Hydraulic diffusivity estimations for US shale gas reservoirs with Gaussian method: Implications for pore-scale diffusion processes in underground repositories

IF 4.9 2区工程技术 Q2 ENERGY & FUELS

Journal of Natural Gas Science and Engineering Pub Date : 2022-10-01 DOI:10.1016/j.jngse.2022.104682

Ruud Weijermars , Clement Afagwu

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引用次数: 14

Abstract

This paper first presents so-called unified Gaussian solutions for the spatial advance of diffusion transients triggered by a sudden change in pressure, molecular mass concentration and/or temperature. The mathematical description with a Gaussian solution for the pressure transient is similar to that for molecular diffusion and quantifies the diffusion of pressure into the reservoir space due to a change in molecular density initiated at the well intervention point. The resulting pressure gradients due to the pressure transient quantify, via Darcy's Law, the fluid-particle velocity resulting from that gradient everywhere in the reservoir. Also based on the Gaussian pressure transient, a Gaussian decline curve fitting formula is derived, uniquely scaled by the hydraulic diffusivity. The physics-based, Gaussian decline curve equation was utilized to match 30-year production data from 68 counties in four major US shale gas plays to compute their hydraulic diffusivities. The average hydraulic diffusivities of Marcellus, Haynesville-Bossier, Barnett and Utica shale are 7.43 × 10⁻⁹ m² s⁻¹, 7.9 × 10⁻⁹ m² s⁻¹, 12.3 × 10⁻⁹ m² s⁻¹, and 59.0 × 10⁻⁹ m² s⁻¹, respectively. The empirical history-matched estimates of the pressure-gradient-driven diffusion rates in shale are similar or faster than the shale diffusion-rates measured in the laboratory. It can be assumed that the empirical diffusion rate accounts for the integrated effects of Darcy and non-Darcy flow. Computation of the Gaussian Péclet number in gas plays confirms that the advective flux is much faster than the combined Fickean and non-Fickean mass transport rates. The implications for gas recovery from shale formations, and secure disposal of nuclear waste in the subsurface shale repositories (wellbores and cavities) are discussed. In particular, our field estimations being faster than the laboratory diffusion rates calls for caution because mass transport from leaking containers at disposal sites would diffuse several orders of magnitude faster than suggested by the slower laboratory rates.

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用高斯方法估算美国页岩气储层的水力扩散系数:对地下储层孔隙尺度扩散过程的影响

本文首先提出了所谓的统一高斯解，用于由压力、分子质量浓度和/或温度的突然变化触发的扩散瞬态的空间推进。压力瞬态的高斯解的数学描述与分子扩散的数学描述类似，并量化了由于油井干预点引发的分子密度变化而导致的压力向储层空间的扩散。通过达西定律，由压力瞬变产生的压力梯度可以量化储层中各处由该梯度产生的流体颗粒速度。同时，基于高斯压力瞬态，导出了一个高斯衰减曲线拟合公式，该公式以水力扩散系数为唯一标度。基于物理的高斯衰减曲线方程用于匹配美国四个主要页岩气区68个县30年的生产数据，以计算其水力扩散系数。Marcellus、Haynesville-Bossier、Barnett和Utica页岩的平均水力扩散系数分别为7.43 × 10−9 m2 s−1、7.9 × 10−9 m2 s−1、12.3 × 10−9 m2 s−1和59.0 × 10−9 m2 s−1。页岩中压力梯度驱动的扩散速率的经验历史估计值与实验室测量的页岩扩散速率相似或更快。可以认为，经验扩散速率考虑了达西流和非达西流的综合效应。对天然气储层的高斯passimclet数的计算证实，对流通量比Fickean和非Fickean质量输运率的总和要快得多。讨论了页岩气开采和地下页岩储存库(井眼和空腔)核废料安全处理的意义。特别是，我们的现场估计比实验室扩散速率快，这需要谨慎，因为处置地点泄漏容器的质量传输将比较慢的实验室速率所建议的扩散速度快几个数量级。

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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来源期刊

Journal of Natural Gas Science and Engineering ENERGY & FUELS-ENGINEERING, CHEMICAL

CiteScore

8.90

自引率

0.00%

发文量

388

审稿时长

3.6 months

期刊介绍： The objective of the Journal of Natural Gas Science & Engineering is to bridge the gap between the engineering and the science of natural gas by publishing explicitly written articles intelligible to scientists and engineers working in any field of natural gas science and engineering from the reservoir to the market. An attempt is made in all issues to balance the subject matter and to appeal to a broad readership. The Journal of Natural Gas Science & Engineering covers the fields of natural gas exploration, production, processing and transmission in its broadest possible sense. Topics include: origin and accumulation of natural gas; natural gas geochemistry; gas-reservoir engineering; well logging, testing and evaluation; mathematical modelling; enhanced gas recovery; thermodynamics and phase behaviour, gas-reservoir modelling and simulation; natural gas production engineering; primary and enhanced production from unconventional gas resources, subsurface issues related to coalbed methane, tight gas, shale gas, and hydrate production, formation evaluation; exploration methods, multiphase flow and flow assurance issues, novel processing (e.g., subsea) techniques, raw gas transmission methods, gas processing/LNG technologies, sales gas transmission and storage. The Journal of Natural Gas Science & Engineering will also focus on economical, environmental, management and safety issues related to natural gas production, processing and transportation.