在气田开发的最后阶段提高生产井的效率

IF 2.8 Q2 MINING & MINERAL PROCESSING

Mining of Mineral Deposits Pub Date : 2022-06-30 DOI:10.33271/mining16.02.001

R.Ya. Kondrat, L. Matiishyn

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引用次数: 0

摘要

目的是提高油气田开发最后阶段剩余碳氢化合物的提取效率，同时优化生产井的操作条件。方法。斯伦贝谢公司的PipeSim软件包已被应用于在井底液体积聚的复杂条件下提高现有井储的效率。已经使用了一口假设井。调查结果。针对不同的水系数值（即50、100、150、200、250、300、350、400和450 l/th.m3），计算了生产井的基本操作参数。该研究有助于确定水系数的增加导致液体速率的增加和气体速率的降低。节点分析方法已用于识别以下情况：在450 l/th.m3的水平上，生产井停止流动。研究结果支持这样一种观点，即要在18 th.m3/day的水平上激活井效，就需要用50.3mm的管柱替换62.0管柱，或者将井口压力从10.16降低到9.88MPa，或者在1.9 th.m3/d的水平上开发气举注入。此外，研究结果还为该方法的实施提供了工程效率的证据。然而，应用的便利性取决于工业设施的加工极限以及无水和湿沉积区域之间的比率。独创性确定了相关性相关性，用于预测高含水井的运行指标。研究结果有助于根据不同类型的地质和工程限制，及时证实提高碳氢化合物产量的方法。实际意义。研究结果的实施将有助于优化活跃边水和底水流入生产池的生产井的操作，并分别提高其碳氢化合物的提取率。

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Improving the efficiency of production wells at the final stage of gas field development

Purpose is to improve the efficiency of extraction of remaining hydrocarbons within the oil and gas fields at the final stage of their development while optimizing operational conditions of the production wells. Methods. Software package PipeSim by Schlumberger has been applied to improve the efficiency of the current well stock under the conditions complicated by liquid accumulation within a bottomhole. A hypothetic well has been used. Findings. The basic operational parameters of a production well have been calculated for different values of water coefficient (i.e. 50; 100; 150; 200; 250; 300; 350; 400 and 450 l/th.m3). The research has helped identify that increase in the water coefficient results in the increased rate of liquid as well as decreased gas rate. A nodal analysis method has been applied to identify the following: at the level of 450 l/th.m3, a production well stops flowing. The results of the studies support the idea that to activate a well efficiency at the level of 18 th.m3/day, it is required either to replace 62.0 tubing string with 50.3 mm one or reduce wellhead pressure from 10.16 down to 9.88 MPa or develop gas lift injection at the level of 1.9 th.m3/day. In addition, the results give the evidence of engineering efficiency as for the method implementation. However, expediency of the application depends upon the processing limits of industrial facilities as well as upon the ratio between the water-free and wet deposit areas. Originality. The correlation dependencies have been determined to forecast operational indices of highly watered wells. The research results help substantiate promptly the methods intensifying hydrocarbon output depending upon different types of geological and engineering limitations. Practical implications. Implementation of the results will help optimize operation of production wells under active edge and bottom water inflow into the productive pools and increase their hydrocarbon extraction respectively.

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来源期刊

Mining of Mineral Deposits MINING & MINERAL PROCESSING-

CiteScore

5.20

自引率

15.80%

发文量