Irreversible Port-Hamiltonian Formulations for 1-Dimensional fluid systems
This work provides a theoretical framework for modeling fluid systems with dissipation, which could be useful for researchers in control theory and thermodynamics, but it appears incremental as it builds on prior IPHS formulations.
The paper extends the Irreversible Port-Hamiltonian Systems (IPHS) framework to model non-isentropic fluids with viscous dissipation in Eulerian coordinates, showing that convective transport can be consistently included by modifying differential operators and ensuring thermodynamic laws are fulfilled.
The Irreversible Port-Hamiltonian Systems (IPHS) framework is extended to the modelling of non-isentropic fluids with viscous dissipation in the Eulerian description. Building on earlier IPHS formulations for diffusion-driven and non-convective distributed systems, it is shown that convective transport can be consistently encompassed by the framework by modifying the underlying differential operators. After revisiting the constitutive relations of non-isentropic fluids in both Eulerian and Lagrangian coordinates, it is demonstrate how these systems fit within an extended IPHS formulation. Furthermore, an extended parametrisation of the boundary port variables which ensures that the first and second laws of Thermodynamics are fulfilled allows to define a general class of boundary controlled IPHS.