Gas Deviation Factor Calculation Made Easy and Accurate Using an IR 4.0 Tool

Nasser M. Al-Hajri, Akram R. Barghouti, Sulaiman T. Ureiga
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Abstract

Gas deviation factor (z-factor) and other gas reservoir fluid properties, such as formation volume factor, density, and viscosity, are normally obtained from Pressure-Volume-Temperature (PVT) experimental analysis. This process of reservoir fluid characterization usually requires collecting pressurized fluid samples from the wellbore to conduct the experimental work. The scope of this paper will provide an alternative methodology for obtaining the z-factor. An IR 4.0 tool that heavily utilizes software coding was developed. The advanced tool uses the novel apparent molecular weight profiling concept to achieve the paper objective timely and accurately. The developed tool calculates gas properties based on downhole gradient pressure and temperature data as inputs. The methodology is applicable to dry, wet or condensate gas wells. The gas equation of state is modified to solve numerically for the z-factor using the gradient survey pressure and temperature data. The numerical solution is obtained by applying an iterative computation scheme as described below:A gas apparent molecular weight value is initialized and then gas mixture specific gravity and pseudo-critical properties are calculated.Gas mixture pseudo-reduced properties are calculated from the measured pressure and temperature values at the reservoir depth.A first z-factor value is determined as a function of the pseudo-reduced gas properties.Gas pressure gradient is obtained at the reservoir depth from the survey and used to back-calculate a second z-factor value by applying the modified gas equation of state.Relative error between the two z factor values is then calculated and compared against a low predefined tolerance.The above steps are reiterated at different assumed gas apparent molecular weight values until the predefined tolerance is achieved. This numerical approach is computerized to perform the highest possible number of iterations and then select the z-factor value corresponding to the minimum error among all iterations. The proposed workflow has been applied on literature data with known reservoir gas properties, from PVT analysis, and showed an excellent prediction performance compared to laboratory analysis with less than 5% error.
使用IR 4.0工具轻松准确地计算气体偏差系数
气体偏差因子(z因子)和其他气藏流体性质,如地层体积因子、密度和粘度,通常是通过压力-体积-温度(PVT)实验分析获得的。储层流体表征过程通常需要从井筒中收集加压流体样品进行实验工作。本文的范围将为获得z因子提供另一种方法。开发了大量利用软件编码的IR 4.0工具。该工具采用新颖的表观分子量谱概念,及时准确地实现了论文目的。开发的工具根据井下梯度压力和温度数据作为输入计算气体特性。该方法适用于干气井、湿气井和凝析气井。对气体状态方程进行了修正,利用梯度测量压力和温度数据对z因子进行了数值求解。数值解采用以下迭代计算方法:初始化气体表观分子量值,计算混合气体比重和拟临界性质。根据储层深度处实测压力和温度值,计算出混合气体的拟还原性质。第一个z因子值被确定为伪还原气体性质的函数。通过测量获得储层深度处的气体压力梯度,并应用修正的气体状态方程反算第二个z因子值。然后计算两个z因子值之间的相对误差,并与较低的预定义公差进行比较。在不同的假定气体表观分子量值下重复上述步骤,直到达到预定义的公差。这种数值方法是计算机化的,以执行尽可能多的迭代次数,然后在所有迭代中选择与最小误差对应的z因子值。该工作流程已应用于已知储层气体性质的文献数据,通过PVT分析,与实验室分析相比,显示出出色的预测性能,误差小于5%。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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