高含水油藏CO2人工气顶驱油-封存适宜条件研究

doi:10.13809/j.cnki.cn32-1825/te.2024.01.007

摘要/Abstract

摘要：

针对水驱油藏开发进入高含水阶段后，剩余油常富集在构造高部位或厚油层顶部，井网控制不到的问题，利用油藏自身特点注CO₂形成气顶驱，可有效改善开发效果并实现CO₂封存，但什么样的油藏适宜开展气顶驱尚待研究。通过剖析典型高含水油藏CO₂气顶驱见效特征，分析气顶驱油过程中油气界面移动规律，结合数值模拟、物理模拟，以提高采收率幅度、换油率、到达极限气油比时间、存气率等为主要评价标准，研究地层倾角、原油密度、黏度、油藏封闭性、渗透率、水动力强弱等相关参数对CO₂气顶驱油-封存效果的影响。按照到达极限气油比时提高采收率的幅度大小，评价各参数对驱油--封存效果的影响程度，确定高含水期油藏的CO₂气顶驱油-封存筛选条件主要受油藏封闭性、地层倾角、原油黏度、油层渗透率及厚度影响，为拓展CO₂驱应用范围提供了依据。

关键词: 高含水, CO₂人工气顶, 敏感性因素, 地层倾角, 水动力强弱, 存气率

Abstract:

In the development of water-flooded oil fields entering the high water-cut stage, the remaining oil often accumulates at the top of structural high positions or thick oil layers, areas not effectively covered by the existing well network. Utilizing the intrinsic characteristics of the reservoir to inject CO₂ and form a gas cap drive can effectively improve development outcomes and achieve CO₂ sequestration. However, the suitability of specific reservoirs for gas cap drive development requires further study. This study delves into the effectiveness of CO₂ gas cap drive in high water-cut reservoirs by examining the movement of the oil-gas interface during the gas cap drive process, using both numerical and physical simulations. Key evaluation metrics include enhanced oil recovery rate, oil displacement efficiency, time to reach the critical gas-oil ratio, and gas retention rate. The research assesses how various reservoir characteristics, such as formation dip angle, crude oil density, viscosity, reservoir confinement, permeability, and the strength of water drive, influence the efficiency of CO₂ gas cap drive for both oil displacement and sequestration. Focusing on these main evaluation criteria, the study identifies that the suitability of CO₂ gas cap drive in reservoirs during the high water-cut phase is significantly influenced by factors such as reservoir confinement, formation dip angle, crude oil viscosity, permeability, and reservoir thickness. These findings aim to provide a foundation for broadening the application of CO₂ flooding techniques. crude oil viscosity, reservoir permeability, and thickness, to provide a basis for expanding the application range of CO₂ flooding.

Key words: high water content, CO₂ artificial gas cap, sensitivity factors, dip angle, hydrodynamic strength, gas storage rate

中图分类号:

TE32

王军,邱伟生. 高含水油藏CO₂人工气顶驱油-封存适宜条件研究[J]. 油气藏评价与开发, 2024, 14(1): 48-54.

WANG Jun,QIU Weisheng. Suitable conditions for CO₂ artificial gas cap flooding-sequestration in high water cut reservoir[J]. Petroleum Reservoir Evaluation and Development, 2024, 14(1): 48-54.

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序号	项目	表征参数	取值	方法
1	油藏倾角	地层倾角/（° ）	0、5、10、15、20、25、30	穷举法
2	封闭性	断层夹角/（° ）含油带宽度/m	60、90、120、180 100、200、300、400	穷举法
3	油层厚度	油层厚度/m	1、3、5、15、20、30	单因素分析
4	原油密度	原油密度/（g/cm³）	0.68、0.76、0.81、0.9	单因素分析
5	原油黏度	原油黏度/（mPa·s）	1、4、8、12、50	单因素分析
6	水动力强弱	边水水体倍数	0、1、2、3、4、20、100	单因素分析
7	压力保持水平	地层压力系数	0.6、0.8、1.0、1.2、1.4	单因素分析
8	剩余油饱和度	含油饱和度	0.3、0.4、0.5	单因素分析
9	渗透率	渗透率/（10^-3 μm²）	1、10、50、100、500、1 000	单因素分析
10	非均质性	韵律和级差	正韵律、反韵律（渗透率级差2、15、50）	单因素分析

敏感性评价	评价标准
不敏感	不同水平对应的阶段末采出程度最大值与最小值之差小于5%
次敏感	不同水平对应的阶段末采出程度最大值与最小值之差介于5%~10%
敏感	不同水平对应的阶段末采出程度最大值与最小值之差介于10%~20%
极敏感	不同水平对应的阶段末采出程度最大值与最小值之差大于20%

区块	原油密度/ （g/cm³）	原油黏度/（mPa·s）	油藏温度/ ℃	油层压力/MPa	渗透率/ （10^-3 μm²）	沉积韵律	主控断层夹角/（° ）	地层倾角/（° ）	含水/ %	气驱前采出程度/%
CZ	0.850	15.31	80.0	22.14	600.0	正韵律	60~80	10~15	98.0	35.3
XNZ	0.860	86.40	84.0	21.61	1 318.0	正韵律	160	5	94.8	34.5
BHZ	0.873	144.00	56.6	13.53	86.4	正韵律	150	2~3	83.8	11.0

区块	井距/ m	见效时间/d	气体突破时间/d	最高增油/ （t/d）	见效后最低含水/%	累积注气/ 10⁴ t	累计增油/ 10⁴ t	换油率/ （t/t）	备注
CZ	50~250	360	600	6.02	59.5	1.07	1.31	1.23	油水界面下移，顶部增加新井2口，增油8 700 t
XNZ	90~360	132	28	2.40	85.1	1.43	0.11	0.08
BHZ	200~300	230	120	3.30	75.9	0.84	0.10	0.12

高含水油藏CO₂人工气顶驱油-封存适宜条件研究

Suitable conditions for CO₂ artificial gas cap flooding-sequestration in high water cut reservoir

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