针对长期生产条件下表现出动态行为的内边界和支撑裂缝的半解析压力和速率瞬态分析模型

IF 6 1区 工程技术 Q2 ENERGY & FUELS
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引用次数: 0

摘要

最近的研究广泛报道了在长期生产条件下,内边界和支撑裂缝的动态行为造成的碳氢化合物产量损失。然而,尚未确定内边界和支撑裂缝变化的定量关系,也未将其纳入压力和速率瞬态分析的半解析模型中。这项工作的重点是描述内边界和支撑裂缝的变化,并从压力瞬态曲线中捕捉典型特征。建立了一个通用的半分析模型,以描述长期生产条件下内边界和支撑裂缝的动态行为。与压力相关的长度收缩系数可量化内界和支撑裂缝的长度变化,该模型对其进行了修改,并将其纳入多区半分析模型。通过拉普拉斯和实时空间的同步数值迭代和数值反演,压力和速率行为的瞬态解在几秒钟内就能确定。内边界和支撑裂缝在瞬态压力曲线上的动态行为分为五个时期:裂缝双线性流动(FR1)、动态 PFs 流动(FR2)、内区域线性流动(FR3)、动态内边界流动(FR4)和外区域主导线性流动(FR5)。对数-对数压力瞬态曲线捕捉到了 FR2 期间的早期驼峰和 FR4 期间的正向上移,反映了长期生产期间内边界和支撑裂缝的动态行为。随着内边界的快速收缩,压力导数曲线将提前向上。由于内部区域未挤压裂缝的闭合导致渗透率降低,从而使压力导数曲线的上升幅度增大。如果忽略未挤压裂缝闭合造成的内边界动态行为的渗透率损失,后期生产时期的流量将被高估。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A semi-analytical pressure and rate transient analysis model for inner boundary and propped fractures exhibiting dynamic behavior under long-term production conditions

The loss of hydrocarbon production caused by the dynamic behavior of the inner boundary and propped fractures under long-term production conditions has been widely reported in recent studies. However, the quantitative relationships for the variations of the inner boundary and propped fractures have not been determined and incorporated in the semi-analytical models for the pressure and rate transient analysis. This work focuses on describing the variations of the inner boundary and propped fractures and capturing the typical characteristics from the pressure transient curves.

A generalized semi-analytical model was developed to characterize the dynamic behavior of the inner boundary and propped fractures under long-term production conditions. The pressure-dependent length shrinkage coefficients, which quantify the length changes of the inner zone and propped fractures, are modified and incorporated into this multi-zone semi-analytical model. With simultaneous numerical iterations and numerical inversions in Laplace and real-time space, the transient solutions to pressure and rate behavior are determined in just a few seconds. The dynamic behavior of the inner boundary and propped fractures on transient pressure curves is divided into five periods: fracture bilinear flow (FR1), dynamic PFs flow (FR2), inner-area linear flow (FR3), dynamic inner boundary flow (FR4), and outer-area dominated linear flow (FR5). The early hump during FR2 period and a positive upward shift during FR4 period are captured on the log-log pressure transient curves, reflecting the dynamic behavior of the inner boundary and propped fractures during the long-term production period.

The transient pressure behavior will exhibit greater positive upward trend and the flow rate will be lower with the shrinkage of the inner boundary. The pressure derivative curve will be upward earlier as the inner boundary shrinks more rapidly. The lower permeability caused by the closure of un-propped fractures in the inner zone results in greater upward in pressure derivative curves. If the permeability loss for the dynamic behavior of the inner boundary caused by the closure of un-propped fractures is neglected, the flow rate will be overestimated in the later production period.

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来源期刊
Petroleum Science
Petroleum Science 地学-地球化学与地球物理
CiteScore
7.70
自引率
16.10%
发文量
311
审稿时长
63 days
期刊介绍: Petroleum Science is the only English journal in China on petroleum science and technology that is intended for professionals engaged in petroleum science research and technical applications all over the world, as well as the managerial personnel of oil companies. It covers petroleum geology, petroleum geophysics, petroleum engineering, petrochemistry & chemical engineering, petroleum mechanics, and economic management. It aims to introduce the latest results in oil industry research in China, promote cooperation in petroleum science research between China and the rest of the world, and build a bridge for scientific communication between China and the world.
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