Abstract
From an aerodynamic point of view, the electric turbocharger for the air supply of an automotive fuel cell faces difficult requirements: it must not only control the pressure level of the fuel cell, but it also has to operate with very high efficiency over a wide range. This paper explores features for the compressor and the turbine of an existing electric turbocharger, which are intended to meet the specific requirements of a fuel cell in an experimentally validated numerical study. Adjustable diffuser or nozzle vanes in the compressor and turbine achieve wider operating ranges but compromise efficiency, especially because of the necessary gaps between vanes and end walls. For the turbine, there are additional efficiency losses since the pivoting of the nozzle vanes leads to incidence and thus to flow separation at the leading edge of the nozzle vanes and the rotor blades. An increase in the mass flow and a slight efficiency improvement of the turbine with the low solidity nozzle vanes counteracts these losses. For the compressor, a reduction in the diffuser height and its influence over the operating range and power consumption yields an increase in surge margin as well as in maximum efficiency.
Highlights
We developed a new volute with a linear cross-sectional area progression and a smaller outlet area based on this finding
One observes a significant overestimation of the total pressure when the mixing plane setup is compared to the experimental results, especially at design speed
Decreasing the diffuser height on the shroud side in the vaneless space reduces the backflow in the diffuser inflow which results from the rotor tip-gap vortex
Summary
Academic Editors: Naser Natsheh Al, Michael Sinapius and Christian Hühne. Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. The main components of fuel cell systems are the fuel cell itself, the cooling system, the hydrogen supply and the air supply. Proton exchange membrane (PEM, called polymer electrolyte membrane) fuel cells can be operated at either low or high pressures. The air supply systems of PEM fuel cells use simple blowers with low pressure ratios or more complex centrifugal compressors with high pressure ratios
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