注气法双梯度钻井隔水管环空温度场模拟

doi:10.7623/syxb201404022

石油学报 ›› 2014, Vol. 35 ›› Issue (4): 779-785.DOI: 10.7623/syxb201404022

注气法双梯度钻井隔水管环空温度场模拟

马永乾¹, 孙宝江², 邵茹¹, 王志远², 刘晓兰¹

1. 中国石油化工股份有限公司胜利石油工程公司钻井工艺研究院山东东营 257017;
2. 中国石油大学石油工程学院山东青岛 266580

收稿日期:2014-02-12 修回日期:2014-06-01 出版日期:2014-07-25 发布日期:2014-08-05
通讯作者: 马永乾，男，1983年2月生，2005年获中国石油大学（华东）学士学位，2010年获中国石油大学（华东）博士学位，现为中国石油化工股份有限公司胜利石油工程公司钻井工艺研究院工程师，主要从事油气井流体力学研究。Email：myq0221@163.com
作者简介:马永乾，男，1983年2月生，2005年获中国石油大学（华东）学士学位，2010年获中国石油大学（华东）博士学位，现为中国石油化工股份有限公司胜利石油工程公司钻井工艺研究院工程师，主要从事油气井流体力学研究。Email：myq0221@163.com
基金资助:
国家支撑计划课题（2008BAB37B02）、国家自然科学基金项目（No.51104113）和山东省自然科学基金项目（Y2007A32）资助。

Simulation computation of temperature field in riser annulus for dual-gradient drilling using gas injection

Ma Yongqian¹, Sun Baojiang², Shao Ru¹, Wang Zhiyuan², Liu Xiaolan¹

1. Drilling Technology Research Institute, Sinopec Shengli Petroleum Engineering Corporation, ShanDong Dongying 257017, China;
2. School of Petroleum Engineering, China University of Petroleum, ShanDong Qingdao 266580, China

Received:2014-02-12 Revised:2014-06-01 Online:2014-07-25 Published:2014-08-05

摘要/Abstract

摘要：

针对注气法双梯度钻井工艺特点，根据不同流型结构特点和传热特性，考虑隔水管环空流体与海水、隔水管环空流体与钻杆内流体的传热关系，建立注气法双梯度钻井隔水管环空多相流控制方程，并给出求解方法。模拟计算结果表明：随着水深增加，环空内流体温度降低，深水低温的影响越明显；随着液体流量增加，环空内温度升高，增幅降低。由于不同流型传热规律的差异，气体流量增加仅在部分井段对温度有较大影响，入口温度升高环空内温度会相应升高，保温层对温度分布影响明显，加装保温层会使环空最低温度高10℃以上。在实际钻井过程中为防止水合物的生成和钻井液胶凝，尽可能提高液相流量，同时隔水管加装保温层，地面循环系统加装加热装置提高钻井液温度。

关键词: 注气, 双梯度钻井, 环空, 温度场, 流型, 模拟计算

Abstract:

Considering the feature of dual-gradient drilling technology via gas injection, this study establishes multiphase flow controlling equations for riser annulus in dual-gradient drilling and further provides the solution according to the heat transfer fingerprint of different flow patterns and by taking into account the heat transfer relationships of fluids in riser annulus with seawater and fluids in drilling pipes. The results of simulation computation show that with increasing water depth, the temperature in annulus rises and the impact of low temperature in deep water becomes more profound. As the liquid discharge is increased, the temperature rises while its increment declines. Because of the difference in heat transfer among various flow patterns, gas discharge only has a great effect on temperature in certain well intervals, and the temperature in annulus rises as that at the injection rises. The presence of an insulating layer significantly affects the distribution of temperature and increases the minimum temperature in the riser annulus by up to 10℃. For preventing hydrate formation and drilling fluid gelation, it is recommended to increase the liquid charge as much as possible, cover the riser with an insulating layer, and install heating equipment in the circulating system to boost the drilling fluid temperature.

Key words: gas injection, dual-gradient drilling technology, annulus, temperature field, flow pattern, simulation computation

中图分类号:

TE52

马永乾, 孙宝江, 邵茹, 王志远, 刘晓兰. 注气法双梯度钻井隔水管环空温度场模拟[J]. 石油学报, 2014, 35(4): 779-785.

Ma Yongqian, Sun Baojiang, Shao Ru, Wang Zhiyuan, Liu Xiaolan. Simulation computation of temperature field in riser annulus for dual-gradient drilling using gas injection[J]. ACTA PETROLEI SINICA, 2014, 35(4): 779-785.

参考文献

[1] 王志远,孙宝江,程海清,等.深水井控过程中天然气水合物生成区域预测[J].应用力学学报,2009,26(2):224-229.
Wang Zhiyuan,Sun Baojiang,Cheng Haiqing,et al.Prediction of natural gas hydrate formation area during deep water well control[J].Chinese Journal of Applied Mechanics,2009,26(2):224-229.
[2] 王志远,孙宝江,高永海,等.深水司钻法压井模拟计算[J].石油学报,2008,29(5):786-790.
Wang Zhiyuan,Sun Baojiang,Gao Yonghai,et al.Simulation computation of well killing with deepwater driller's method[J].Acta Petrolei Sinica,2008,29(5):786-790.
[3] 许亮斌,蒋世全,陈国明,等.深水双梯度钻井技术[R].上海:中国深水油气开发工程高技术论坛,2005:251-257.
Xu Liangbin,Jiang Shiquan,Chen Guoming,et al.The deepwater dual-gradient drilling technology[R].Shanghai:High Technology Forum of China Deepwater Oil and Gas Development Project,2005:251-257.
[4] Kabir C S,Hasan A R.Predicting fluid temperature profiles in gas-lift wells[R].SPE 26098,1993.
[5] 高永海,孙宝江,王志远,等.深水钻探井筒温度场的计算与分析[J].中国石油大学学报:自然科学版,2008,4(2):58-62.
Gao Yonghai,Sun Baojiang,Wang Zhiyuan,et al.Calculation and analysis of well bore temperature field in deepwater drilling[J].Journal of China University of Petroleum:Edition of Natural Science,2008,4(2):58-62.
[6] Martinelli R C,Boelter L M K,Taylor T H M,et al.Isothermal pressure drop for Two-phase Two-component flow in horizontal pipes[J].Chemical Engineering Progress,1944(40):136~141.
[7] Zuber N,Findly J.Average volumetric concentration in two phase flow systems[J].ASME Journal of Heat Transfer,1965,87(11):453-546.
[8] Barbosa Jr.J R,Govan A H,Hewitt G F.Visualisation and modelling studies of churn flow in a vertical pipe[J].International Journal of Multiphase Flow,2001,27(12):2105-2127.
[9] 马永乾,孙宝江,王志远,等.垂直上升气液柱塞流中含气率分布[J].中国石油大学学报:自然科学版,2010,34(1):64-69.
Ma Yongqian,Sun Baojiang,Wang Zhiyuan,et al.void fraction distribution of vertical upward gas-liquid slug flow[J].Journal of China University of Petroleum,2010,34(1):64-69.
[10] 高永海.深水油气钻探井筒多相流动与井控的研究[D].东营:中国石油大学(华东),2007.
Gao Yonghai.Study on Multi-phase flow in wellbore and well control in deep water drilling[D].Dongying:China University of Petroleum (East China),2007.
[11] Abdul-Majeed G H,Al-Mashat A M.A mechanistic model for vertical and inclined two-phase slug flow[J].Journal of Petroleum Science and Engineering,2000,27(1/2):59-67.
[12] Kim D,Ghajar A J,Dougherty R L,et al.Comparison of 20 Two-Phase heat transfer correlations with seven sets of experimental data,including flow pattern and tube inclination effects[J].Heat Transfer Engineering,1999,20(1):15-40.
[13] Ovan A H,Hewitt G F,Richter H J,et al.flooding and churn flow in vertical piples[J].International Journal of Multiphase Flow,1991,17(1):27-44.
[14] Taitel Y,Barnea D,Dukler A E.Modeling flow pattern transition For steady upward Gas-Liquid flow in vertical flow in vertical tubes[J].AIChE Journal,1980,26(3):345-354.
[15] Dranchuk P M,Purvis R A,Robinson D B.Computer calculations of natural gas compressibility factors using the standing and katz correlation[J].Inst of Petroleum Technical Series,1974,36(4):76-80.
[16] 沈维道,蒋智敏,童钧耕.工程热力学[M].北京:高等教育出版社,2001.
Shen Weidao,Jiang Zhimin,Tong Jungeng.Engineering thermodynamics[M].Beijing:Higher Education Press,2001.
[17] 郭绪强,荣淑霞,杨继涛,等.纯组分高压流体的粘度模型[J].石油大学学报:自然科学版,1998,22(6):95-97.
Guo Xuqiang,Rong Shuxia,Yang Jitao,et al.A model for calculating viscosity of high pressure fluids with pure substances[J].Journal of the University of Petroleum,China,1998,22(6):95-97.
[18] 吴彬,向兴金,张岩,等.深水低温条件下水基钻井液的流变性研究[J].钻井液与完井液,2006,23(3):12-19.
Wu Bin,Xiang Xingjin,Zhang Yan,et al.Rheology study of the water based drilling fluids at deep water and low temperature[J].Drilling Fluid & Completion Fluid,2006,23(3):12-19.

注气法双梯度钻井隔水管环空温度场模拟

Simulation computation of temperature field in riser annulus for dual-gradient drilling using gas injection

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