Abstract
We investigate the hydrodynamic stability of compressible boundary layers over adiabatic walls with fluids at supercritical pressure in the proximity of the Widom line (also known as the pseudo-critical line). Depending on the free-stream temperature and the Eckert number that determines the viscous heating, the boundary-layer temperature profile can be either sub-, trans- or supercritical with respect to the pseudo-critical temperature, $T_{pc}$. When transitioning from sub- to supercritical temperatures, a seemingly continuous phase change from a compressible liquid to a dense vapour occurs, accompanied by highly non-ideal changes in thermophysical properties. Using linear stability theory (LST) and direct numerical simulations (DNS), several key features are observed. In the sub- and supercritical temperature regimes, the boundary layer is substantially stabilized the closer the free-stream temperature is to $T_{pc}$ and the higher the Eckert number. In the transcritical case, when the temperature profile crosses $T_{pc}$, the flow is significantly destabilized and a co-existence of dual unstable modes (Mode II in addition to Mode I) is found. For high Eckert numbers, the growth rate of Mode II is one order of magnitude larger than Mode I. An inviscid analysis shows that the newly observed Mode II cannot be attributed to Mack’s second mode (trapped acoustic waves), which is characteristic in high-speed boundary-layer flows with ideal gases. Furthermore, the generalized Rayleigh criterion (also applicable for non-ideal gases) unveils that, in contrast to the trans- and supercritical regimes, the subcritical regime does not contain an inviscid instability mechanism.
Highlights
Complex molecular interactions close to the vapour–liquid critical point of a substance are responsible for the highly non-ideal thermodynamic behaviour
Significant improvements of turbine efficiency can be achieved by using complex molecular fluids in organic Rankine cycles (Brown & Argrow 2000); injecting fuels at supercritical conditions can be employed to obtain higher efficiency of mixing and combustion in air breathing and liquid rocket engines (Wang & Yang 2017); and power cycles operating with supercritical carbon dioxide offer the potential to drastically increase thermal efficiency to enable competitive utility scale renewable electricity production
This study aims to investigate the stability of boundary-layer flows with fluids close to the critical point, through linear stability theory (LST), direct numerical simulations (DNS) and inviscid analysis
Summary
Complex molecular interactions close to the vapour–liquid critical point of a substance are responsible for the highly non-ideal thermodynamic behaviour. Significant improvements of turbine efficiency can be achieved by using complex molecular fluids in organic Rankine cycles (Brown & Argrow 2000); injecting fuels at supercritical conditions can be employed to obtain higher efficiency of mixing and combustion in air breathing and liquid rocket engines (Wang & Yang 2017); and power cycles operating with supercritical carbon dioxide offer the potential to drastically increase thermal efficiency to enable competitive utility scale renewable electricity production Despite this fundamental importance both in science and industrial applications, flow instability and laminar-to-turbulent transition with fluids close to their vapour–liquid critical point still remain unexplored. Kawai (2016) performed the first DNS on supercritical turbulent boundary-layer flow with transcritical temperature, and showed that the turbulent mass flux terms in the turbulent kinetic energy equation largely exceed values as observed for ideal gas at the same free-stream Mach numbers. Applying the Blasius solution, the displacement thickness δ1∗ ≈ 1.721δ∗, momentum thickness δ2∗ ≈ 0.664δ∗ (Schlichting & Gersten 2017)
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