{"title":"应用人工智能,利用切削刃内传感数据和振动模式预测岩石强度和钻孔效率","authors":"Alexis Koulidis, Guang Ooi, Shehab Ahmed","doi":"10.1007/s13202-024-01823-6","DOIUrl":null,"url":null,"abstract":"<p>Drilling is a complex destructive action that induces vibrations due to the rock-bit interaction, which affects the overall drilling efficiency and wellbore quality. This study aims to enhance drilling efficiency by deploying artificial neural networks (ANNs) to integrate in-cutter force sensing and vibration data. Data is collected from experiments conducted with sharp cutters on rock samples of varying mechanical properties, measuring variables such as weight on bit, torque, rotational speed, in-cutter force, and vibration measurements. A scoring system is used to evaluate the drilling efficiency by coupling the mechanical specific energy and vibration modes. An ANN is trained with these variables to predict the rate of penetration and rock strength, which are also measured in the experiments to be used as ground truth. The reliability of the framework is demonstrated by testing the validity of the ANN model on samples with various mechanical properties. It introduces a reliable and swift method for determining optimal drilling parameters, supported by a sensitivity analysis to fine-tune the ANN and assess the influence of each parameter on performance. This study demonstrates that ANN could be successfully implemented to predict the rate of penetration and rock strength on a laboratory-scaled drilling rig. The results show that the ANN model accurately predicts training and testing datasets for scoring while drilling multiple layers with a correlation coefficient of 0.966. Integration of in-cutter sensing technology, vibration data, and ANN can be of significant interest and be used on field applications to provide a reliable and rapid decision about drilling efficiency.</p>","PeriodicalId":16723,"journal":{"name":"Journal of Petroleum Exploration and Production Technology","volume":"38 1","pages":""},"PeriodicalIF":2.4000,"publicationDate":"2024-05-30","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Application of artificial intelligence to predict rock strength and drilling efficiency using in-cutter sensing data and vibration modes\",\"authors\":\"Alexis Koulidis, Guang Ooi, Shehab Ahmed\",\"doi\":\"10.1007/s13202-024-01823-6\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p>Drilling is a complex destructive action that induces vibrations due to the rock-bit interaction, which affects the overall drilling efficiency and wellbore quality. 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引用次数: 0
摘要
钻井是一项复杂的破坏性工作,由于岩层与钻头之间的相互作用会产生振动,从而影响整体钻井效率和井筒质量。本研究旨在通过部署人工神经网络(ANN)来整合切削力传感和振动数据,从而提高钻井效率。数据收集自在不同机械性能的岩石样本上使用锋利刀具进行的实验,测量变量包括钻头重量、扭矩、转速、刀内力和振动测量值。通过耦合机械比能量和振动模式,使用评分系统来评估钻孔效率。利用这些变量对 ANN 进行训练,以预测穿透率和岩石强度。通过在具有不同机械性能的样本上测试 ANN 模型的有效性,证明了该框架的可靠性。它引入了一种可靠、快速的方法来确定最佳钻探参数,并辅以敏感性分析对 ANN 进行微调,评估每个参数对性能的影响。这项研究表明,在实验室规模的钻机上,可以成功地使用方差网络来预测贯入率和岩石强度。结果表明,ANN 模型能准确预测多层钻进时的得分训练数据集和测试数据集,相关系数为 0.966。切削刃内传感技术、振动数据和 ANN 的集成具有重要意义,可用于现场应用,为钻井效率提供可靠、快速的决策。
Application of artificial intelligence to predict rock strength and drilling efficiency using in-cutter sensing data and vibration modes
Drilling is a complex destructive action that induces vibrations due to the rock-bit interaction, which affects the overall drilling efficiency and wellbore quality. This study aims to enhance drilling efficiency by deploying artificial neural networks (ANNs) to integrate in-cutter force sensing and vibration data. Data is collected from experiments conducted with sharp cutters on rock samples of varying mechanical properties, measuring variables such as weight on bit, torque, rotational speed, in-cutter force, and vibration measurements. A scoring system is used to evaluate the drilling efficiency by coupling the mechanical specific energy and vibration modes. An ANN is trained with these variables to predict the rate of penetration and rock strength, which are also measured in the experiments to be used as ground truth. The reliability of the framework is demonstrated by testing the validity of the ANN model on samples with various mechanical properties. It introduces a reliable and swift method for determining optimal drilling parameters, supported by a sensitivity analysis to fine-tune the ANN and assess the influence of each parameter on performance. This study demonstrates that ANN could be successfully implemented to predict the rate of penetration and rock strength on a laboratory-scaled drilling rig. The results show that the ANN model accurately predicts training and testing datasets for scoring while drilling multiple layers with a correlation coefficient of 0.966. Integration of in-cutter sensing technology, vibration data, and ANN can be of significant interest and be used on field applications to provide a reliable and rapid decision about drilling efficiency.
期刊介绍:
The Journal of Petroleum Exploration and Production Technology is an international open access journal that publishes original and review articles as well as book reviews on leading edge studies in the field of petroleum engineering, petroleum geology and exploration geophysics and the implementation of related technologies to the development and management of oil and gas reservoirs from their discovery through their entire production cycle.
Focusing on:
Reservoir characterization and modeling
Unconventional oil and gas reservoirs
Geophysics: Acquisition and near surface
Geophysics Modeling and Imaging
Geophysics: Interpretation
Geophysics: Processing
Production Engineering
Formation Evaluation
Reservoir Management
Petroleum Geology
Enhanced Recovery
Geomechanics
Drilling
Completions
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