The pulsating nature of gas flow within the exhaust manifold of an internal combustion engine is not well captured by the quasi-steady techniques typically employed by cycle simulation programs for turbocharger modeling. This problem is compounded by the unequal admission conditions imposed on the turbine by the use of multiple entry housings installed as standard on pulse turbocharged diesel engines. This unsteady behavior presents the simulation engineer with a unique set of difficulties when modeling turbocharger turbines. It is common for experienced analysts to accommodate multiple entries by splitting the flow across duplicate components and by tuning the level of interference between volute entries but this necessarily bespoke approach is limited to upstream modifications that cannot capture true turbine unsteady operation. This paper describes recent simulation code development work undertaken at Caterpillar to improve machine submodel accuracy essential for virtual product development meeting U.S. nonroad Tier 4 emission standards. The resulting turbine performance model has been validated against experimental data for a twin entry turbocharger suitable for heavy duty nonroad applications, obtained using a permanent magnet eddy-current dynamometer and pulse flow test facility. Comparison between experiment and prediction demonstrates good agreement under full admission in terms of both instantaneous flow capacity and turbine actual power although unequal admission results indicate the need for further model development.
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April 2011
Research Papers
Pulse Performance Modeling of a Twin Entry Turbocharger Turbine Under Full and Unequal Admission
Aaron W. Costall,
e-mail: costall_aaron@cat.com
Aaron W. Costall
Caterpillar Inc.
, Applied Research Europe, Perkins Engines Co. Ltd., Peterborough PE1 5NA, UK
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Robert M. McDavid,
e-mail: mcdavid_robert_m@cat.com
Robert M. McDavid
Caterpillar Inc.
, Applied Research Europe, Perkins Engines Co. Ltd., Peterborough PE1 5NA, UK
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Ricardo F. Martinez-Botas,
Ricardo F. Martinez-Botas
Department of Mechanical Engineering,
e-mail: r.botas@imperial.ac.uk
Imperial College London
, Exhibition Road, London SW7 2BX, UK
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Nicholas C. Baines
Nicholas C. Baines
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Aaron W. Costall
Caterpillar Inc.
, Applied Research Europe, Perkins Engines Co. Ltd., Peterborough PE1 5NA, UKe-mail: costall_aaron@cat.com
Robert M. McDavid
Caterpillar Inc.
, Applied Research Europe, Perkins Engines Co. Ltd., Peterborough PE1 5NA, UKe-mail: mcdavid_robert_m@cat.com
Ricardo F. Martinez-Botas
Department of Mechanical Engineering,
Imperial College London
, Exhibition Road, London SW7 2BX, UKe-mail: r.botas@imperial.ac.uk
Nicholas C. Baines
J. Turbomach. Apr 2011, 133(2): 021005 (9 pages)
Published Online: October 19, 2010
Article history
Received:
July 20, 2009
Revised:
August 6, 2009
Online:
October 19, 2010
Published:
October 19, 2010
Citation
Costall, A. W., McDavid, R. M., Martinez-Botas, R. F., and Baines, N. C. (October 19, 2010). "Pulse Performance Modeling of a Twin Entry Turbocharger Turbine Under Full and Unequal Admission." ASME. J. Turbomach. April 2011; 133(2): 021005. https://doi.org/10.1115/1.4000566
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