Abstract
Fluid machinery operating in the supersonic regime unveil avenues towards more compact technology. However, internal supersonic flows are associated with high aerodynamic and thermal penalties, which usually prevent their practical implementation. Indeed, both shock losses and the limited operational range represent particular challenges to aerodynamic designers that should be taken into account at the initial phase of the design process. This paper presents a design methodology for supersonic passages based on direct evaluations of the velocity field using the method of characteristics and computation of entropy generation across shock waves. This meshless function evaluation tool is then coupled to an optimization scheme, based on evolutionary algorithms that minimize the entropy generation across the supersonic passage. Finally, we assessed the results with 3D Reynolds Averaged Navier Stokes calculations.
Highlights
The specific power extraction in fluid machinery scales with the specific mass flow, reaching a maximum at sonic conditions
We are compelled to explore supersonic internal rotating passages. The design of such supersonic internal passages is governed by the existence of large shock losses and a restricted operational range [1,2]
This paper presents a design methodology for two-dimensional supersonic internal flow passages
Summary
The specific power extraction in fluid machinery scales with the specific mass flow, reaching a maximum at sonic conditions. Based on the conservation of momentum through a fluid machine, it Entropy 2015, 17 follows that the specific power increases with the flow velocity. We are compelled to explore supersonic internal rotating passages. The design of such supersonic internal passages is governed by the existence of large shock losses and a restricted operational range [1,2]. In the 1950s, research was focused on steam turbine applications [3] and rocket propulsion systems [4]. Supersonic turbine rotors with a subsonic axial Mach number are being used in several applications:
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