 /% 19.87 6.62 66.7 27.83 15.79 43.3 50~180 3.45~41.37 MPa 15% 23.4% 参考文献 : [1] İŞÇI E, TURUTOĞLU S İ. Stabilization of the mixture of bentonite and sepiolite as a water based drilling fluid[j]. Journal of Petroleum Science & Engineering, 2011, 76(1): 1-5. [2] ALTUN G, OSGOUEI A E, OZYURTKAN M H, et al. Sepiolite based muds as an alternate drilling fluid for hot environments[c]// Proceedings of the 2015 World Geothermal Congress. Melbourne: International Geothermal Association, 2015. [3] ALTUN G, SERPEN U. Investigating improved rheological and fluid loss performance of sepiolite muds under elevated temperatures[c]// Proceedings of the 2005 World Geothermal Congress. Antalya, Turkey: International Geothermal Association, 2005: 2440-2452. [4] OSGOUEI A E, OZYURTKAN M H, ALTUN G. Dynamic filtration properties of fresh water sepiolite-based muds[j]. Energy Sources Part A Recovery Utilization & Environmental Effects, 2014, 36(19): 2079-2086. [5] SRIVATSA J T, ZIAJA M B. An experimental investigation on use of nanoparticles as fluid loss additives in a surfactant-polymer based drilling fluids[r]. IPTC 14952-MS, 2011. [6] SENSOY T. Use of nanoparticles for maintaining shale stability[d]. Austin: University of Texas at Austin, 2009. [7] CAI J, CHENEVERT M, SHARMA M, et al. Decreasing water invasion into Atoka shale using nonmodified silica nanoparticles[j]. SPE Drilling & Completion, 2012, 27(1): 103-112. [8] PAIAMAN A M, DURAYA B. Using nanoparticles to decrease differential pipes sticking and its feasibility in Iranian oil fields[j]. NAFTA, 2009, 60(12): 645-647. [9] MORONI L P, VICKERS S R, GRAY C, et al. Good things come in little packages: nanotechnology for reduction in pore pressure transmission[r]. SPE 170687-MS, 2014. [10] ABDO J, HANEEF M D. Clay nanoparticles modified drilling fluids for drilling of deep hydrocarbon wells[j]. Applied Clay Science, 2013, 86(48): 76-82. [11] ØREN P E, BAKKE S. Reconstruction of Berea sandstone and pore-scale modelling of wettability effects[j]. Journal of Petroleum Science and Engineering, 2003, 39(3): 177-199. [12] ARIEH S, EMILIO G. Developments in palygorskite-sepiolite research: A new outlook on these nanomaterials[m]. 1st ed. Amsterdam: Elsevier, 2011. 第一作者简介 :AL-MALKI Needaa(1989-), 女, 阿曼人, 苏丹卡布斯大学石油化工学院硕士研究生, 主要从事钻井工程方面的研究工作 地址 :Petroleum Development Oman (PDO), Muscat, Oman E-mail : needa.nm.malki@pdo.co.om 联系作者 :POURAFSHARY Peyman(1979-), 男, 伊朗人, 苏丹卡布斯大学石油化工学院助理教授, 主要从事提高采收率方面的研究工作 地址 :Department of Petroleum and Chemical Engineering, Sultan Qaboos University, Muscat, Oman E-mail:pourafshary@squ.edu.om 收稿日期 :2015-09-13 修回日期 :2016-05-25 胡苇玮