异常高压气藏气水两相流井产能分析方法

张辉; 王磊; 汪新光; 周伟; 曾小明; 刘昌为; 赵楠; 汪来潮; 王新斌; 王文涛

doi:10.11698/PED.2017.02.10

石油勘探与开发 >

2017 , Vol. 44 >Issue 2: 258 - 262

DOI: https://doi.org/10.11698/PED.2017.02.10

油气田开发

异常高压气藏气水两相流井产能分析方法

张辉 ,
王磊 ,
汪新光 ,
周伟 ,
曾小明 ,
刘昌为 ,
赵楠 ,
汪来潮 ,
王新斌 ,
王文涛

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1. 中海石油（中国）有限公司湛江分公司,广东湛江 524057;
2. 中国地质大学（北京）,北京 100083

张辉（1979-）,男,陕西咸阳人,学士,中海石油（中国）有限公司湛江分公司高级工程师,主要从事油气田早期评价、油气田开发评价等方面的研究工作。地址：广东省湛江市坡头区中海石油（中国）有限公司湛江分公司,邮政编码：524057。E-mail：zhanghui4@cnooc.com.cn

收稿日期: 2016-04-26

修回日期: 2017-01-16

网络出版日期: 2017-05-22

基金资助

“十三五”重大专项“莺琼盆地高温高压天然气富集规律与勘探开发关键技术”（2016ZX05024005）

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Productivity analysis method for gas-water wells in abnormal overpressure gas reservoirs

ZHANG Hui ,
WANG Lei ,
WANG Xinguang ,
ZHOU Wei ,
ZENG Xiaoming ,
LIU Changwei ,
ZHAO Nan ,
WANG Laichao ,
WANG Xinbin ,
WANG Wentao

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1. China National Offshore Oil Corporation (China) LTD. Zhanjiang Branch, Zhanjiang 524057, China;
2. China University of Geoseiences, Beijing 100083, China

Received date: 2016-04-26

Revised date: 2017-01-16

Online published: 2017-05-22

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摘要

提出了综合考虑气水两相渗流能力变化、储集层与流体的弹性驱动能量和应力敏感引起的储集层物性变化等因素的异常高压气藏气水两相流井产能分析方法,并结合实例分析了各因素对产气量的影响。基于广义达西公式和质量守恒定律建立了考虑储集层应力敏感和气水两相渗流能力变化的稳态及非稳态渗流数学模型,推导了相应的产气量方程。实例分析结果表明：储集层含水率上升造成气相渗流能力减小,导致产气量降低,在气水两相流井产能评价过程中不能忽视气水两相渗流能力变化对产气量的影响;生产压差较小时产气量随储集层应力敏感性增强变化不大,而生产压差较大时产气量随储集层应力敏感性增强显著减小,对于应力敏感性气藏,初期生产压差不宜过高。图4参23

关键词： 含水气藏; 异常高压气藏; 应力敏感性; 气水两相流; 稳态渗流; 非稳态渗流; 气井产能

本文引用格式

张辉 , 王磊 , 汪新光 , 周伟 , 曾小明 , 刘昌为 , 赵楠 , 汪来潮 , 王新斌 , 王文涛 . 异常高压气藏气水两相流井产能分析方法[J]. 石油勘探与开发, 2017 , 44(2) : 258 -262 . DOI: 10.11698/PED.2017.02.10

Abstract

A productivity analysis for gas-water wells in abnormal overpressure gas reservoirs, considering seepage capability changes of gas-water two phases, elastic drive energy of reservoir and fluid, physical property changes caused by stress sensitivity of reservoir etc, is proposed, and the influences of various factors on gas production rate are analyzed by practical examples. Based on generalized Darcy formula and the law of conservation of mass, mathematical models of steady-state and unsteady-state seepage considering stress sensitivity of reservoirs and seepage capability changes of gas-water two phases are established, then, corresponding formulas of gas production rate are deduced. Results of practical example analysis show that: the increase of reservoir water content causes decrease of seepage capability of gas phase, and thus declining the gas production rate, so the influence of seepage capability changes of gas-water two phases on gas production rate cannot be ignored in the process of productivity evaluation for gas-water wells; gas production rate has smaller variations with the increase of stress sensitivity when production pressure drop is small, while gas production rate decreases significantly with the increase of stress sensitivity when production pressure drop is large. Therefore, the production pressure drop of gas wells at the beginning of the development should not be too high for gas reservoirs with high stress sensitivity.

Key words： water-bearing gas reservoir; abnormal overpressure gas reservoir; stress sensitivity; gas-water two phases; steady-state seepage; unsteady-state seepage; gas well productivity

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