钻井边缘计算系统的自主粘度/密度传感系统

Miguel Gonzalez, Robert W. Adams, Tim Thiel, C. Gooneratne, A. Magana-Mora, Ali Safran, Faisal Ghamdi, C. Powell, Ed Hulse, J. Ramasamy, M. Deffenbaugh
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引用次数: 1

摘要

目前的泥浆监测实践受到限制,因为它们依赖于手动测量,如漏斗粘度计、重量秤或基本的现场流变仪。这些手工操作限制了可用数据的数量和质量,而这些数据对于确保最佳和安全的钻井作业至关重要。在这项研究中,我们介绍了一种新的基于机电音叉谐振器的自主泥浆粘度/密度系统。该系统被集成到边缘计算系统中,以改进数据收集和机器学习模型的部署。该系统在实际钻井作业中进行了测试。粘度/密度传感器是基于一个机电音叉谐振器。该传感器集成在一个潜水外壳中,用于罐内测量。开发了两种系统,用于同时测量流入(负鼠腹)和流出(吸坑)。来自两个系统的数据被无线广播到钻井平台的中央机房,由边缘计算系统进行实时显示和数据聚合,用于使用机器学习开发时间序列分析模型。在最初的现场测试中,来自单个传感器的数据以低于每秒一个样本的速率收集了几个小时。该测试允许对当前测量方法无法实现的泥浆稠度进行连续监测。这些数据表明,该仪器具有实时计算和显示钻井参数的潜力,并可以检测可能表明作业问题的流体异常,这将使该仪器能够用作早期预警系统和实时计算钻井参数。这里详细介绍的系统为实现钻井自动化提供了一个重要的组成部分。该仪器的坚固性和紧凑性使其能够安装在泥浆循环系统的不同位置,以生成大型数据集,这些数据集可以在边缘计算框架中使用现代分析算法进行处理。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Autonomous Viscosity/Density Sensing System for Drilling Edge-Computing System
Current mud monitoring practices are limited due to their reliance on manual measurements such as funnel viscometers, weight balances, or basic field rheometers. These manual practices impose restraints on the quantity and quality of the available data that are essential to ensure optimal and safe drilling operations. In this study, we introduce a new autonomous mud viscosity/density system based on an electromechanical tuning fork resonator. The system was integrated into an edge-computing system for improved data collection and deployment of machine learning models. The system was tested during a live drilling campaign. The viscosity/density sensor is based on an electromechanical tuning fork resonator. The sensor was integrated into a submergible housing for in-tank measurements. Two systems were developed for simultaneous measurements at inflow (possum belly) and outflow (suction pit). The data from the two systems were broadcast wirelessly to the central computer room at the rig for real-time display and data aggregation by the edge-computing system for the development of time-series analysis models using machine learning. During initial field testing, data from a single sensor were collected for various hours at a rate less than a sample per second. The test allowed for continuous monitoring of the mud consistency not accessible by current measurement practices. The data demonstrated the potential to perform real-time calculation and display of drilling parameters and to detect anomalies in the fluid that might be indicative of developing operational problems, which would enable the instrument to be used as an early-warning system and real-time calculation of drilling parameters. The system detailed here provides an essential building block to enable drilling automation. The robustness and compactness of the instrument allow it to be installed at various points in the mud circulation system for the generation of large data sets that can be processed using modern analytics algorithms in an edge-computing framework.
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