Modelling the Condensation Phenomena within the Radial Turbine of a Fuel Cell Turbocharger

Modelling the Condensation Phenomena within the Radial Turbine of a Fuel Cell Turbocharger

Radial turbines used in automotive fuel cell turbochargers operate with humid air. The gas expansion in the turbine causes droplets to form, which then grow through condensation. The associated release of latent heat and decrease in the gaseous mass flow strongly influence the thermodynamics of the...

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Bibliographic Details
Main Authors: Tim Wittmann, Sebastian Lück, Christoph Bode, Jens Friedrichs
Format: Article
Language:English
Published: MDPI AG 2021-07-01
Series:International Journal of Turbomachinery, Propulsion and Power
Subjects:
radial turbine
turbocharger
fuel cell
nucleation
condensation
Euler–Lagrange
Online Access:https://www.mdpi.com/2504-186X/6/3/23
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spelling doaj-9c4308d36bb84c55a3c1f0ef0f1affcd2021-09-26T00:26:02ZengMDPI AGInternational Journal of Turbomachinery, Propulsion and Power2504-186X2021-07-016232310.3390/ijtpp6030023Modelling the Condensation Phenomena within the Radial Turbine of a Fuel Cell TurbochargerTim Wittmann0Sebastian Lück1Christoph Bode2Jens Friedrichs3Institute of Jet Propulsion and Turbomachinery, Technische Universität Braunschweig, Hermann-Blenk-Straße 37, 38108 Braunschweig, GermanyInstitute of Jet Propulsion and Turbomachinery, Technische Universität Braunschweig, Hermann-Blenk-Straße 37, 38108 Braunschweig, GermanyInstitute of Jet Propulsion and Turbomachinery, Technische Universität Braunschweig, Hermann-Blenk-Straße 37, 38108 Braunschweig, GermanyInstitute of Jet Propulsion and Turbomachinery, Technische Universität Braunschweig, Hermann-Blenk-Straße 37, 38108 Braunschweig, GermanyRadial turbines used in automotive fuel cell turbochargers operate with humid air. The gas expansion in the turbine causes droplets to form, which then grow through condensation. The associated release of latent heat and decrease in the gaseous mass flow strongly influence the thermodynamics of the turbine. This study aims to investigate these phenomena. For this purpose, the classical nucleation theory and Young’s growth law are integrated into a Euler–Lagrange approach. The main advantages of this approach are the calculation of individual droplet trajectories and a full resolution of the droplet spectrum. The results indicate an onset of nucleation at the blade tip and in the tip gap, followed by nucleation over the entire blade span, depending on the humidity at the turbine inlet. With a saturated turbine inflow, condensation causes the outlet temperature to rise to almost the same level as at the inlet. In addition, condensation losses reduce the efficiency and the latent heat released by condensation leads to significant thermal throttling.https://www.mdpi.com/2504-186X/6/3/23radial turbineturbochargerfuel cellnucleationcondensationEuler–Lagrange
collection DOAJ
language English
format Article
sources DOAJ
author Tim Wittmann
Sebastian Lück
Christoph Bode
Jens Friedrichs
spellingShingle Tim Wittmann
Sebastian Lück
Christoph Bode
Jens Friedrichs
Modelling the Condensation Phenomena within the Radial Turbine of a Fuel Cell Turbocharger
International Journal of Turbomachinery, Propulsion and Power
radial turbine
turbocharger
fuel cell
nucleation
condensation
Euler–Lagrange
author_facet Tim Wittmann
Sebastian Lück
Christoph Bode
Jens Friedrichs
author_sort Tim Wittmann
title Modelling the Condensation Phenomena within the Radial Turbine of a Fuel Cell Turbocharger
title_short Modelling the Condensation Phenomena within the Radial Turbine of a Fuel Cell Turbocharger
title_full Modelling the Condensation Phenomena within the Radial Turbine of a Fuel Cell Turbocharger
title_fullStr Modelling the Condensation Phenomena within the Radial Turbine of a Fuel Cell Turbocharger
title_full_unstemmed Modelling the Condensation Phenomena within the Radial Turbine of a Fuel Cell Turbocharger
title_sort modelling the condensation phenomena within the radial turbine of a fuel cell turbocharger
publisher MDPI AG
series International Journal of Turbomachinery, Propulsion and Power
issn 2504-186X
publishDate 2021-07-01
description Radial turbines used in automotive fuel cell turbochargers operate with humid air. The gas expansion in the turbine causes droplets to form, which then grow through condensation. The associated release of latent heat and decrease in the gaseous mass flow strongly influence the thermodynamics of the turbine. This study aims to investigate these phenomena. For this purpose, the classical nucleation theory and Young’s growth law are integrated into a Euler–Lagrange approach. The main advantages of this approach are the calculation of individual droplet trajectories and a full resolution of the droplet spectrum. The results indicate an onset of nucleation at the blade tip and in the tip gap, followed by nucleation over the entire blade span, depending on the humidity at the turbine inlet. With a saturated turbine inflow, condensation causes the outlet temperature to rise to almost the same level as at the inlet. In addition, condensation losses reduce the efficiency and the latent heat released by condensation leads to significant thermal throttling.
topic radial turbine
turbocharger
fuel cell
nucleation
condensation
Euler–Lagrange
url https://www.mdpi.com/2504-186X/6/3/23
work_keys_str_mv AT timwittmann modellingthecondensationphenomenawithintheradialturbineofafuelcellturbocharger
AT sebastianluck modellingthecondensationphenomenawithintheradialturbineofafuelcellturbocharger
AT christophbode modellingthecondensationphenomenawithintheradialturbineofafuelcellturbocharger
AT jensfriedrichs modellingthecondensationphenomenawithintheradialturbineofafuelcellturbocharger
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