Journal of Energy Research and Reviews

With drilling operations continuing to venture into increasingly complex environments, particularly in deepwater and high-pressure, high-temperature (HPHT) settings, the demand for intelligent, real-time fluid management strategies continues to grow. Traditional rheological models often fail to capture the nonlinear and transient behaviours of drilling fluids under the dynamic downhole conditions encountered in these complex environments. This paper presents a conceptual framework for integrating machine learning (ML) into drilling fluid systems to facilitate predictive modelling and adaptive control. The proposed framework architecture combines real-time sensor data, feature engineering, supervised learning models, and decision support layers to forecast key fluid properties. These include viscosity, gel strength, and equivalent circulating density (ECD). Potential use case scenarios are discussed, including early barite sag detection, fluid loss prediction in fractured zones, and dynamic ECD optimisation. Implementation challenges related to data quality, model generalisation, system latency, and interpretability are explored, along with future research directions. By bridging data-driven modelling with operational decision-making, this work lays the foundation for the development of intelligent, self-optimising fluid systems in next-generation drilling environments.