Larsen & Skauge相渗滞后模型在高温高压CO2-水互驱实验中的适应性

油气藏评价与开发

Larsen & Skauge相渗滞后模型在高温高压CO2-水互驱实验中的适应性

王烁石, 纪强, 郭平, 刘煌, 温连辉, 徐锐锋, 汪周华, 张瑞旭

西南石油大学油气藏地质及开发工程全国重点实验室，四川成都 610500

发布日期:2025-03-13 出版日期:2025-03-13
基金资助:
国家自然青年基金“页岩油藏微乳液-CO2协同吞吐提高采收率机理研究”（52404044）

Applicability of larsen & skauge relative permeability hysteresis model in high-temperature and high-pressure water alternating CO2-experiments

WANG Shuoshi, JI Qiang, GUO Ping, LIU Huang, WEN Lianhui, XU Ruifeng, WANG Zhouhua, ZHANG Ruixu

State Key Laboratory of Oil and Gas Reservoir Geology and Exploitation, Southwest Petroleum University, Chengdu, Sichuan 610500, China

Online:2025-03-13 Published:2025-03-13

摘要/Abstract

摘要：

多孔介质中的相渗滞后效应经多年实验研究已经形成了较为统一的结论。由于相渗滞后效应的影响，气水交替过程中不同周期的相渗曲线形态、各束缚相饱和度等参数都受到饱和路径及饱和历史的影响变化。涉及多相渗流交变工况的石油工程应用不能忽略相渗滞后现象。现有CO2-水交替过程的数值模拟研究中对相渗滞后效应考虑不足，导致开发过程中CO2埋存量及油采收率等关键参数的数值模拟预测结果与实际情况存在偏差。因此，基于Larsen & Skauge三相相渗滞后模型，设计并开展了含油岩心高温高压条件下的多周期CO2-水互驱实验，系统分析了不同起始注入相在混相或非混相条件下气水交替过程中相渗曲线的变化；通过Larsen & Skauge三相相渗滞后模型进行了数值模拟岩心实验拟合，并对比了由实验测定的相渗滞后参数与拟合校正后滞后参数的拟合结果。结果表明，非混相实验中的滞后现象较混相实验更为显著。此外，岩心的初始饱和状态对气水交替驱替效果也有影响。由实验测得的滞后参数仅适用于初始拟合值，在不同工况的应用场景需要开展单独实验拟合。该研究结果可为评估CO2-水交替过程中的相渗滞后效应提供参考，揭示多周期气水交替驱替过程中的相渗曲线变化规律，提高油采收率和CO2埋存相渗滞后效应数值模拟研究的准确性。

关键词: 相渗滞后, CO2-气水交替, 高温高压, 数值模拟, Larsen & Skauge模型

Abstract:

The capillary hysteresis effect in porous media has been studied extensively over many years, leading to a relatively unified conclusion. Due to the influence of capillary hysteresis, the morphology of capillary pressure-saturation curves and various parameters such as the saturation of trapped phases during gas-water alternating injection cycles are influenced by the saturation path and history. In petroleum engineering applications involving multiphase flow under alternating conditions, the capillary hysteresis phenomenon cannot be ignored. Current numerical simulation studies of CO2-water alternating processes often fail to fully consider the hysteresis effect, resulting in discrepancies between simulated and actual values for key parameters such as CO2 storage and oil recovery rates during development. Therefore, based on the Larsen & Skauge three-phase hysteresis model, this study designed and conducted multi-cycle CO2-water miscible and immiscible flooding experiments under high-temperature and high-pressure conditions using oil-bearing cores. The changes in capillary pressure curves during gas-water alternating cycles, with different initial injection phases under both miscible and immiscible conditions, were systematically analyzed. Numerical simulations were performed by fitting core experimental results using the Larsen & Skauge three-phase hysteresis model, and the fitting results of the experimentally measured hysteresis parameters were compared with those obtained from the corrected hysteresis parameter fitting. The results show that hysteresis is more pronounced in immiscible experiments compared to miscible ones. Additionally, the core’s initial saturation state also influences the gas-water alternating displacement effect. The hysteresis parameters measured by experiments are only applicable as initial fitting values, and separate experimental fittings should be conducted for different operational conditions. The findings of this study provide a reference for evaluating the capillary hysteresis effect in CO2-water alternating processes, reveal the changes in capillary pressure curves during multi-cycle gas-water alternating displacement, and improve the accuracy of numerical simulation studies on oil recovery and CO2 storage in relation to capillary hysteresis effects.

Key words: capillary hysteresis, CO2-water alternating, high temperature and pressure, numerical simulation, Larsen & Skauge model

Applicability of larsen & skauge relative permeability hysteresis model in high-temperature and high-pressure water alternating CO2-experiments[J]. Petroleum Reservoir Evaluation and Development, 0, (): 1-12.

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