模拟井下温度测井数据,优化井下生产监控

G. M. Hashmi, Farrukh Hamza, M. Azari
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摘要

油藏管理的最佳实践源于高效的油井作业。单口井的流体流动剖面会随着时间的推移而变化,有时是不可预测的;随着储层逐渐枯竭,油气性质发生变化,含水率开始增加。在常规井和非常规井的一次、二次和三次采油过程中,生产监控是优化油藏管理的关键。确定多个层的井下生产流剖面有助于控制压降压力,调节地面节流装置,并减少过量的产水。本文对井筒周围的传热和流体流动进行了严格的力学分析,以帮助确定广义的井筒流动剖面。该方法可以独立于井下旋转器数据计算多相速率,并且几乎完全基于温度测量。由于温度测量是可靠的和更普遍的,该方法提供了一个强大的技术,以确定流量的贡献在广泛的监测应用。该技术已被证明可以与其他测井数据一起使用,例如电容、流体密度和气含率工具,以传递生产过程中流体相的更精确信息。该方法提出了一种瞬态温度模型的应用,可以根据电缆下入过程中获得的温度数据计算流速。该方法包括一个分析井筒流体瞬态温度模型。温度计算取决于质量流量和流动时间;因此,采用一种反演技术,将给定时间内的测量温度与计算温度进行匹配,以估计流量。观察到该模型依赖于确定准确的地热梯度,特别是在早期时间流的情况下。根据完井力学计算了系统中的各种传热阻力。该方法还考虑了井筒中摩擦和压降对流体温度的影响。算例分析表明了暂态模型的实用性和价值。模型的瞬态特性也有利于多种应用。实时流量监测、层间贡献、套管后流、泄漏定量测定和完井完整性都是该方法的潜在应用。瞬态温度建模方法可以与生产测井旋转器一起使用,以校准模型,并提供永久的井下监测工具,以帮助避免昂贵的测井重做。该研究为常规生产测井测量的各种应用提供了基础,在海上油田等非常规技术难以应用且成本高昂的情况下尤其有用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Simulating Downhole Temperature Logging Data for Optimum Downhole Production Surveillance
Reservoir management best practices originate from efficient well operations. The fluid flow profile from individual wells can change over time, sometimes unpredictably; as the reservoirs become depleted, changes in hydrocarbon properties occur, and water cut begins to increase. During primary, secondary, and tertiary recovery from conventional and unconventional wells, production surveillance is pivotal for optimum reservoir management. Determining the downhole production flow profile from multiple zones helps to manage drawdown pressure, regulate surface choke settings, and mitigate excessive water production. This paper presents a rigorous mechanistic analysis of the heat transfer and fluid flow around the wellbore to aid in determining a generalized wellbore flow profile. The approach enables the calculation of multiphase rates independently of downhole spinner data and is based almost solely on temperature measurements. Because temperature measurements are reliable and more commonly available, the method provides a robust technique to determine flow contributions across a broad spectrum of surveillance applications. The technique is shown to work with other logs, such as capacitance, fluid density, and gas holdup tool, to relay more refined information about fluid phases during production. The methodology presents an application of transient-temperature modeling for computing flow rates from temperature data obtained during a wireline run. The approach includes an analytical wellbore fluid transient-temperature model. Temperature calculations depend on mass flow rate and flow duration; therefore, an inversion technique is applied to match the measured temperature and calculated temperature for a given time duration to estimate flow rate. The model is observed to depend on determining an accurate geothermal gradient, particularly in cases of early time flow. The various heat transfer resistances in the system are calculated based on the completion mechanics. The method also accounts for the effect of friction and pressure drop in the wellbore on fluid temperature. The case study included demonstrates the utility and value of the transient model. The transient nature of the model also facilitates multiple applications. Real-time flow rate monitoring, zonal contributions, flow behind casing, quantitative determination of leaks, and completion integrity are all potential applications of the proposed method. The transient-temperature modeling methodology can be used with production logging spinners to calibrate the model and provide a permanent downhole monitoring tool to help avoid costly logging reruns. The study provides a foundation for various applications arising from conventional production logging measurements and could be particularly useful in cases, such as offshore fields, where more evolved unconventional techniques can be difficult and costly to apply.
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