抗高温硅酸盐钻井液体系室内研究
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摘要
硅酸盐钻井液在解决井壁失稳问题具有突出优势,但目前对硅酸盐钻井液体系在高温条件下的研究较少,制约着硅酸盐钻井液体系的推广应用。通过硅酸盐、高温流变调节剂、降失水剂及pH稳定剂等单剂的筛选,最终确定硅酸盐钻井液体系配方,并进行了性能评价。结果表明:所研究的硅酸盐钻井液体系可以抗170℃高温,体系流变及高温高压失水均可满足需求;体系具有较好的抗钻屑、海水及盐污染的能力,侵污前后流变相差不大;该硅酸盐钻井液体系具有较好的抗温性能和抗搬土污染性能。
Silicate drilling fluid has outstanding advantages in solving the problem of wellbore instability. However, there are few studies on silicate drilling fluid system under high temperature conditions, which restricts the popularization and application of silicate drilling fluid system. Through the screening of single agents such as silicate, high temperature rheology modifier, fluid loss reducer and rheological stabilizer, the formula of silicate drilling fluid system was finally determined and the performance was evaluated. The results showed that the silicate drilling fluid system could resist high temperature of 170 °C, and the system rheology and high temperature and high pressure water loss met the drilling demand. It could resist 15% of soil pollution, and the rheology before and after pollution was not much different. The silicate drilling fluid system has good temperature resistance and resistance to soil contamination.
Silicate drilling fluid has outstanding advantages in solving the problem of wellbore instability. However, there are few studies on silicate drilling fluid system under high temperature conditions, which restricts the popularization and application of silicate drilling fluid system. Through the screening of single agents such as silicate, high temperature rheology modifier, fluid loss reducer and rheological stabilizer, the formula of silicate drilling fluid system was finally determined and the performance was evaluated. The results showed that the silicate drilling fluid system could resist high temperature of 170 °C, and the system rheology and high temperature and high pressure water loss met the drilling demand. It could resist 15% of soil pollution, and the rheology before and after pollution was not much different. The silicate drilling fluid system has good temperature resistance and resistance to soil contamination.
引文
[1]何恕,郑涛,敬增秀,等.利用压力传递实验技术评价硅酸盐钻井液井壁稳定[J].钻井液与完井液, 2001,18(6):10-13.
[2]张金波,范维旺,宁军明,等.KCl/硅酸盐钻井液体系在苏丹6区的成功应用[J].钻井液与完井液, 2007,24(6):81-83.
[3]王书琪,梁大川,何涛,等.降低地层坍塌压力增加幅度的钻井液技术[J].钻井液与完井液, 2008,25(3):22-24.
[4]孟丼艳,黄宁,张麒麟.硅酸盐钻井液体系的研究进展[J].精细石油化工进展, 2012,13(12):37-38.
[5] Duncan J, McDonald M. Exceeding Drilling Performance and environmental requirements with potassium silicate based drilling fluid[C]. SPE 86700-MS, 2004.
[6]梁大川,罗平亚,刘向君,等.钻井液处理剂及体系对泥页岩坍塌压力的影响研究[J].钻采工艺, 2011,34(2):83-84.
[7]吴靖,王昌军,由福昌.纳米技术在钻井液和储层保护中的应用[J].当代化工,2018,47(1):140-143.
[8]孙玉学,杨婧娜,朱红.硅酸盐钻井液室内评价与研究[J].科学技术与工程,2010,10(25):6068-6270.
[9]汪传伟,李皋,严俊涛,等.川南硬脆性页岩井壁失稳机理实验研究[J].科学技术与工程,2012,12(30):8012-8014.
[10]罗健生,徐绍成,王雪山,等.硅酸盐钻井液对泥页岩地层井眼稳定性影响研究[J].钻井液与完井液, 2006,23(2):18-20.
[2]张金波,范维旺,宁军明,等.KCl/硅酸盐钻井液体系在苏丹6区的成功应用[J].钻井液与完井液, 2007,24(6):81-83.
[3]王书琪,梁大川,何涛,等.降低地层坍塌压力增加幅度的钻井液技术[J].钻井液与完井液, 2008,25(3):22-24.
[4]孟丼艳,黄宁,张麒麟.硅酸盐钻井液体系的研究进展[J].精细石油化工进展, 2012,13(12):37-38.
[5] Duncan J, McDonald M. Exceeding Drilling Performance and environmental requirements with potassium silicate based drilling fluid[C]. SPE 86700-MS, 2004.
[6]梁大川,罗平亚,刘向君,等.钻井液处理剂及体系对泥页岩坍塌压力的影响研究[J].钻采工艺, 2011,34(2):83-84.
[7]吴靖,王昌军,由福昌.纳米技术在钻井液和储层保护中的应用[J].当代化工,2018,47(1):140-143.
[8]孙玉学,杨婧娜,朱红.硅酸盐钻井液室内评价与研究[J].科学技术与工程,2010,10(25):6068-6270.
[9]汪传伟,李皋,严俊涛,等.川南硬脆性页岩井壁失稳机理实验研究[J].科学技术与工程,2012,12(30):8012-8014.
[10]罗健生,徐绍成,王雪山,等.硅酸盐钻井液对泥页岩地层井眼稳定性影响研究[J].钻井液与完井液, 2006,23(2):18-20.
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