Lithologic Reservoirs ›› 2017, Vol. 29 ›› Issue (3): 147-151.doi: 10.3969/j.issn.1673-8926.2017.03.018

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A new method of measuring critical liquid carrying flow rate in the variable wellbore-rate gas well: a case of multi-completion gas wells in Xihu Sag, the East China Sea

LU Kefeng, JIAN Jie, ZHANG Yanzhen, ZHU Wenjuan, XIAO Han   

  1. Exploration and Development Research Institute, Shanghai Branch of CNOOC Ltd., Shanghai 200335, China
  • Received:2016-07-20 Revised:2016-09-19 Online:2017-05-21 Published:2017-05-21

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Abstract: For the constant wellbore-rate gas well, the critical liquid carrying flow rate depends on cross-sectional area of wellbore. However, in the research of multi-completion gas wells in Xihu Sag of the East China Sea, there aer 39% of the survey wells with the accumulated fluid levels located at the sliding sleeves. A set of determination method of measuring critical liquid carrying flow rate in the variable wellbore-rate gas wells was formed by building a regional critical liquid carrying flow rate model with gas wells. This method includes the selection of fitting data of model coefficient X, the condition of filtering the wellbore node where is most likely to appear accumulated fluid, and the transformation method of turning the critical liquid carrying flow rate at the wellbore node to that in the whole well. The result shows that sectional flow distribution in multi-completion gas wells results more effusion than that in single layer wells and the accumulated fluid levels are usually located at the sliding sleeves. The study has certain reference significance for rational production adjustment in multi-completion gas wells.

Key words: logging while drilling(LWD), azimuthal gamma, gamma imaging, color calibration, image processing

CLC Number: 

  • TE372
[1] 周瑞立, 周舰, 罗懿, 等.低渗产水气藏携液模型研究与应用. 岩性油气藏, 2013, 25(4):123-128. ZHOU R L, ZHOU J, LUO Y, et al. Research and application of liquid-carrying model for low permeability and water production gas reservoir. Lithologic Reservoirs, 2013, 25(4):123-128.
[2] 刘刚.气井携液临界流量计算新方法.断块油气田, 2014, 21(3):339-340. LIU G. A new calculation method for critical liquid carrying flow rate of gas well. Fault-Block Oil & Gas Field, 2014, 21(3):339-340.
[3] 赵界, 李颖川, 刘通, 等.大牛地地区致密气田气井积液判断新方法.岩性油气藏, 2013, 25(1):122-125. ZHAO J, LI Y C, LIU T, et al. A new method to judge liquid loading of gas wells in tight gas field of Daniudi area. Lithologic Reservoirs, 2013, 25(1):122-125.
[4] 宋玉龙, 杨雅惠, 曾川, 等.临界携液流量与流速沿井筒分布规律研究.断块油气田, 2015, 22(1):90-93. SONG Y L, YANG Y H, ZENG C, et al. Research on distribution of critical carrying fluid flow rate and velocity along shaft. Fault-Block Oil & Gas Field, 2015, 22(1):90-93.
[5] 刘双全, 吴晓东, 吴革生, 等.气井井筒携液临界流速和流量的动态分布研究.天然气工业, 2007, 27(2):104-106. LIU S Q, WU X D, WU G S, et al. A study on dynamic distribution of the liquid-carrying critical velocities and flow rates along the wellbore of gas wells. Natural Gas Industry, 2007, 27(2):104-106.
[6] 于继飞, 管虹翔, 顾纯巍, 等.海上定向气井临界流量预测方法.特种油气藏, 2011, 18(6):117-119. YU J F, GUAN H X, GU C W, et al. Prediction of critical flow rate for offshore directional gas wells. Special Oil & Gas Field, 2011, 18(6):117-119.
[7] 吴志均, 何顺利.低气液比携液临界流量的确定方法.石油勘探与开发, 2004, 31(4):108-111. WU Z J, HE S L. Determination of the critical liquid carrying flow rate at low gas liquid ratio. Petroleum Exploration and Development, 2004, 31(4):108-111.
[8] 王云. 气井合理油管直径选择. 特种油气藏, 2010, 17(1):108-110. WANG Y. Study on selecting reasonable tubing diameter for gas wells. Special Oil & Gas Field, 2010, 17(1):108-110.
[9] 王景芹, 朱振锐, 高纯良, 等.朝阳沟油田储气库注采井油管尺寸优选.特种油气藏, 2013, 20(2):90-92. WANG J Q, ZHU Z R, GAO C L, et al. Optimal selection of tubing size of injection & production wells in Chaoyanggou Oilfield Gas Storage. Special Oil & Gas Field, 2013, 20(2):90-92.
[10] 刘捷, 廖锐全, 陈进, 等.新疆油田气井排液采气工艺优选方法.特种油气藏, 2015, 22(1):141-143. LIU J, LIAO R Q, CHEN J, et al. Gas well liquid drainage gas recovery technology optimization in Xinjiang Oilfield. Special Oil & Gas Field, 2015, 22(1):141-143.
[11] 杨涛, 余淑明, 杨桦, 等.气井涡流排水采气新技术及其应用. 天然气工业, 2012, 32(8):63-66. YANG T, YU S M, YANG H, et al. A new technology of vortex dewatering gas recovery in gas wells and its application. Natural Gas Industry, 2012, 32(8):63-66.
[12] TURNER R G, HUBBARD M G, DUKLER A E, et al. Analysis and prediction of minimum flow rate for the continuous removal of liquids from gas wells. Journal of Petroleum Technology, 1969, 21(11):1475-1482.
[13] 李闽, 郭平, 谭光天. 气井携液新观点. 石油勘探与开发, 2001, 28(5):105-106. LI M, GUO P, TIAN G T. New look on removing liquids from gas wells. Petroleum Exploration and Development, 2001, 28(5):105-106.
[14] 汪政明, 王晓磊, 张赟, 等.预测盆5凝析气藏气井临界携液量方法及应用.新疆石油天然气, 2014, 10(3):77-82. WANG Z M, WANG X L, ZHANG Y, et al. The method and application of forecast the critical liquid carrying rate in gas well of Pen-5 condensate gas reservoir. Xinjiang Oil & Gas, 2014, 10(3):77-82.
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