A New Low Density Slag Cementing Slurry
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摘要: 针对漂珠、空心玻璃微珠等减轻剂价格昂贵、使用量大、其浆体与钻井液相容性较差等问题,借鉴钻井液转化为水泥浆(MTC)技术,直接以矿渣作为胶凝材料替代油井水泥配制固井液,并研究了配套的激活剂和缓凝剂。通过大量的室内实验,初步筛选出一种碱金属氢氧化物JHQ和一种碱金属硅酸盐JGY作为激活剂,并最终确定他们的掺量分别为3%和2%,此时固化体3 d的抗压强度可达到12.5 MPa ;体系采用的缓凝剂HNJ主要靠分子中α和β位羟基羧酸基团能与Ca2+有很强的螯合作用,形成高度稳定的五元环或六元环,部分吸附于矿渣颗粒上,阻止水化产物性能,以达到延长工作液稠化时间的目的,浆体稠化时间与缓凝剂HNJ掺量几乎呈线性增长趋势;体系选用具有提高浆体稳定性和控制失水能力的膨润土类悬浮剂GYW-201,并配合使用悬浮稳定作用强的高聚物悬浮剂GYW-301。结果表明,矿渣固井液适用温度为50~90℃,密度在1.30~1.50 g/cm3范围可调,具有成本低、失水量低、沉降稳定性良好、与钻井液相容性好、稠化时间线性可调、低温下强度发展迅速等优点。该体系已应用于江苏油田现场作业,固井质量良好。因此该矿渣固井液可替代低密度水泥浆,用于低压易漏井、长封固段、欠平衡井等固井施工,降低固井成本。Abstract: Floating beads and hollow glass beads are commonly used lightweight additives in cement slurries. These lightweight additives are expensive, and generally large amount of them are needed in formulating cement slurries of required density. Cement slurries treated with floating beads and hollow glass beads have poor compatibility with drilling fluids. A clue borrowed from MTC technology can be used to solve these problems, that is, using slag as a gelling material to replace oil well cement in formulating cementing slurries. Activators and retarders as assorted agents in this new technology have been studied. An alkaline metal hydroxide JHQ and an alkaline metal salt of silicate JGY were preliminarily screened out as the activators through large amount of laboratory experiments, and the concentration of the activators were determined to be 3% and 2%, respectively. At these concentrations of activators, the set cementing slurry had compressive strength of 12.5 MPa. The retarder selected, HNJ, has hydroxycarboxylic acid groups on the α and β carbon atoms that have strong chelating capacity to calcium ions. The result of the chelating was the formation of highly stable pentacyclic or hexacyclic structures. HNJ was adsorbed on the surface of slag particles to retard the hydration process and prolong the thickening time. The thickening time was almost in a positive linear relationship with the concentration of HNJ. A bentonitic suspending agent, GYW-201, was selected to enhance the stability of the cementing slurry and to control flter loss. GYW-301, a high polymer suspending agent, was used in combination with GYW-201. The slag cementing slurry is suitable for use at 50-90℃, and has density adjustable between 1.30 g/cm3 and 1.50 g/cm3. Low cost, low flter loss, good sedimentation stability, good compatibility with drilling fluids, linearly adjustable thickening time, fast-developing low temperature strength were the advantages of the cementing slurry. Good cementing job quality has been obtained in the Jiangsu oilfeld. As a low cost technology, this new slag cementing slurry has the potential to replace low density cement slurry in cementing low pressure wells liable to lost circulation, wells with long cementing section, and under-balanced wells.
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[1] 刘学鹏, 张明昌, 冯明慧, 等. 复合空心微珠低密度水泥浆的研究与应用[J]. 石油钻采工艺, 2014, 36(6):39-41.LIU Xuepeng, ZHANG Mingchang, FENG Minghui, et al. The research and application of low density cement slurry of composite hollow microsphere[J]. Oil Drilling & Production Technology, 2014, 36(6):39-41. [2] 马春旭, 段志伟, 刘富芳, 等. 人造微珠低密度水泥浆的研究与应用[J]. 钻井液与完井液, 2014, 31(2):62-64.MA Chunxu, DUAN Zhiwei, LIU Fufang, et al. The research and appliction of low density cement slurry of Synthetic beads[J]. Drilling Fluid & Completion Fluid, 2014, 31(2):62-64. [3] 文湘杰, 袁建强, 宋艳霞, 等. 漂珠低密度水泥浆在安棚碱井的应用[J]. 钻井液与完井液, 2003, 20(2):58-59.WEN Xiangjie, YUAN Jianqiang, SONG Yanxia, et al. Drift beads low density cement slurry in the application of Ann tent alkali Wells[J]. Drilling Fluid & Completion Fluid, 2003, 20(2):58-59. [4] 王成文. 复杂井固井低密度水泥浆体系研究[D]. 西南石油学院, 2004. WANG Chengwen. The research of low density cement slurry system in complex well cementing[D]. Chengdu:Southwest petroleum university, 2004. [5] 李明, 齐奉忠, 靳建洲, 等. 适合煤层气井固井的低密度水泥浆体系[J]. 天然气工业, 2011, 31(7):63-66.LI Ming, QI Fengzhong, JIN Jianzhou, et al. The low density cement slurry system suitabled for CBM well cementing[J]. Natural Gas Industry, 2011, 31(7):63-66. [6] 张伟, 魏瑞华, 杨洪, 等. 超低密度水泥浆固井技术的应用——以百泉1井为例[J]. 天然气工业, 2012, 3(24):69-71.ZHANG Wei, WEI Ruihua, YANG Hong, et al. The application of ultra low density cement slurry cementing technology-in BaiQuan 1 Well[J]. Natural Gas Industry, 2012, 32(4):69-71. [7] 庄成宏, 王良才. 粉煤灰低密度水泥浆在塔河油田简化井身结构井中的应用[J]. 天然气勘探与开发, 2011, 34(3):76-79.ZHUANG Chenghong, WANG Liangcai. The application of fly ash low density cement slurry to the simplified structure of well bore Wells in Tahe Oilfield[J]. Natural Gas Exploration and Development, 2011, 34(3):76-79. [8] 周剑, 高德伟, 严海兵. 早强低密度水泥浆体系提高低压易漏井固井质量[J]. 天然气工业, 2012, 32(4):72-74.ZHOU Jian, GAO Dewei, YAN Haibing. The low density cement slurry system improved the low-voltage leakage well cementing quality[J]. Natural Gas Industry, 2012, 32(4):72-74. [9] 张林海, 郭小阳, 李早元, 等. 一种提高注水泥质量的可固化工作液体系研究[J]. 西南石油大学学报, 2007(S2):85-88. ZHANG Linhai, GUO Xiaoyang, LI Zaoyuan, et al. A research of curing fluid system to improve the cementing quality[J]. Journal of southwest petroleum university, 2007(S2):85-88. [10] LEIMKUHLER J M, RAINBOW F H K, WARREN P B, et al. Downhole performance evaluation of blast furnace slag-based cements:onshore and offshore field applications[C]//SPE Annual Technical Conference and Exhibition. Society of Petroleum Engineers, 1994. [11] 彭志刚, 何育荣, 刘崇建, 等. 矿渣MTC固化体开裂的本质原因分析[J]. 天然气工业, 2005, 25(5):72-74.PENG Zhigang, HE Yurong, LIU Chongjian, et al. Analysis of the reason that slag MTC solidified body cracked[J]. Natural Gas Industry, 2005, 25(5):72-74. [12] 路宁. 用多功能钻井液设计超低密度矿渣水泥浆[J]. 钻采工艺, 1998(6):63-66. LU Ning. Ultra low density slag cement designed by multifunctional drilling fluid[J]. Drilling & Production Technology, 1998(6):63-66. [13] 吴达华, 吴永革. 高炉水淬矿渣结构特性及水化机理[J]. 石油钻探技术, 1997, 14(1):31-33.WU Dahua, WU Yongge. The structure characteristics and hydration mechanism of blast furnace water quenched slag[J]. Petroleum Drilling Techniques, 1997, 14(1):31-33.
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