海上L低渗油藏CO2混相驱微观动用特征实验研究

doi:10.13809/j.cnki.cn32-1825/te.2025.04.007

摘要/Abstract

摘要：

渤海L低渗油藏储层整体表现出中孔、低渗的特点且油藏流体低密度、低黏度，在开发前期已经进行水驱补能，亟须探索不同开发方式的可行性研究，为后续合理开发提供参考依据。但该油藏不同驱替方式微观动用特征、机制以及影响因素尚不明确。以渤海L低渗油藏为研究对象，选取储层内部2块代表性砂岩岩心，运用在线核磁驱替技术，开展岩心CO₂混相驱油和水驱转CO₂混相驱油室内实验测试，在驱替过程中对岩心进行实时扫描，明确不同驱替方式微观动用特征差异及影响因素。结果表明：在相同驱替条件下驱替2.0 PV流体后，高渗岩心a（33.80×10^-3μm²）和低渗岩心b（2.95×10^-3μm²）CO₂混相驱（最终驱替效率分别为69.31%，66.18%）相比水驱转CO₂混相驱（驱替效率分别为58.07%，56.97%）效果更佳；高渗岩心相比于低渗岩心大孔占比更多，孔隙连通性强，CO₂混相驱油以及水驱转CO₂混相驱油的驱替效率分别提高3.13%和1.10%，表明物性对驱替效率影响较小；高渗岩心和低渗岩心水驱时孔喉动用下限分别为0.019 7 μm和0.009 8 μm，渗透率低使得压差较大，故孔喉动用下限更低；当水驱转CO₂混相驱后，油、气、水三相渗流，增大了实验压差，此时孔喉动用下限分别降低至0.008 μm和0.004 9 μm，与一直使用CO₂混相驱2块岩心孔喉动用下限（0.006 9 μm、0.005 2 μm）接近；推荐CO₂混相驱为L油藏后期合理开发方式。

关键词: 在线核磁, CO₂驱, 水驱转CO₂驱, 砂岩油藏, 驱替效率

Abstract:

The L low permeability reservoir in Bohai Sea is characterized by medium porosity and low permeability, with reservoir fluids exhibiting low density and low viscosity. Water flooding has been implemented in the early stage to supplement energy. It is therefore urgent to explore the feasibility of different development methods to provide a basis for subsequent rational development. However, the microscopic operation characteristics, mechanisms, and influencing factors of different displacement methods in this reservoir remain unclear. Taking the L low permeability reservoir in Bohai Sea as the research object, two representative sandstone cores from the reservoir were selected. Using online nuclear magnetic resonance displacement technology, indoor experiments were conducted on core samples using CO₂ miscible flooding and water flooding to CO₂ miscible flooding. Real-time scanning of the cores was carried out during the displacement process to identify the differences in microscopic operation characteristics and influencing factors among the different displacement methods. The results showed that under the same displacement conditions with 2.0 PV of injected fluid, CO₂ miscible flooding achieved higher final displacement efficiencies in both the high-permeability core a (33.80×10^-3 μm², 69.31%) and low-permeability core b (2.95×10^-3 μm², 66.18%), compared with those of water flooding to CO₂ miscible flooding (58.07% and 56.97%, respectively). Compared to the low-permeability cores, the high-permeability core had a higher proportion of large pores and better pore connectivity. The displacement efficiency increased by 3.13% and 1.10% for CO₂ miscible flooding and water flooding to CO₂ miscible flooding, respectively, indicating that physical properties had a limited effect on displacement efficiency. During water flooding, the lower pore-throat operation limits were 0.019 7 μm and 0.009 8 μm for the high-permeability and low-permeability cores, respectively. Lower permeability led to higher pressure differentials, resulting in lower pore-throat operation limits. When water flooding was switched to CO₂ miscible flooding, three-phase flow of oil, gas, and water occurred, further increasing the experimental pressure differential and reducing the lower limits of pore throat operation to 0.008 μm and 0.004 9 μm, respectively, which were close to the lower pore-throat operation limits (0.006 9 μm and 0.005 2 μm) of the two cores that had been using CO₂ miscible flooding. CO₂ miscible flooding is recommended as an optimal development method for the later stage of the L reservoir.

Key words: online nuclear magnetic resonance, CO₂ flooding, water flooding to CO₂ flooding, sandstone reservoir, displacement efficiency

中图分类号:

TE341

何洋,汪周华,郑祖号, 等. 海上L低渗油藏CO₂混相驱微观动用特征实验研究[J]. 油气藏评价与开发, 2025, 15(4): 589-596.

HE Yang,WANG Zhouhua,ZHENG Zuhao, et al. Experimental study on microscopic operation characteristics of CO₂ miscible flooding in offshore L low permeability reservoirs[J]. Petroleum Reservoir Evaluation and Development, 2025, 15(4): 589-596.

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名称	目标组分/%	配制组分/%	名称	目标组分/%	配制组分/%
CO₂	0.77	0.75	nC₅	1.48	1.63
N₂	0.93	0.96	C₆	4.38	4.52
C₁	25.17	25.45	C₇	4.40	4.51
C₂	3.67	3.86	C₈	4.42	4.46
C₃	4.57	4.75	C₉	4.81	4.35
iC₄	1.19	1.42	C₁₀	4.22	4.31
nC₄	2.76	2.51	C₁₁₊	35.98	35.24
iC₅	1.25	1.28	总计	100.00	100.00

方案	岩心编号	长度/cm	直径/cm	渗透率/10^-3μm²	孔隙度/%	注气设计	注入阶段	实验温度/℃	实验压力/MPa	设计流速/ （mL/min）
1	a	6.09	2.494	33.80	20.0	CO₂混相驱	CO₂驱2.0 PV	122.5	40	0.1
2	b	7.38	2.535	2.95	21.9	CO₂混相驱	CO₂驱2.0 PV	122.5	40	0.1
3	a	6.09	2.494	33.80	20.0	水驱转CO₂混相驱	水驱1.0 PV后转CO₂驱1.0 PV	122.5	40	0.1
4	b	7.38	2.535	2.95	21.9	水驱转CO₂混相驱	水驱1.0 PV后转CO₂驱1.0 PV	122.5	40	0.1

海上L低渗油藏CO₂混相驱微观动用特征实验研究

Experimental study on microscopic operation characteristics of CO₂ miscible flooding in offshore L low permeability reservoirs

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