Application of Data Science and Machine Learning Algorithms for ROP Optimization in West Texas: Turning Data into Knowledge

C. Noshi
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引用次数: 8

Abstract

A high rate of penetration (ROP) is considered one of the most sought-after targets when drilling a well. While physics-based models determine the importance of drilling parameters, they fail to capture the extent or degree of influence of the interplay of the different dynamic drilling features. Parameters such as WOB, RPM, and flowrate, (Mechanical Specific Energy) MSE, bit run distance, gamma ray for each rock formation in West Texas were examined. Ensuring an adequate ROP while controlling the tool face orientation is quite challenging. Nevertheless, its helps follow the planned well trajectory and eliminates excessive doglegs that lead to wellbore deviations. Five different Machine Learning algorithms were implemented to optimize ROP and create a less tortuous borehole. The collected data was cleaned and preprocessed and used to structure and train Random Forest, Artificial Neural Networks, Support Vector Regression, Ridge Regression, and Gradient Boosting Machine and the appropriate hyperparameters were selected. A successful model was chosen based a minimized deviation from planned trajectory, minimized tortuosity, and maximized ROP. A MAE of 10% was achieved using Random Forest. The algorithms have demonstrated competence in the historical dataset, accordingly it will be further tested on blind data to serve as a real-time system for directional drilling optimization to enable a fully automated system.
数据科学和机器学习算法在西德克萨斯州ROP优化中的应用:将数据转化为知识
高机械钻速(ROP)被认为是钻井过程中最受欢迎的目标之一。虽然基于物理的模型确定了钻井参数的重要性,但它们无法捕捉到不同动态钻井特征相互作用的影响程度或程度。研究人员检查了西德克萨斯州每个岩层的钻压、转速、流量、机械比能(MSE)、钻头下入距离、伽马射线等参数。在控制工具面朝向的同时确保足够的ROP是相当具有挑战性的。然而,它有助于遵循计划的井眼轨迹,并消除过多的狗腿导致的井眼偏差。采用了五种不同的机器学习算法来优化机械钻速,减少井眼的弯曲。对收集到的数据进行清洗和预处理,用于构建和训练随机森林、人工神经网络、支持向量回归、脊回归和梯度增强机,并选择合适的超参数。根据最小的偏离计划轨迹、最小的弯曲度和最大的ROP选择成功的模型。随机森林的MAE为10%。该算法已经在历史数据集中证明了其能力,因此将在盲数据上进一步测试,作为定向钻井优化的实时系统,以实现全自动化系统。
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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