Abstract
Real-time monitoring of multiphase fluid flows with distributed fibre optic sensing has the potential to play a major role in industrial flow measurement applications. One such application is the optimization of hydrocarbon production to maximize short-term income, and prolong the operational lifetime of production wells and the reservoir. While the measurement technology itself is well understood and developed, a key remaining challenge is the establishment of robust data analysis tools that are capable of providing real-time conversion of enormous data quantities into actionable process indicators. This paper provides a comprehensive technical review of the data analysis techniques for distributed fibre optic technologies, with a particular focus on characterizing fluid flow in pipes. The review encompasses classical methods, such as the speed of sound estimation and Joule-Thomson coefficient, as well as their data-driven machine learning counterparts, such as Convolutional Neural Network (CNN), Support Vector Machine (SVM), and Ensemble Kalman Filter (EnKF) algorithms. The study aims to help end-users establish reliable, robust, and accurate solutions that can be deployed in a timely and effective way, and pave the wave for future developments in the field.
Highlights
Increasing field recovery is essential in the oil and gas industry
We provide a structured and comprehensive review of the recent advances in the multiphase fluid flow estimation based on the distributed fibre optic sensor technologies
This paper focuses on providing a comprehensive review of the last approach, using distributed sensors with physical flow modelling and machine learning algorithms for multiphase flow estimation
Summary
Increasing field recovery is essential in the oil and gas industry. Equinor, a Norwegian state-owned energy company, estimates an untapped potential of around four billion barrels of oil from a 10% increase of oil recovery on the Norwegian Continental Shelf (NCS) alone [1]. A typical starting point for production optimization is through continuous monitoring of the downhole production well variables (e.g., Water in Liquid Ratio (WLR), Gas Volume Fraction (GVF), fluid flow rate, water or gas breakthrough, and sand production). These measurements are combined with simulations in order to optimize production control parameters (e.g., Inflow Control Valve (ICV) and/or Inflow Control Device (ICD) parameters, pressure setting, and controlling water/gas injection) for stimulating production [5]. It is crucial to have robust, reliable, and accurate monitoring capabilities to achieve the most optimized oil production system
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