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Thermodynamics-Informed Neural Network (TINN) for Phase Equilibrium Calculations Considering Capillary Pressure

Tao Zhang, Shuyu Sun

2021Energies39 citationsDOIOpen Access PDF

Abstract

The thermodynamic properties of fluid mixtures play a crucial role in designing physically meaningful models and robust algorithms for simulating multi-component multi-phase flow in subsurface, which is needed for many subsurface applications. In this context, the equation-of-state-based flash calculation used to predict the equilibrium properties of each phase for a given fluid mixture going through phase splitting is a crucial component, and often a bottleneck, of multi-phase flow simulations. In this paper, a capillarity-wise Thermodynamics-Informed Neural Network is developed for the first time to propose a fast, accurate and robust approach calculating phase equilibrium properties for unconventional reservoirs. The trained model performs well in both phase stability tests and phase splitting calculations in a large range of reservoir conditions, which enables further multi-component multi-phase flow simulations with a strong thermodynamic basis.

Topics & Concepts

Flash evaporationComponent (thermodynamics)Context (archaeology)Phase (matter)Artificial neural networkThermodynamic equilibriumBottleneckEquation of stateComputer scienceThermodynamicsTwo-phase flowFlow (mathematics)Statistical physicsMechanicsChemistryPhysicsGeologyArtificial intelligenceOrganic chemistryPaleontologyEmbedded systemHydrocarbon exploration and reservoir analysisEnhanced Oil Recovery TechniquesReservoir Engineering and Simulation Methods
Thermodynamics-Informed Neural Network (TINN) for Phase Equilibrium Calculations Considering Capillary Pressure | Litcius