A new semi-analytical flow model for multi-branch well testing in natural gas hydrates

IF 9 1区 地球科学 Q1 ENERGY & FUELS
Hongyang Chu, Jingxuan Zhang, Liwei Zhang, Tianbi Ma, Yubao Gao, W. J. Lee
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引用次数: 7

Abstract

: This paper presents a new semi-analytical solution and the related methodology to analyze the pressure behavior of multi-branch wells produced from natural gas hydrates. For constant bottom-hole pressure production, the transient flow solution is obtained by Laplace transforms. The interference among various branches is investigated using the superposition principle. A simplified form of the proposed model is validated using published analytical solutions. The complete flow profile can be divided into nine distinct regimes: wellbore storage and skin, vertical radial flow, linear flow, pseudo-radial flow, composite flow, dissociated flow, transitional flow, improvement flow and stress-sensitive flow. A well’s multi-branch structure governs the vertical radial and the linear flow regimes. In our model, a dynamic interface divides the natural gas hydrates deposit into dissociated and non-dissociated regions. Natural gas hydrates formation properties govern the composite-effect, dissociated, transitional, and improvement flow regimes. A dissociation coefficient governs the difference in flow resistance between dissociated and non-dissociated natural gas hydrates regions. The dissociated-zone radius affects the timing of these flow regimes. Conversion of natural gas hydrates to natural gas becomes instantaneous as the dissociation coefficient increases. The pressure derivative exhibits the same features as a homogeneous formation. The natural gas hydrates parameter values in the Shenhu area of the South China Sea cause the prominent dissociated flow regime to conceal the later transitional and improvement flow regimes. Due to the maximum practical well-test duration limitation, the first five flow regimes (through composite flow) are more likely to appear in practice than later flow regimes.
天然气水合物多分支试井的半解析流动模型
本文提出了一种分析天然气水合物多分支井压力特性的新的半解析解和相关方法。对于恒定井底压力生产,通过拉普拉斯变换获得瞬态流量解。利用叠加原理研究了不同支路之间的干扰。使用已发表的分析解决方案验证了所提出模型的简化形式。完整的流动可分为九种不同的状态:井筒储存和表皮、垂直径向流动、线性流动、伪径向流动、复合流动、离解流动、过渡流动、改善流动和应力敏感流动。井的多分支结构控制着垂直径向和线性流动状态。在我们的模型中,动态界面将天然气水合物矿床划分为离解区和非离解区。天然气水合物的形成特性决定了复合效应、离解、过渡和改善流动机制。离解系数决定了离解和未离解天然气水合物区域之间的流动阻力差异。游离区半径影响这些流动状态的时间。随着离解系数的增加,天然气水合物转化为天然气的过程变得瞬间。压力导数表现出与均质地层相同的特征。南海神湖地区天然气水合物参数值导致突出的离解流机制掩盖了后来的过渡和改善流机制。由于实际试井的最大持续时间限制,前五种流动方式(通过复合流动)比后一种流动方式更有可能出现在实践中。
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
Advances in Geo-Energy Research
Advances in Geo-Energy Research natural geo-energy (oil, gas, coal geothermal, and gas hydrate)-Geotechnical Engineering and Engineering Geology
CiteScore
12.30
自引率
8.50%
发文量
63
审稿时长
2~3 weeks
期刊介绍: Advances in Geo-Energy Research is an interdisciplinary and international periodical committed to fostering interaction and multidisciplinary collaboration among scientific communities worldwide, spanning both industry and academia. Our journal serves as a platform for researchers actively engaged in the diverse fields of geo-energy systems, providing an academic medium for the exchange of knowledge and ideas. Join us in advancing the frontiers of geo-energy research through collaboration and shared expertise.
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