Abstract
The objective of this work is to investigate linear modal and algebraic instability in Poiseuille flows with fluids close to their vapour–liquid critical point. Close to this critical point, the ideal gas assumption does not hold and large non-ideal fluid behaviours occur. As a representative non-ideal fluid, we consider supercritical carbon dioxide ($\text{CO}_{2}$) at a pressure of 80 bar, which is above its critical pressure of 73.9 bar. The Poiseuille flow is characterized by the Reynolds number ($Re=\unicode[STIX]{x1D70C}_{w}^{\ast }u_{r}^{\ast }h^{\ast }/\unicode[STIX]{x1D707}_{w}^{\ast }$), the product of the Prandtl ($Pr=\unicode[STIX]{x1D707}_{w}^{\ast }C_{pw}^{\ast }/\unicode[STIX]{x1D705}_{w}^{\ast }$) and Eckert numbers ($Ec=u_{r}^{\ast 2}/C_{pw}^{\ast }T_{w}^{\ast }$) and the wall temperature that in addition to pressure determine the thermodynamic reference condition. For low Eckert numbers, the flow is essentially isothermal and no difference with the well-known stability behaviour of incompressible flows is observed. However, if the Eckert number increases, the viscous heating causes gradients of thermodynamic and transport properties, and non-ideal gas effects become significant. Three regimes of the laminar base flow can be considered: the subcritical (temperature in the channel is entirely below its pseudo-critical value), transcritical and supercritical temperature regimes. If compared to the linear stability of an ideal gas Poiseuille flow, we show that the base flow is modally more unstable in the subcritical regime, inviscid unstable in the transcritical regime and significantly more stable in the supercritical regime. Following the principle of corresponding states, we expect that qualitatively similar results will be obtained for other fluids at equivalent thermodynamic states.
Highlights
Many processes in industrial applications constitute flows with fluids that do not follow the ideal gas law
Since there is very limited knowledge on flow stability with highly non-ideal fluids, we investigate Poiseuille flows with fluids close to the thermodynamic vapour–liquid critical point
To achieve a first impression of the non-ideal gas effects, the problem is first studied with the RP model, where thermodynamic and transport properties are taken from the REFPROP library
Summary
Many processes in industrial applications constitute flows with fluids that do not follow the ideal gas law. Researchers have studied how non-ideal gas effects influence turbulence and heat transfer. Sciacovelli et al (2016), Sciacovelli, Cinnella & Gloerfelt (2017a), Sciacovelli, Cinnella & Grasso (2017b) comprehensively studied turbulence dynamics and near-wall turbulence of flows with molecularly complex fluids in the dense gas regime using direct numerical simulations. Based on the modified O-S equations, early studies show that including a linear temperature profile destabilizes the Poiseuille flow (Potter & Graber 1972) and stabilizes/destabilizes the water boundary layer flow (depend on wall heating/cooling) (Wazzan et al 1972). The above studies are based on the incompressible flow assumption or the ideal gas EoS; at the same time, transport properties are estimated as functions of temperature only. Discussions on the choice of different reference scalings are provided in appendix D
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