A Numerical Investigation into the Effect of Controllable Parameters on the Natural Gas Storage in a Weak Reservoir-type Aquifer

A. Jafari, Peyman Sadirli, Reza Gharibshahi, E. K. Tooseh, Masoud Samivand, A. Teymouri
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引用次数: 1

Abstract

Natural gas storage process in aquifer, due to fluid flow behavior of gas and water in the porous medium and because of their contact with each other under reservoir conditions, faces several challenges. Therefore, there should be a clear understanding of the injected gas behavior before and after the injection into the reservoir. This research simulates the natural gas storage in aquifer by using Eclipse 300 software. For this purpose, a core sample was considered as the porous medium for gas injection, and a composition of natural gas was injected into the core in different conditions. Moreover, by using Plackett-Burman method, all of the factors affected in this process were screened, and finally four main significant parameters, including the flow rate of injected gas, permeability, pressure, and irreducible water saturation were selected for designing a design of experiments (DOE) plan. Response surface method (RSM) is one of the best methods of experimental design used for optimizing the process and finding the best combination of parameters to have a high stored gas volume and a high recovered gas volume. The simulation includes 28 runs with four considered parameters, and the output is the recovered gas, which in turn is vital for the process accomplishment. Sensitivity analysis and grid independency test were checked. To this end, three grids with different number of cells in x-direction were generated, and by analyzing the results of gas saturation in the porous medium for each model, a grid with 11250 cells (50 elements in x-direction and 15 elements in y- and z-directions) was then chosen as the main grid. Uncertainty analysis and the validation of numerical simulations were carried out, and good agreement was observed between the numerical results and experimental data. In addition, the numerical results showed that the flow rate of the injected gas had a significant impact on the process in comparison with other parameters. Furthermore, increasing permeability and decreasing pressure and irreducible water saturation raise the amount of trapped gas in aquifers. Therefore, for having the maximum stored gas volume and a high recovered gas volume, the best combination of parameters is a high gas injection flow rate (0.9 cc/min), high permeability (1.54 md), a low pressure (2254 psi), and irreducible water saturation. (0.46). Finally, in a natural gas storage operation in an aquifer, both rock properties and operational parameters play important roles, and they should be optimized in order to have the highest amount of stored gas.
弱储集型含水层可控参数对天然气储层影响的数值研究
由于气水在多孔介质中的流动特性和储层条件下的相互接触,含水层天然气的储气过程面临着诸多挑战。因此,对注入储层前后的注气行为要有一个清晰的认识。利用Eclipse 300软件对含水层天然气储层进行模拟。为此,将岩心样品作为注气的多孔介质,在不同条件下向岩心注入一种天然气成分。利用Plackett-Burman方法对影响这一过程的所有因素进行筛选,最终筛选出注气量、渗透率、压力、不可还原含水饱和度4个主要重要参数,设计实验设计(DOE)方案。响应面法(RSM)是一种最佳的实验设计方法,用于优化工艺流程,寻找最佳的参数组合,以获得高储气量和高采收率。模拟包括28次运行,考虑了四个参数,输出是回收的气体,这对过程的完成至关重要。进行敏感性分析和网格独立性检验。为此,在x方向上生成了3个不同单元格数的网格,通过分析每个模型的孔隙介质中气体饱和度结果,选择一个单元格数为11250的网格(x方向50个单元,y和z方向15个单元)作为主网格。对数值模拟进行了不确定度分析和验证,数值结果与实验数据吻合较好。此外,数值计算结果表明,与其他参数相比,注入气体的流量对过程有显著影响。此外,渗透率的增加和压力的降低以及含水饱和度的不降低也增加了含水层中被困气体的数量。因此,为了获得最大的储气量和高采收率,最佳参数组合是高注气量(0.9 cc/min)、高渗透率(1.54 md)、低压(2254 psi)和不可降低的含水饱和度。(0.46)。最后,在含水层天然气储气作业中,岩石性质和作业参数都起着重要的作用,为了获得最大的储气量,必须对其进行优化。
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