A variable geometry concept for advanced turbocharger (TC) systems is presented. The variability of the device is based on outlet area changes as opposed to the more common systems that are based on inlet turbine geometry changes. In addition to the conventional variable turbine geometry (VTG), the new variable turbine type is termed variable outlet turbine (VOT). The flow variability is achieved by variation of the flow cross section at the turbine outlet using an axial displacement of a sliding sleeve over the exducer and provides a simple solution for flow variability. In order to predict the aerodynamic performance and to analyze the loss mechanisms of this new turbine, the flow field of the VOT is calculated by means of steady state 3D-CFD (computational fluid dynamics) simulations. The VOT design is optimized by finding a good balance between clearance and outlet losses. Furthermore, experimental results of the VOT are presented and compared to a turbine equipped with a waste gate (WG) that demonstrates an efficiency advantage of 5%. Additionally, engine performance measurements were carried out to investigate the influence of the VOT on fuel consumption and to asses the functionality of the new pneumatic actuating system. The VOT engine tests show also performance advantage in comparison to a WG turbine especially toward high engine loads. It is found that the use of the VOT at this condition shows a turbine efficiency advantage of 6% related to a reduction in engine fuel consumption of 1.4%. The behavior at part load is neutral and the peak turbine efficiency of the VOT is comparable with a fix turbine geometry.
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Development Heavy Duty Engines,
e-mail: elias.chebli@daimler.com
Department of Mechanical Engineering,
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December 2014
Research-Article
The Variable Outlet Turbine Concept for Turbochargers
Elias Chebli,
Development Heavy Duty Engines,
e-mail: elias.chebli@daimler.com
Elias Chebli
1
Turbocharger Aero-Thermodynamics
,Development Heavy Duty Engines,
Daimler AG
,Stuttgart 70546
, Germany
e-mail: elias.chebli@daimler.com
1Corresponding author.
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Michael Casey,
Michael Casey
Institute of Thermal Turbomachinery,
ITSM,
ITSM,
University Stuttgart
Stuttgart 70546
, Germany
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Ricardo Martinez-Botas,
Department of Mechanical Engineering,
Ricardo Martinez-Botas
Imperial College London
,Department of Mechanical Engineering,
London SW7 2AZ
, UK
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Siegfried Sumser,
Siegfried Sumser
Group Research & Advanced Engineering Powertrain
,Daimler AG
,Stuttgart 70546
, Germany
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Markus Müller,
Markus Müller
Turbocharger Development,
Development Heavy Duty Engines
,Daimler AG
,Stuttgart 70546
, Germany
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Stefan Künzel,
Stefan Künzel
Performance Development,
Development Heavy Duty Engines
,Daimler AG
,Stuttgart 70546
, Germany
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Johannes Leweux,
Johannes Leweux
Turbocharging Development,
Development Heavy Duty Engines
,Daimler AG
,Stuttgart 70546
, Germany
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Andreas Gorbach,
Andreas Gorbach
Engine Development,
Department Heavy Duty
,Daimler AG
,Stuttgart 70546
, Germany
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Wolfram Schmidt
Wolfram Schmidt
Engine Development,
Department Heavy Duty
,Daimler AG
,Stuttgart 70546
, Germany
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Elias Chebli
Turbocharger Aero-Thermodynamics
,Development Heavy Duty Engines,
Daimler AG
,Stuttgart 70546
, Germany
e-mail: elias.chebli@daimler.com
Michael Casey
Institute of Thermal Turbomachinery,
ITSM,
ITSM,
University Stuttgart
Stuttgart 70546
, Germany
Ricardo Martinez-Botas
Imperial College London
,Department of Mechanical Engineering,
London SW7 2AZ
, UK
Siegfried Sumser
Group Research & Advanced Engineering Powertrain
,Daimler AG
,Stuttgart 70546
, Germany
Markus Müller
Turbocharger Development,
Development Heavy Duty Engines
,Daimler AG
,Stuttgart 70546
, Germany
Stefan Künzel
Performance Development,
Development Heavy Duty Engines
,Daimler AG
,Stuttgart 70546
, Germany
Johannes Leweux
Turbocharging Development,
Development Heavy Duty Engines
,Daimler AG
,Stuttgart 70546
, Germany
Andreas Gorbach
Engine Development,
Department Heavy Duty
,Daimler AG
,Stuttgart 70546
, Germany
Wolfram Schmidt
Engine Development,
Department Heavy Duty
,Daimler AG
,Stuttgart 70546
, Germany
1Corresponding author.
Contributed by the International Gas Turbine Institute (IGTI) Division of ASME for publication in the JOURNAL OF TURBOMACHINERY. Manuscript received July 1, 2014; final manuscript received July 26, 2014; published online August 26, 2014. Editor: Ronald Bunker.
J. Turbomach. Dec 2014, 136(12): 121001 (14 pages)
Published Online: August 26, 2014
Article history
Received:
July 1, 2014
Revision Received:
July 26, 2014
Citation
Chebli, E., Casey, M., Martinez-Botas, R., Sumser, S., Müller, M., Künzel, S., Leweux, J., Gorbach, A., and Schmidt, W. (August 26, 2014). "The Variable Outlet Turbine Concept for Turbochargers." ASME. J. Turbomach. December 2014; 136(12): 121001. https://doi.org/10.1115/1.4028231
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