油藏型储气库周期注采渗流和库容特征物理模拟

doi:10.13809/j.cnki.cn32-1825/te.2025.06.021

摘要/Abstract

摘要：

油藏型储气库流体渗流涉及油气水三相，其库容空间不仅包含气置换液的孔隙空间，油气间还存在溶解与组分传质作用。为明确周期注采过程中油气水互驱相渗特征和储气空间的组成，基于油藏型储气库运行工况，开展了多轮次气水、油水、气油互驱相渗实验及多周期注采长岩心仿真物理模拟实验，分析了两相互驱渗流规律、周期注采气驱液效率及油气相态变化，研究了储气库周期注采渗流能力、驱油效率及库容空间的变化规律。实验结果表明：①多轮次两相互驱过程中，水相会降低气相、油相的渗流能力，不利于储气库建库扩容；②采用“地层压力下气驱到极限采收率+上下限压力循环注采”的建库模式进行长岩心建库物理模拟，模型最终驱油效率达65.11%，其中水驱采油20%，气驱采油37.51%，循环注采占7.6%。连续气驱阶段是主要提采阶段，循环注采阶段为建库形成阶段；③长岩心气驱液置换的孔隙体积是库容量的主要组成部分，占比超70%，残余油溶解气和残余油收缩孔隙体积占比不足30%。第14轮次注采气后，库容量和工作气量均趋于稳定，二者主要受含气饱和度影响。因此，建议在油藏型储气库建库中，不宜急于进行衰竭采气，应优先实施“提采”策略，再开展“建库”工作。保持地层压力气驱油，待达到极限采收率后，再进行循环注采建库，以充分提高油水采出程度，进而提升库容量和工作气量。

关键词: 油藏型储气库, 多轮次两相互驱, 渗流特征, 长岩心物理模拟, 库容量, 工作气量

Abstract:

The fluid seepage in oil reservoir-type gas storage involves three phases of oil, gas, and water. The storage capacity not only includes the pore space for gas displacement of liquid, but involves dissolution and component mass transfer between oil and gas. To elucidate the relative permeability characteristics of multiphase displacement among oil, gas, and water and the composition of the gas storage space during cyclic injection and production, multiple cycles of gas-water, oil-water, and gas-oil multiphase displacement and relative permeability experiments were conducted, along with long-core physical simulation experiments under multi-cycle injection and production, based on the operational parameters of reservoir-type gas storage. The seepage patterns of two-phase mutual displacement, gas displacing fluid efficiencies, and fluid saturation changes during cyclic injection and production, and the changes in oil and gas phase states were analyzed. Furthermore, the variations in seepage capacity, oil displacement efficiency, and storage space during cyclic injection and production were investigated. The experimental result showed that: (1) during the processes of multi-cycle two-phase mutual displacement, the water phase reduced the seepage capacity of the gas phase and oil phase, which was unfavorable for the construction and expansion of gas storage facilities. The gas-oil mutual displacement process reduced the residual oil saturation and increased the volume of mobile fluid, which was conducive to the construction and expansion of gas storage facilities. (2) The physical simulation of long-core reservoir construction was performed using the approach of “gas displacement to ultimate recovery under formation pressure + cyclic injection and production within upper and lower pressure limits”. The model’s final oil displacement efficiency reached 65.11%, with 20% from water displacement, 37.51% from gas displacement, and 7.6% from cyclic injection and production. The continuous gas displacement stage was the primary recovery enhancement stage, while the cyclic injection-production stage served as the reservoir construction stage. (3) The pore volume displaced by gas in long-core experiments constituted the main part of the storage capacity, accounting for more than 70%, while the pore volume of solution gas in residual oil and residual oil shrinkage accounted for less than 30%. The storage capacity and working gas volume tended to stabilize after the 14th injection-production cycle, primarily influenced by the gas saturation. Therefore, it is recommended that in the construction of reservoir-type gas storage, premature depletion-driven gas production should be avoided. Instead, a “recovery enhancement” strategy should be prioritized before “reservoir construction”. Reservoir pressure during gas-oil displacement should be maintained until the ultimate recovery efficiency is achieved, after which cyclic injection and production can be implemented to construct the reservoir. This can adequately increase oil and water recovery degree, thereby increasing the storage capacity and working gas volume.

Key words: reservoir-type gas storage, multi-cycle two-phase mutual displacement, seepage characteristics, long-core physical simulation, storage capacity, working gas volume

中图分类号:

TE341

张国辉,徐德月,李佳慧, 等. 油藏型储气库周期注采渗流和库容特征物理模拟[J]. 油气藏评价与开发, 2025, 15(6): 1139-1146.

ZHANG Guohui,XU Deyue,LI Jiahui, et al. Physical simulation of seepage and reservoir capacity characteristic during cyclic injection and production in reservoir-type gas storage[J]. Petroleum Reservoir Evaluation and Development, 2025, 15(6): 1139-1146.

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岩心号	直径/cm	长度/cm	孔隙度/%	气体渗透率/10^-3μm²	实验温度/℃	实验内容
7	2.5	5.37	29.82	891.64	87.5	气水相渗
10	2.5	5.40	29.22	583.73	87.5	气油相渗
2	2.5	4.58	29.48	763.13	87.5	油水相渗