碳酸盐岩储气库多孔介质中多组分体系扩散规律研究

摘要/Abstract

摘要： 目前,国际地缘政治局势复杂多变,能源供应链面临诸多不确定性。储气库作为国家能源储备体系的重要组成部分,可有效地缓冲国际天然气市场价格波动与供应中断风险,保障民生和工业生产等领域稳定用气,成为守护国家能源安全的坚实屏障。对于储气库多组分、多周期注采的高效安全运行,准确掌握储气库中工作气与垫层气的混合气扩散流动规律至关重要。然而,现有的气体扩散实验多聚焦于页岩、煤和致密岩石,对碳酸盐岩中多组分气体扩散规律认识尚不清晰。该研究选用卧龙河气田石炭系黄龙组上统的碳酸盐岩岩样,通过核磁共振和高压压汞实验测定碳酸盐岩孔喉半径分布特征,开展了CH₄与CO₂、N₂、O₂多组分体系的扩散实验,并通过拟合结果对比分析优选了适用于多尺度碳酸盐岩储层的气体扩散系数数学模型。研究表明：碳酸盐岩岩样具有明显的多尺度孔隙分布特征。在相同温度和压力下,岩石孔隙度和渗透率越大,各组分气体的扩散系数越大,CH₄与CO₂的二元扩散系数高于N₂与CO₂的二元扩散系数。在多组分体系扩散中,O₂扩散系数最大,CH₄扩散系数次之,而N₂与CO₂扩散系数最小。O₂的存在影响了CH₄与N₂扩散系数对CO₂和N₂体积分数变化的响应。通过结合实验数据优选的气体扩散系数数学模型可推广应用于不同温度和压力条件下的扩散系数预测。研究成果可为储气库运行规律准确预测和运行制度合理设计提供实验和计算方法。

关键词: 碳酸盐岩, 扩散系数, 多组分, 扩散实验, 数学模型

Abstract: Energy supply chains face uncertainties due to complex international geopolitics. Gas storage, as a crucial component of the national energy reserve, buffers fluctuations in natural gas prices and mitigates supply disruptions, ensuring stable supply to residential and industrial sectors and safeguarding national energy security. For efficient and safe operation of gas storage under multi-component, multi-cycle injection-production operations, accurate understanding of the mixing and diffusion of working and cushion gases in the reservoir is essential. However, experimental studies on gas diffusion have largely focused on shale, coal, and tight formations, leaving the diffusion behavior of multi-component gases in carbonate reservoirs poorly understood. In this study, carbonate samples from the Upper Carboniferous Huanglong Formation (upper member) of the Wolonghe Gas Field were examined, and their pore size distribution was characterized by nuclear magnetic resonance and high-pressure mercury intrusion porosimetry. Diffusion experiments were conducted on gas mixtures containing CH₄ with CO₂, N₂, and O₂. Based on comparative analysis of the experimental data, an appropriate mathematical model for gas diffusion coefficients in multi-scale carbonate reservoirs was identified. The carbonate samples exhibit a pronounced multi-scale pore structure. Under identical temperature and pressure conditions, higher porosity and permeability correspond to larger diffusion coefficients for all gas species; moreover, the binary diffusion coefficient of the CH₄-CO₂ pair exceeds that of the N₂-CO₂ pair. In a multi-component system, O₂ exhibits the largest diffusion coefficient, followed by CH₄, while N₂ and CO₂ have the smallest; furthermore, the presence of O₂ affects the sensitivity of the CH₄ and N₂ diffusion coefficients to changes in the volumetric fractions of CO₂ and N₂. The calibrated diffusion coefficient model can be extended to predict diffusion coefficients under different temperature and pressure conditions. These findings provide experimental and computational methodologies for the accurate prediction of gas storage operations and the rational design of operational strategies.

Key words: Carbonate rock, Diffusion coefficient, Multi-component, Diffusion experiment, Mathematical model

中图分类号:

TE133

张芮菡,胡博,彭先, 等. 碳酸盐岩储气库多孔介质中多组分体系扩散规律研究[J]. 油气藏评价与开发, 2025, (): 2024086-.

ZHANG RUIHAN,HU BO,PENG XIAN, et al. Study on diffusion law of multi-component system in porous media of carbonate gas storage[J]. Petroleum Reservoir Evaluation and Development, 2025, (): 2024086-.

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