Prediction of Gas-liquid Two-phase Flow Patterns in Horizontal Gas Wells

doi:10.11885/j.issn.1674-5086.2018.06.11.01

Abstract

Abstract: An accurate estimation of the flow pattern of a horizontal gas well that produces water is the key to predicating the pressure drop of the wellbore and establishing a sensible water-drainage production plan. The angle of a horizontal well constantly varies from 90 ° to 0 according to the flow direction. A unified flow pattern map that describes the two-phase flow of horizontal wells has not yet been discovered. Therefore, three separate flow pattern maps are used to describe the horizontal, slanted, and vertical pipes individually. These maps are obtained under extremely different experimental conditions. In addition, the gas wells may produce extremely low water output. In such cases, the gas-liquid ratio may exceed the valid coordinate range of the commonly used gas-liquid two-phase flow pattern map leading to significant errors in the prediction results. Considering all these drawbacks, this study has developed an air-water two-phase flow simulation experimental device for horizontal, slanted, and vertical pipes. Provided the extremely high gas-liquid ratio of the gas well with water production, this study has conducted a gas-water two-phase flow pattern experiment using 7 slanted pipes and 641 horizontal pipes. It has summarized five flow patterns and the typical characteristics of horizontal gas wells. This work has used the dimensionless gas velocity number defined by Duns and Ros and the pipe inclination angle as the X-axis. A three-dimensional flow pattern map has been constructed to describe the gas-liquid two-phase pipe flow in the horizontal gas well. This study has also proposed a method to predict the flow pattern based on the back propagation neural network model. The pressure measurement results from 20 horizontal gas wells in the gas fields at Western Sichuan indicate that the flow map demonstrates an accuracy of 90% in prediction.

Key words: horizontal gas well, gas-liquid two-phase flow, pipe angle, three-dimensional flow pattern map, BP neural network

CLC Number:

TE377

LIU Yonghui, LUO Chengcheng, LIU Tong, REN Guirong, WANG Zhongwu. Prediction of Gas-liquid Two-phase Flow Patterns in Horizontal Gas Wells[J]. 西南石油大学学报(自然科学版), 2019, 41(3): 107-112.

0
/ / Recommend

Add to citation manager EndNote|Ris|BibTeX

URL: http://journal15.magtechjournal.com/Jwk_xnzk/EN/10.11885/j.issn.1674-5086.2018.06.11.01

http://journal15.magtechjournal.com/Jwk_xnzk/EN/Y2019/V41/I3/107

References

[1] AL_DUAIS M S, YAAKUB A R, YUSOFF N, et al. A novel strategy for speed up training for back propagation algorithm via dynamic adaptive the weight training in artificial neural network[J]. Research Journal of Applied Sciences, Engineering and Technology, 2015, 9(3):189-200. doi:10.19026/rjaset.9.1394
[2] TAITEL Y, BARNEA D, DUKLER A E. Modelling flow pattern transitions for steady upward gas-liquid flow in vertical tubes[J]. Aiche Journal, 1980, 26(3):345-354. doi:10.1002/aic.690260304
[3] GOVIER G W, AZIZ K. The flow of complex mixtures in pipes[M]. New York:Van Nostrand Reinhold, 1972.
[4] LIN P Y, HANRATTY T J. Effect of pipe diameter on flow patterns for air-water flow in horizontal pipes[J]. International Journal of Multiphase Flow, 1987, 13(4):549-563. doi:10.1016/0301-9322(87)90021-8
[5] 李丹,王瑞. 水平气液两相管流流型转变实验研究[J]. 中国石油和化工标准与质量, 2013(20):159. doi:10.-3969/j.issn.1673-4076.2013.20.132 LI Dan, WANG Rui. Experimental study on flow pattern transition of horizontal gas-liquid two-phase flow[J]. China Petroleum and Chemical Standard and Quality, 2013(20):159. doi:10.3969/j.issn.1673-4076.2013.20.-132
[6] 李银朋. 向上倾斜管道内气液两相流的实验研究[D]. 大庆:大庆石油学院, 2010. LI Yinpeng. Experimental study of gas-liquid two-phase flow in upward inclined pipes[D]. Daqing:Daqing Petroleum Institute, 2010.
[7] 韩洪升,张雪,徐学考,等. 倾斜管内两相流流型的实验研究[J]. 当代化工, 2015, 44(4):709-710. doi:10.-3969/j.issn.1671-0460.2015.04.015 HAN Hongsheng, ZHANG Xue, XU Xuekao, et al. Experimental study on the flow pattern of two-phase flow in inclined pipe[J]. Contemporary Chemical Industry, 2015, 44(4):709-710. doi:10.3969/j.issn.1671-0460.2015.04.-015
[8] GOULD T L. Vertical two-phase steam-water flow in geothermal wells[J]. Journal of Petroleum Technology, 1974, 26(8):833-842. doi:10.2118/4961-PA
[9] BEGGS D H, BRILL J P. A study of two phase flow in inclined pipes[J]. Journal of Petroleum Technology, 1973, 25(5):607-617. doi:10.2118/4007-PA
[10] DUNS H Jr, ROS N C J. Vertical flow of gas and liquid mixtures in wells[C]. The 6^th World Petroleum Congress, Frankfurt am Main, Germany, 1963.
[11] HEWITT G F, ROBERTS D N. Studies of two-phase flow patterns by simultaneous X-ray and flash photography[R]. Atomic Energy Research Establishment, Harwell, UK, 1969.
[12] WEISMAN J, KANG S Y. Flow pattern transitions in vertical and upwardly inclined lines[J]. International Journal of Multiphase Flow, 1981, 7(3):271-291. doi:10.1016/-0301-9322(81)90022-7
[13] 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(自科版), 2014, 11(14):84-87. doi:10.16772/j.cnki.1673-1409.-2014.14.028 GAO Qinghua, LI Tiantai, ZHAO Yajie, et al. Simulated experiment of flow characteristics with gas-liquid twophase flow in wellbore[J]. Journal of Yangtze University(Natural Science Edition), 2014, 11(14):84-87. doi:10.-16772/j.cnki.1673-1409.2014.14.028
[14] VOGL T P, MANGIS J K, RIGLER A K, et al. Accelerating the convergence of the back-propagation method[J]. Biological Cybernetics, 1988, 59(4-5):257-263. doi:10.-1007/BF00332914
[15] ZIPSER D, ANDERSEN R A. A back-propagation programmed network that simulates response properties of a subset of posterior parietal neurons[J]. Nature, 1988, 331(6158):679-684. doi:10.1038/331679a0
[16] YOON K, SHIN C, MARFURT K J. Waveform inversion using time-windowed back propagation[J]. SEG 2003-0690, 2003.doi:10.1190/1.1818027
[17] MI Y, ISHⅡ M, TSOUKALAS L H. Flow regime identification methodology with neural networks and two-phase flow models[J]. Nuclear Engineering and Design, 2001, 204(1/3):87-100. doi:10.1016/S0029-5493(00)00325-3
[18] TENGESDAL J Ø, KAYA A S, SARICA C. Flow-pattern transition and hydrodynamic modeling of churn flow[J]. SPE Journal, 1999, 4(4):342-348. doi:10.2118/57756-PA
[19] GILL L E, HEWITT G F, LACEY P M C. Sampling probe studies of the gas core in annular two-phase flow-Ⅱ:studies of the effect of phase flow rates on phase and velocity distribution[J]. Chemical Engineering Science, 1964, 19(9):665-682. doi:10.1016/0009-2509(64)85054-5
[20] GILL L E, HEWITT G F, LACEY P M C. Data on the upwards annular flow of air-water mixtures[J]. Chemical Engineering Science, 1965, 20(2):71-88. doi:10.1016/-0009-2509(65)85001-1