彭水区块水平井简化全井段流态模拟及流型图版优选

魏瑞玲; 王光彪; 魏风玲; 段承琏; 刘静; 吴小丁

doi:10.13809/j.cnki.cn32-1825/te.2020.01.011

油气藏评价与开发 >

2020 , Vol. 10 >Issue 1: 71 - 76

DOI: https://doi.org/10.13809/j.cnki.cn32-1825/te.2020.01.011

工程工艺

彭水区块水平井简化全井段流态模拟及流型图版优选

魏瑞玲 ,
王光彪 ,
魏风玲 ,
段承琏 ,
刘静 ,
吴小丁

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^1. 中国石化中原油田石油工程技术研究院,河南濮阳 457000
^2. 西南石油大学石油与天然气工程学院,四川成都 610500

魏瑞玲（1975 —）,女,本科,高级工程师,主要从事采气工艺研究与推广工作。通讯地址：河南省濮阳市中原油田石油工程技术研究院,邮政编码：457000。E-mail：308645178@qq.com

收稿日期: 2019-07-22

网络出版日期: 2020-02-04

基金资助

国家科技重大专项“高效排水采气工艺技术应用研究”(2016ZX05061-017)

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Simulation of wellbore flow pattern and optimization of flow pattern of simplified horizontal well in Pengshui block

Ruiling WEI ,
Guangbiao WANG ,
Fengling WEI ,
Chenglian DUAN ,
Jing LIU ,
Xiaoding WU

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^1. Research Institute of Petroleum Engineering, Sinopec Zhongyuan Oilfield Company, Puyang, Henan 457000, China
^2. Petroleum Engineering School, Southwest Petroleum University, Chengdu, Sichuan 610500, China

Received date: 2019-07-22

Online published: 2020-02-04

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摘要

准确判断产水水平气井井筒流型是预测井筒生产动态、合理选取人工举升措施的关键。基于彭水区块气井实际生产情况,设计了一套可视化、可变角度的空气、水两相流动模拟实验装置,并且采用相似准则开展5种管斜角、6种气速、5种液速共150组两相流动模拟实验,归纳出4种流型类型,再分析角度、气速、液速对流型的影响：气速对垂直、倾斜管段流型影响较大,随气速的降低,流型依次表现为环状流、搅动流、段塞流;而液流速对各管段流型影响较小。最后将实验流型与文献中典型流型图板进行对比优选,确定了适用于彭水区块的两相流流型图板：垂直管AZIZ流型图+倾斜管GOULD流型图+水平管GOIVER流型图。其研究成果能有效预测井筒流态变化,为后续人工举升工艺的选取提供技术支撑。

关键词： 彭水区块; 水平井; 两相管流; 实验; 流型图

本文引用格式

魏瑞玲 , 王光彪 , 魏风玲 , 段承琏 , 刘静 , 吴小丁 . 彭水区块水平井简化全井段流态模拟及流型图版优选[J]. 油气藏评价与开发, 2020 , 10(1) : 71 -76 . DOI: 10.13809/j.cnki.cn32-1825/te.2020.01.011

Abstract

Accurate judgement of the wellbore flow pattern of water producing horizontal gas wells is the key to predict the wellbore production dynamics and reasonable selection of artificial lift measures. Based on the gas well production data of Pengshui block, a set of visual air-water two-phase flow simulation experimental device with variable deviation angle is designed. And the similarity criterion is used to carry out 150 groups of two-phase flow simulation experiments, including five pipe bevel angles, six gas velocities and five liquid velocities. Finally, four flow types are summarized and the influences of angle, gas velocity and liquid velocity on the convection type are analyzed. Gas velocity has a great influence on flow pattern in vertical and inclined pipe sections. With the decrease of gas velocity, flow pattern shows in turn as annular flow, agitating flow and slug flow. However, the liquid velocity has little effect on the flow pattern of each section. By comparing the experimental flow pattern with the typical flow pattern chart of the reference articals, the two-phase flow pattern chart suitable for the Pengshui block is optimized, that is, AZIZ flow pattern chart of vertical pipe + GOULD flow pattern chart of inclined pipe + GOIVER flow pattern chart of horizontal pipe. The research results can effectively predict wellbore flow pattern changes and provide technical support for the adoption of subsequent artificial lifting process.

Key words： Pengshui block; horizontal well; two-phase tube flow; experiment; flow pattern

参考文献

[1]	孙玉平, 陆家亮, 巩玉政 , 等. 我国气藏水平井技术应用综述[J]. 天然气技术与经济, 2011,5(1):24-27.
[1]	SUN Y, LU J L, GONG Y Z , et al. Review and suggestion on application of horizontal-well technology to gas reservoirs in China[J]. Natural Gas Technology and Economy, 2011,5(1):24-27.
[2]	吴月先, 钟水清, 徐永高 , 等. 中国水平井技术实力现状及发展趋势[J]. 石油矿场机械, 2008,37(3):33-36.
[2]	WU Y X, ZHONG S Q, XU Yonggao , et al. Present condition of horizontal well technique strength and its development trend in China[J]. Oil Field Equipment, 2008,37(3):33-36.
[3]	BAGHERIAN B, SARMADIVALEH M, GHALAMBOR A, et al. Optimization of multiple-fractured horizontal tight gas well[C]// paper SPE-127899-MS presented at the SPE International Symposium and Exhibition on Formation Damage Control, 10-12 February 2010, Lafayette, Louisiana, USA.
[4]	袁照永 . 水平井环空泡沫携岩流动规律研究[D]. 北京:中国石油大学, 2009: 53-55.
[4]	YUAN Z Y . Research on cuttings transport phenomenon with foam in annulus of horizontal wells[D]. Beijing: China University Of Petroleum, 2009: 53-55.
[5]	宋红伟, 郭海敏, 戴家才 . 水平井生产测井气水两相流流型试验分析[J]. 石油天然气学报, 2011,33(12):96-101.
[5]	SONG H W, GUO H M, DAI J C , et al. Experimental analysis of gas-water flow pattern during production well logging in horizontal wells[J]. Journal of Oil and Gas Technology, 2011,33(12):96-101.
[6]	黄建勇, 李明忠 . 水平井井筒流动模拟实验装置[J]. 中国石油大学学报(自然科学版), 1994,18(S1):56-60.
[6]	HUANG J Y, LI M Z . Development Of The Experimental Facility For Modelling Multiphase Folw In Horizontal Wellbore[J]. Journal of China University of Petroleum(Edition of Natural Science), 1994,18(S1):56-60.
[7]	谢宾, 陆灯云, 张剑 , 等. 水平井连续油管冲砂与分流实验装置的研制[J]. 天然气工业, 2009,29(11):67-69.
[7]	XIE B, LU D Y, ZHANG J , et al. Development of experimental facilities for sand washing and fluid diverting of coiled tubing in horizontal wells[J]. Natural Gas Industry, 2009,29(11):67-49.
[8]	肖高棉, 李颖川, 喻欣 . 气藏水平井连续携液理论与实验[J]. 西南石油大学学报(自然科学版), 2010,32(3):122-126.
[8]	XIAO G M, LI Y C, YU X . Theory and experiment research on the liquid continuous removal of horizontal gas well[J]. Journal of Southwest Petroleum University(Science & Technology Edition), 2010,32(3):122-126.
[9]	高升 . 定向气井携液临界流量实验及应用[D]. 成都:西南石油大学, 2012: 6-18.
[9]	GAO S . Critical gas flow rate experiment and application in slant wells[D]. Chengdu: Southwest Petroleum University, 2012: 6-18.
[10]	王琦 . 水平井井筒气液两相流动模拟实验研究[D]. 成都:西南石油大学, 2014: 26-31.
[10]	WANG Q . Experimental study on gas-liquid flowig in the wellbore of horizontal well[D]. Chengdu: Southwest Petroleum University, 2014: 26-31.
[11]	DUNS H, Jr, ROS N C J. Vertical flow of gas and liquid mixtures in wells[C]// paper WPC-10132 presented at the 6th World Petroleum Congress, 19-26 June 1963, Frankfurt am Main, Germany.
[12]	ORKISZEWSKI J . Predicting two-phase pressure drops in vertical pipes[J]. Journal of Petroleum Technology, 1967,19(6):829-838.
[13]	AZIZ K, GOVIER G W . Pressure drop in wells producing oil and gas[J]. Journal of Canadian Petroleum Technology, 1972,11(3):38-47.
[14]	TAITEL Y, BORNEA D, DUKLER A E . Modelling flow pattern transitions for steady upward gas-liquid flow in vertical tubes[J]. AlChE Journal, 1980,26(3):345-354.
[15]	高庆华, 李天太, 赵亚杰 , 等. 井筒气液两相流流动特性模拟试验研究[J]. 长江大学学报(自然科学版), 2014,11(14):84-87.
[15]	GAO Q H, LI T T, ZHAO Y J , Et al. Simulated experiment of flow characteristics with gas-liquid two-phase flow in wellbore[J]. Journal of Yangtze University(Nature Science Edition), 2014,11(14):84-87.
[16]	GOULD T . Vertical two-phase flow in oil and gas well[D]. Michigan: University of Michigan, 1972.
[17]	BARNEA D, SHOHAM O, TAITEL Y , Et al. Flow pattern transition for gas-liquid flow in horizontal and inclined pipes. Comparison of experimental data with theory[J]. International Journal of Multiphase Flow, 1980,6(3):217-225.
[18]	DIAZ M, NYDAL O J. Inlet effects on flow regimes in downwards inclined pipes[C]// paper OTC-26121-MS presented at the OTC Brasil, 27-29 October 2015, Rio de Janeiro, Brazil.
[19]	GOVIER G W, AZIZ K . The flow of complex mixtures in pipes[M]. New York: Van Nostrand Reinhold Company, 1972.
[20]	MANDHANE J M, GREGORY G A, AZIZ K . A flow pattern map for gas-liquid flow in horizontal pipes[J]. International Journal of Multiphase Flow, 1973,1(4):537-553.
[21]	邵奇 . 基于Taitel-Dukler方法的气液两相流型边界计算软件开发[J]. 当代化工, 2015,45(8):1981-1983.
[21]	SHAO Q . Development of gas-liquid two-phase flow boundary calculation software based on Taitel-Dukler method[J]. Contemporary Chemical Industry, 2015,45(8):1981-1983.
[22]	TAITEL Y, DUKLER A E . A model for predicting flow regime transitions in horizontal andnear horizontal gas-liquid flow[J]. AIChE Journal, 1976,22(1):47-55.

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