一种利用单相页岩气藏生产数据量化井间通信的简单方法

H. Hamdi, H. Behmanesh, C. Clarkson
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引用次数: 3

摘要

利用速率瞬态分析(RTA)技术可以量化水力裂缝/储层性质和原位流体,该技术适用于非常规油藏中完井的多裂缝水平井(MFHWs)的流速/压力。这些方法通常用于分析单井的生产数据,而不考虑与附近井的通信。然而,在实践中,从同一区块钻出的井之间可以有很强的水力通信。本研究旨在为分析单相页岩气藏中通信mfhw的生产数据提供理论基础。开发了一种简单实用的半分析方法,通过分析单井的在线生产数据,量化从同一区块钻探的井之间的通信。该方法以交通罐模型为基础,采用宏观物质平衡和准稳态演替的概念。利用高效的Adams-Bashforth-Moulton算法,生成并求解了一组非线性常微分方程(ODEs)。通过鲁棒数值仿真验证了所提方法的准确性。在第一个示例中,给出了MFHW井对,其中井通过具有不同通信强度的主水力裂缝进行通信。在随后的示例中,将该方法扩展到考虑三井和六井区块的葡萄酒架式完井的生产数据。所开发的模型具有足够的灵活性,可以考虑从具有不同裂缝/岩石性质的不同储层区块生产的异步井。对于所有的研究案例,半解析方法都能很好地再现数值模拟的结果。结果表明,在某些情况下,当新井开始生产时,现有井的产量可能会显著下降。产能损失的大小是井间通信强度的直接函数。新方法可以通过调整水力裂缝之间的传导系数来精确量化井间的通信强度,以匹配单井的生产数据。在这项研究中,提出了一种新的简单有效的半分析方法,可以用最少的计算时间同时分析从一个区块钻探的多口井的在线生产数据。该方法的主要优点是其可扩展性,可以很容易地将额外的井添加到系统中。
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A Simple Method for Quantifying Inter-Well Communication Using Production Data from Single-Phase Shale Gas Reservoirs
Hydraulic fracture/reservoir properties and fluid-in-place can be quantified by using rate-transient analysis (RTA) techniques applied to flow rates/pressures gathered from multi-fractured horizontal wells (MFHWs) completed in unconventional reservoirs. These methods are commonly developed for the analysis of production data from single wells without considering communication with nearby wells. However, in practice, wells drilled from the same pad can be in strong hydraulic communication with each other. This study aims to develop the theoretical basis for analyzing production data from communicating MFHWs completed in single-phase shale gas reservoirs. A simple and practical semi-analytical method is developed to quantify the communication between wells drilled from the same pad by analyzing online production data from the individual wells. This method is based on the communicating tanks model and employs the concepts of macroscopic material balance and the succession of pseudo-steady states. A set of nonlinear ordinary differential equations (ODEs) are generated and solved simultaneously using the efficient Adams-Bashforth-Moulton algorithm. The accuracy of the solutions is verified against robust numerical simulation. In the first example provided, a MFHW well-pair is presented where the wells are communicating through primary hydraulic fractures with different communication strengths. In the subsequent examples, the method is extended to consider production data from a three-well and a six-well pad with wine-rack-style completions. The developed model is flexible enough to account for asynchronous wells that are producing from distinct reservoir blocks with different fracture/rock properties. For all the studied cases, the semi-analytical method closely reproduces the results of fully numerical simulation. The results demonstrate that, in some cases, when new wells start to produce, the production rates of existing wells can drop significantly. The amount of productivity loss is a direct function of the communication strengths between the wells. The new method can accurately quantify the communication strength between wells through transmissibility multipliers between the hydraulic fractures that are adjusted to match individual well production data. In this study, a new simple and efficient semi-analytical method is presented that can be used to analyze online production data from multiple wells drilled from a pad simultaneously with minimal computation time. The main advantage of the developed method is its scalability, where additional wells can be added to the system very easily.
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