Performance of a horizontal well in a bounded anisotropic reservoir: Part II: Performance analysis of well length and reservoir geometry

IF 1.5 Q2 ENGINEERING, MULTIDISCIPLINARY

Open Engineering Pub Date : 2023-01-01 DOI:10.1515/eng-2022-0477

Timothy Kitungu Nzomo, S. Adewole, K. Awuor, Daniel Okang’a Oyoo

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Abstract

Abstract Evaluation of the performance of horizontal wells is an important aspect in the enhancement of their productivity. This study provides mathematical computations, and analysis for theoretical well and reservoir considerations. The study investigates how well design and reservoirs geometry affect the overall performance of a horizontal well in a completely bounded reservoir throughout its productive life. A horizontal well in a rectangular reservoir with completely sealed boundaries is considered and the effect of dimensionless well length L D \hspace{.25em}{L}_{\text{D}} , dimensionless reservoir length x eD \hspace{.25em}{x}_{\text{eD}} , and dimensionless reservoir width y eD {y}_{\text{eD}} on the pressure response over a given period of production using dimensionless time t D {t}_{\text{D}} is studied. The mathematical model used was derived using source and Green’s functions presented in part I of this study. Appropriate well and reservoir parameters are considered and the respective dimensionless parameters are computed which are then used in computing dimensionless pressure P D {P}_{\text{D}} and its dimensionless pressure derivative P D ′ \hspace{.25em}{P}_{\text{D}}^{^{\prime} } . From the computations, the results obtained are analysed in diagnostic log–log plots with a discussion of the flow periods. The results obtained indicate that an increase in dimensionless well length decreases pressure response during the infinite-acting flow at early times and during transition flows at middle time but increases the pressure response during the pseudosteady state flow at late times. The dimensionless reservoir width and length are observed not to influence dimensionless pressure response during the infinite-acting flow at early times and during the transition flows at middle time, only affecting the prevalence time of the flow periods. However it is observed that during the pseudosteady state flow at late times, dimensionless pressure response reduces with increased dimensionless reservoir length and width.

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有界各向异性油藏中水平井的性能：第二部分：井长和油藏几何形状的性能分析

水平井动态评价是提高水平井产能的一个重要方面。本研究为理论井和储层考虑因素提供了数学计算和分析。该研究调查了井设计和储层几何形状如何影响完全有界储层中水平井在其生产寿命内的整体性能。考虑了边界完全封闭的矩形油藏中的水平井，并考虑了无量纲井长L D \ hspace｛.25em｝的影响{L}_｛\text｛D｝｝，无量纲储层长度x eD\space｛.25em｝{x}_｛\text｛eD｝｝和无量纲储层宽度y eD{y}_｛\text｛eD｝｝在给定生产周期内使用无量纲时间t D的压力响应{t}_｛\text｛D｝｝进行了研究。所使用的数学模型是使用本研究第一部分中提出的source和Green函数推导的。考虑适当的井和储层参数，并计算相应的无量纲参数，然后将其用于计算无量纲压力PD{P}_｛\text｛D｝｝及其无量纲压力导数P D′\space｛.25em｝{P}_｛\text｛D｝｝^｛^｝\prime｝。通过计算，在诊断对数图中分析了获得的结果，并讨论了流量周期。结果表明，无量纲井长的增加降低了无限作用流早期和过渡流中期的压力响应，但增加了伪稳态流后期的压力响应。在早期的无限作用流和中期的过渡流期间，观察到无量纲储层宽度和长度不会影响无量纲压力响应，只影响流动期的盛行时间。然而，观察到，在后期的伪稳态流动过程中，无量纲压力响应随着无量纲储层长度和宽度的增加而减小。

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

Open Engineering ENGINEERING, MULTIDISCIPLINARY-

CiteScore

3.90

自引率

0.00%

发文量

审稿时长

30 weeks

期刊介绍： Open Engineering publishes research results of wide interest in emerging interdisciplinary and traditional engineering fields, including: electrical and computer engineering, civil and environmental engineering, mechanical and aerospace engineering, material science and engineering. The journal is designed to facilitate the exchange of innovative and interdisciplinary ideas between researchers from different countries. Open Engineering is a peer-reviewed, English language journal. Researchers from non-English speaking regions are provided with free language correction by scientists who are native speakers. Additionally, each published article is widely promoted to researchers working in the same field.