Natural modes of the two-fluid model of two-phase flow

A physically based method to derive well-posed instances of the two-fluid momentum transport equations from first principles is presented. The basic tools used in this endeavor are the variational principles of field theory, namely, the Hamilton principle and the virtual power principle. The state of the two-fluid flow is represented by the superficial velocity and the drift flux, instead of the average velocities of each fluid. This generates the conservation equations of the two principal motion modes naturally: the global center-of-mass flow and the relative velocity between fluids. Well-posed equations can be obtained by modeling the storage and exchange of kinetic energy in fluctuations structures induced by the interaction between fluids, like wakes and vortexes. In this way, the equations can be regularized without losing in the process the kinetic instabilities responsible for flow-patterns formation and transition. A specific case of vertical air-water flow is analyzed showing the capability of the present model to predict the formation of the slug flow regime as a train of solitons.

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This article presents a physically based method to derive well-posed instances of the two-fluid momentum transport equations from first principles using the variational principles of field theory. By modeling the storage and exchange of kinetic energy in fluctuations structures induced by the interaction between fluids, clear equations can be obtained, allowing for regularization without losing the kinetic instabilities responsible for flow-patterns formation and transition. A specific case of vertical air-water flow is analyzed to demonstrate the model's ability to predict the formation of the slug flow regime as a train of solitons.