基于电阻率数据和进化优化算法的地质导向技术

IF 2.6 Q2 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS Applied Computing and Geosciences Pub Date : 2024-03-27 DOI:10.1016/j.acags.2024.100162
Maksimilian Pavlov , Georgy Peshkov , Klemens Katterbauer , Abdallah Alshehri
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引用次数: 0

摘要

目前,石油和天然气行业在解决水平钻井的地质导向问题方面面临着诸多挑战。为了优化碳氢化合物资源的开采,避免钻进含水层,行业专家经常利用实时测量来修改钻井轨迹。这种方法需要对地下的不确定性进行实时量化,从而通过更明智的洞察力来增强操作决策,但同时也增加了决策的复杂性。本文展示了一种基于实时地层评估数据和微分演化算法的轨迹修正决策方法。该方法使用体积电阻率测井数据和储层模型数据(如孔隙度)。所提供的方法通过目标函数的最大化对计划的油井轨迹提出修正建议。目标函数与计算出的碳氢化合物饱和度环境一起运行,作为虚拟顺序钻井过程中的决策系统。为了证明我们的方法的准确性和可靠性,我们将修正后的轨迹与在同一区域钻探的初步轨迹进行了模拟比较。此外,我们还进行了多次实验,调整微分进化算法的超参数,为案例研究选择最佳参数集,并将提出的微分进化算法与粒子群优化算法和模式搜索算法进行比较。实验结果表明,实时地层评估数据与微分进化算法相结合的效果优于钻井工程师提供的轨迹。与其他优化算法相比,差分进化算法表现出更强的性能。我们实施了一个完整的管道,从生成电阻率和孔隙度立方体,到使用阿奇方程估算石油饱和度,再到根据近井数据、角度约束和油井轨迹规划前设定的预定义超参数在该立方体中生成修正轨迹。我们在合成数据集和真实数据集上对所开发的方法进行了验证。与初步提供的水平井相比,我们的决策系统显示出更好的累积石油饱和度值。
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Geosteering based on resistivity data and evolutionary optimization algorithm

Currently, the oil and gas industry faces numerous challenges in addressing geosteering issues in horizontal drilling. To optimize the extraction of hydrocarbon resources and to avoid penetration in aquifers, industry experts frequently modify the drilling trajectory using real-time measurements. This approach involves quantifying subsurface uncertainties in real-time, enhancing operational decision-making with more informed insights but also adding to its complexity. This paper demonstrates an approach to decision making for trajectory correction based on real-time formation evaluation data and the differential evolution algorithm. The approach uses volumetric resistivity log data and data from reservoir models, such as porosity. The provided methodology suggests corrections for planned well trajectories by maximization of the objective function. The objective function operates with a calculated hydrocarbon saturation environment as the decision-making system in a virtual sequential drilling process. To demonstrate the accuracy and reliability of our approach, we compared the simulations of the corrected trajectory with the preliminary trajectory drilled in the same area. In addition, we conducted several experiments to tune the hyper-parameters of the differential evolution algorithm to select the optimal parameter set for our case study and compared proposed differential evolution algorithm with particle swarm optimization and pattern search algorithms. The results of our experiments showed that the real-time formation evaluation data combined with the differential evolution algorithm outperformed a trajectory provided by the drilling engineers. Differential evolution algorithm demonstrated strong performance compared to others optimization algorithms. We have implemented a complete pipeline from generating resistivity and porosity cubes, using the Archie equation to estimate oil saturation, and consequently generating a corrected trajectory in this cube based on near-well data, angle constraints and predefined hyper-parameters set prior to well trajectory planning. The methods developed were validated on synthetic and real datasets. Our decision-making system shows better cumulative oil saturation values than the preliminary provided horizontal well.

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来源期刊
Applied Computing and Geosciences
Applied Computing and Geosciences Computer Science-General Computer Science
CiteScore
5.50
自引率
0.00%
发文量
23
审稿时长
5 weeks
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