注入水水质对SN-1井区油藏采收率影响研究

doi:10.13809/j.cnki.cn32-1825/te.2020.06.016

Abstract

Abstract:

In order to solve the problems in Wellblock-SN-1 in Junggar Basin such as high water cut in oil wells, poor water injection effect in some wells, and decline in permeability of oil and water wells after water injection with wastewater and other issues, the influencing factors of water flooding recovery of reservoir have been studied. By the water injection optimization numerical simulations and experiments such as damage by the injection water to core, core flooding and injection water quality indicator analysis, the formation damage by injection water have been studied from microscopic scale, core scale and macroscopic scale respectively, and the damage mechanism leading to the decrease of permeability in production and injection wells has been revealed. It is recognized that the formation damage caused by solid blockage in injection water is the main controlling factor leading to low oil recovery. It is found that the solid blockage not only affects the microscopic flooding effect, but also increases the mobility ratio and reduces the sweep efficiency. Therefore, the water quality of the re-injection of the reservoir in Wellblock-SN-1 is the main factor for the poor water injection efficiency. The suspended solid mass concentration should be treated as the primary water quality control index. The proposed multi-scale evaluation method improves the reliability of the results, and is helpful for improving the exploitation effect of oilfield water flooding. It can provide technical reserves for stable oilfield exploitation.

Key words: Junggar Basin, formation damage, core experiment, water quality, multi-scale evaluation, oil recovery

CLC Number:

TE341

Zhaozhong YANG,Yang LI,Zheng RAO, et al. Impact of injected water quality on oil recovery ratio of reservoir in Wellblock-SN-1[J]. Reservoir Evaluation and Development, 2020, 10(6): 103-109.

Figures/Tables 12

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References 22

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检测项目	控制指标	取样地点水样检测结果
检测项目	控制指标	SNXX井口水	石西集中处理站
注入水矿化度/（mg·L^-1）	≥10 000或等于注入层的地层水矿化度	18 449.1	22 961.1
悬浮固体含量/（mg·L^-1）	≤4.0	9.76	4.87
悬浮物固体直径/μm	≤5.0	8.036	0.190
含油量/（mg·L^-1）	≤10.0	0	0
平均腐蚀率/（mm·a^-1）	≤0.076	0.033	0.016
硫酸盐还原菌/（个·mL^-1）	≤25	250	60
铁细菌/（个·mL^-1）	≤n×10³（1<n<10）	2.5×10⁵	2.5×10³
腐生菌/（个·mL^-1）	≤n×10³（1<n<10）	2.5×10⁵	2.5×10³

水质	残余油饱和度/%	原始含油饱和度/%	驱油效率	水驱采收率/%
清水	18.20	60.66	0.70	51.91
井口水	24.29	61.46	0.60	49.09

水质	残余油饱和度	原始含油饱和度	驱油效率	水驱采收率
清水	19.72	62.52	68.46	53.31
井口水	20.56	61.18	66.40	51.14

层段	采收率历史值/%	采收率拟合值/%	传递因子（T）
砂岩层	33.1	33.3	0.6
砾岩层	29.7	29.6	0.1

层段	水质类型	传递因子（T）
砂岩层	清水	0.80
砂岩层	井口水	0.40
砾岩层	清水	0.30
砾岩层	井口水	0.08

Impact of injected water quality on oil recovery ratio of reservoir in Wellblock-SN-1

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