Digital twin technology for wellbore and intelligent decision-making in drilling operations: Current status and future prospects

doi:10.3969/j.issn.2096-1693.2026.01.002

Abstract

Abstract:

This paper systematically reviews the current technical framework and implementation approaches for drilling digital twin modeling, focusing on key challenges such as multi-source heterogeneous data fusion during wellbore drilling operations, the coupling of physics-based and data-driven models, and intelligent decision feedback mechanisms. First, targeting the objects and levels of drilling data fusion, the fusion mechanisms for multi-temporal and multi-spatial scale data and conflict resolution methods were explored. Second, a comprehensive digital twin architecture suitable for drilling operating conditions was established, and methods for implementing joint physics-based and data-driven modeling were summarized. Then, diagnostic methods for drilling anomaly data features were proposed, enabling the establishment of multi-perspective decision feedback mechanisms between the physical and digital entities. Finally, the application potential of wellbore digital twin technology was prospected in the areas of high spatiotemporal resolution cognition, edge deployment, and model credibility assurance. The research results can provide theoretical support and methodological guidance for achieving drilling state recognition and efficient control under complex operating conditions.

Key words: oil and gas, wellbore digital twin, multi-source data fusion, intelligent decision-making, data-physics driven

摘要：

本文围绕井眼钻井过程中的多源异构数据融合、物理与数据驱动模型耦合以及智能决策反馈等关键问题，系统梳理了当前钻井数字孪生建模的技术框架与实现路径。首先，针对钻井数据融合对象与层次，探讨了多时空尺度数据的融合机制和冲突处理方法。其次，构建了一个适用于钻井工况的数字孪生总体架构，总结了实现机理与数据的联合驱动建模的方法。然后，提出了钻井异常数据特征诊断方法，并以此建立实体与数字体间的多视角决策反馈方法。最后，展望了井眼数字孪生技术在高时空分辨率认知、边端部署、模型可信性保障等方面的应用潜力。研究结果可为实现复杂工况下的钻井状态识别与高效控制提供理论支撑与方法指导。

关键词: 油气, 井眼数字孪生, 多源数据融合, 智能决策, 数据－机理驱动

CLC Number:

TE21
TP183

ZHANG Feifei, ZHANG Cong, WANG Xi, LOU Wenqiang, YU Yibing, WANG Xueying, YU Mengjiao. Digital twin technology for wellbore and intelligent decision-making in drilling operations: Current status and future prospects[J]. Petroleum Science Bulletin, 2026, 11(1): 191-208.

张菲菲, 张聪, 王茜, 娄文强, 余义兵, 王学迎, 于梦蛟. 井眼数字孪生与钻井智能决策技术及展望[J]. 石油科学通报, 2026, 11(1): 191-208.

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URL: https://sykxtb.cup.edu.cn/EN/10.3969/j.issn.2096-1693.2026.01.002

https://sykxtb.cup.edu.cn/EN/Y2026/V11/I1/191

Figures/Tables 20

References 62

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融合尺度	场景案例	数据特点	融合方法	效果说明
空间尺度	井底切削图像+钻头WOB/TOB/ROP/振动数据	微观图像+中尺度力学数据	特征融合	分析钻头磨损状态、识别岩性突变
空间尺度	井眼轨迹+地质建模数据	中尺度轨迹数据+宏观地层模型	模型+决策融合	实时调整钻井路径，避免钻出靶层
时间尺度	毫秒级振动数据+分钟级钻井参数	高频+低频	信号融合	捕捉异常工况如涡动、黏滑、卡钻等
时间尺度	日志级设备运行数据+周期性完井数据	小时+月年周期	决策融合	优化钻完井施工方案、评估设备健康周期

融合尺度	场景案例	数据特点	融合方法	效果说明
空间尺度	井底切削图像+钻头WOB/TOB/ROP/振动数据	微观图像+中尺度力学数据	特征融合	分析钻头磨损状态、识别岩性突变
空间尺度	井眼轨迹+地质建模数据	中尺度轨迹数据+宏观地层模型	模型+决策融合	实时调整钻井路径，避免钻出靶层
时间尺度	毫秒级振动数据+分钟级钻井参数	高频+低频	信号融合	捕捉异常工况如涡动、黏滑、卡钻等
时间尺度	日志级设备运行数据+周期性完井数据	小时+月年周期	决策融合	优化钻完井施工方案、评估设备健康周期

方法类别	典型算法或技术	应用场景	技术特点
卡尔曼滤波/ 贝叶斯融合	UKF / Deep Kalman Filter	高频传感器状态估计与连续融合	多传感器姿态融合、井底压力估计准确性显著提高
加权平均/逆方差加权	贝叶斯权重分配方法	简单数值型参数融合	快速决策、易实现、便于解释
工程规则裁剪与插值	限值筛查、稳态窗口漏洞检查、时间插值	异常剔除、时间序列对齐	工程实践中常用，实时性好
集成学习融合	Stacking 模型(RF+SVM+KNN+ 决策树，XGBoost meta)	钻井工况分类与异常检测	多模型融合提高稳定性与泛化能力，解释性较好

方法类别	典型算法或技术	应用场景	技术特点
卡尔曼滤波/ 贝叶斯融合	UKF / Deep Kalman Filter	高频传感器状态估计与连续融合	多传感器姿态融合、井底压力估计准确性显著提高
加权平均/逆方差加权	贝叶斯权重分配方法	简单数值型参数融合	快速决策、易实现、便于解释
工程规则裁剪与插值	限值筛查、稳态窗口漏洞检查、时间插值	异常剔除、时间序列对齐	工程实践中常用，实时性好
集成学习融合	Stacking 模型(RF+SVM+KNN+ 决策树，XGBoost meta)	钻井工况分类与异常检测	多模型融合提高稳定性与泛化能力，解释性较好

方法类别	典型算法或技术	应用场景	技术特点
参数拟合	物残差建模 + ML	机械钻速预测	保留可解释性、提升预测精度
参数拟合	物理信息机器学习(PIML)	摩擦预测、物理机制解释	高物理一致性、解释性强、鲁棒性好
知识嵌入	物理信息神经网络(PINN)	井眼传热模型	耦合偏微分方程，物理约束强
知识嵌入	理论指导神经网络	井筒多相流模型	提升计算速度，适应井控状态评估
模型融合	串行耦合：机理模型+残差修正	井下工具故障预测	物理框架提供趋势，数据模型修正误差
	并联耦合：加权/切换融合	钻井参数优化	贝叶斯平均降低方差，适用高噪声环境
	嵌入耦合：物理约束损失函数	井壁稳定性评估	多场耦合功能，真实模拟地层环境

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