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English Pages 372 [391] Year 2020
14TH INTERNATIONAL CONFERENCE ON
The contributions focus on the development of air management solutions and waste heat recovery ideas to support thermal propulsion systems leading to high thermal efficiency and low exhaust emissions. These can be in the form of internal combustion engines or other propulsion technologies (e.g. Fuel cell) in both direct drive and hybridised configuration. 14th International Conference on Turbochargers and Turbocharging also provides a particular focus on turbochargers, superchargers, waste heat recovery turbines and related air managements components in both electrical and mechanical forms.
TURBOCHARGERS AND TURBOCHARGING
14th International Conference on Turbochargers and Turbocharging addresses current and novel turbocharging system choices and components with a renewed emphasis to address the challenges posed by emission regulations and market trends.
Institution of Mechanical Institution Of Mechanical Engineers 1 Birdcage Walk Westminster London SW1H 9JJ
14TH INTERNATIONAL CONFERENCE ON TURBOCHARGERS AND TURBOCHARGING
Engineers
T: +44 (0)20 7973 1251 F: +44 (0)20 7304 6845 E: [email protected]
Institution of Mechanical Engineers
www.imeche.org/events
ISBN: 9780367546526
9 780367 546526
A BALKEMA BOOK
TURBOCHARGERS AND TURBOCHARGING XIV
TURBOCHARGERS AND TURBOCHARGING XIV. PROCEEDINGS OF THE INTERNATIONAL CONFERENCE ON TURBOCHARGERS AND TURBOCHARGING (LONDON, UK, 2021)
TURBOCHARGERS AND TURBOCHARGING XIV
Edited by Institution of Mechanical Engineers
CRC Press/Balkema is an imprint of the Taylor & Francis Group, an informa business Typeset by Integra Software Services Pvt. Ltd., Pondicherry, India The Open Access version of this book, available at www.taylorfrancis.com has been made available under a Creative Commons Attribution-Non CommercialNo Derivatives 4.0 license. Published by: CRC Press/Balkema Schipholweg 107C, 2316XC Leiden, The Netherlands e-mail: [email protected] www.routledge.com – www.taylorandfrancis.com ISBN: 978-0-367-67645-2 (Hbk)
ISBN: 978-1-003-13217-2 (eBook)
DOI: 10.1201/9781003132172
https://doi.org/10.1201/9781003132172
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Turbochargers and Turbocharging XIV – Institution of Mechanical Engineers, ISBN: 978-0-367-67645-2
Table of Contents Organising Committee
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Design and evaluation of an active inlet swirl control device for automotive turbocharger compressors Charles Stuart, Stephen Spence, Queen’s University Belfast Sönke Teichel, Andre Starke, IHI Charging Systems International GmbH Steady-state CFD calculation of a complete turbocharger radial turbine performance map: Mass flow rate and efficiency Georges Salameh, Pascal Chesse, David Chalet, Pierre Marty, Ecole Centrale de Nantes Aerodynamic design of a fuel cell compressor for passenger car application Hua Chen, Dalian Maritime University Lei Huang, Kai Guo, Koen Kramer, Zeyu Zhang, Great Wall Motors Design and validation of a pulse generator for the pulse shaping of the turbine inlet pressure at the hot-gas test bench Philipp Nachital, Henning Rätz, Joerg Seume, Leibniz University Hannover, Institute of Turbomachinery and Fluid Dynamics Holger Mai, Kratzer Automation AG 1D gas exchange modelling of double scroll turbines: Experimental validation and improved modelling Tetsu Suzuki, Georgios Iosifidis, Jörg Starzmann, Dietmar Filsinger, IHI Charging Systems International GmbH Wataru Sato, Takahiro Bamba, IHI Corporation Study on analytical method for thermal and flow field of a VG turbocharger Tsuyoshi Kitamura, Toru Suita, Toyotaka Yoshida, Mitsubishi Heavy Industries Yosuke Danmoto, Yoji Akiyama, Mitsubishi Heavy Industries Engine & Turbocharger
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One dimensional modelling on twin-entry turbine: An application of TURBODYNA Bijie Yang, Ricardo Martinez-Botas, Peter Newton, Imperial College London Toru Hoshi, Bipin Gupta, Seiichi Ibaraki, Mitshubishi Heavy Industries A system-level study of an organic Rankine cycle applied to waste heat recovery in light-duty hybrid powertrains Antonio Pessanha, Colin Copeland, University of Bath Zhihang Chen, Jaguar Land Rover
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Designing a bespoke high efficiency turbine stage for a key engine condition through pulse utilisation Craig Hasler, Cummins Turbo Technologies
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Development and validation of a high-pressure compressor stage Robert Lotz, BorgWarner Emissions
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The smallest CV VNTTM developed for Euro VI+ & Japan PPNLT light duty commercial applications with extreme braking Shuichi Ikeda, Ondrej Senekl, Vinaey Kalyanaraman, Garrett – Advancing Motion
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Integrated design optimisation and engine matching of a turbocharger radial turbine Piotr Luczynski, Carola Freytag, Manfred Wirsum, Institute of Power Plant Technology, Steam and Gas Turbines, RWTH Aachen Karl Hohenberg, Ricardo Martinez-Botas, Imperial College London Maximum turbocharger efficiency for an engine operating at 50% brake thermal efficiency Parasharan Ananthakrishnan, Seán Egan, Jamie Archer, Cummins Turbo Technologies Timothy Shipp, Cummins Research and Technology Transfer of turbocharger shaft motion behavior from engine testing to hot gas component testing Felix Falke, Adrian Schloßhauer, Hendrik Ruppert, Institute for Combustion Engines, RWTH Aachen University Max Stadermann, Dominik Lückmann, Richard Aymanns, FEV Europe GmbH
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Experimental investigation on the transient response of an automotive turbocharger coupled to an electrically assisted compressor Silvia Marelli, Vittorio Usai, Massimo Capobianco, University of Genoa Steady state and transient tuning of a driven turbocharger for commercial diesel engines Thomas Waldron, Ryan Sherill, Jared Brin, Super Turbo Technologies Development of new generation MET turbocharger Yushi Ono, Yoshikazu Ito, Mitsubishi Heavy Industries Marine Machinery and Equipment An approach to thermo-mechanical fatigue life prediction for turbine housings in gasoline engine application Hiroaki Nakai, Masahiro Takanashi, Hidenori Kojima, Kotaro Ito, IHI Corporation Multidisciplinary and multi-point optimisation of radial and mixed-inflow turbines for turbochargers using 3D inverse design method Jiangnan Zhang, Advanced Design Technology Mehrdad Zangeneh, University College London Experimental and computational analysis of the flow passing through each branch of a twin-entry turbine José Galindo, José Ramón Serrano, Luis Miguel García-Cuevas, Nicolás Medina, Universitat Politècnica de València Design and modelling of circular volutes for centrifugal compressors Hamid Hazby, Robert O’Donoghue, Chris Robinson, PCA Engineers SC-VNTTM a route toward high efficiency for gasoline engines Nathaniel Bontemps, David Francois, Juan Camillo Sierra, Peter Davies, Garrett – Advancing Motion Leandro Lazzarini Monaco, Alois Fuerhapter, AVL List GmbH
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Study on loss characteristic of penetrating exhaust manifold for low-speed two-stroke marine diesel engine Yingyuan Wang, Ruiqi Zhang, Mingyang Yang, Kangyao Deng, Shanghai Jiao Tong University Bo Liu, Yuehua Qian, China Shipbuilding Power Engineering Institute Co Heat transfer modelling in vehicular turbochargers for engine simulation Yoshiyuki Watanabe, Nobuyuki Ikeya, Shun Okamoto, IHI Corporation Dietmar Filsinger, IHI Charging System International GmbH Trends in passenger car powertrains and their impact on turbocharger developments Nick Baines, Consultant Eric Krivitzky, Dartmouth College Jiangtao Bai, Xuefeng Zhang, Xeca Turbo Technologies
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360 Boosting the JCB Fastrac “World’s fastest tractor” Alex Skittery, JCB Power Systems Richard Cornwall, Richard King, Ricardo Automotive & Industrial Author index
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Turbochargers and Turbocharging XIV – Institution of Mechanical Engineers, ISBN: 978-0-367-67645-2
Organising Committee Powertrains Systems and Fuels Group The Institution of Mechanical Engineers
Member Credits Ricardo Martinez-Botas (Chair)
Imperial College London
Peter Davies (Vice-Chair)
Garett – Advancing Motion
Jamie Archer
Cummins Turbo Technologies
Lutz Aurahs
MAN Energy Solutions
Alan Baker
Jaguar Land Rover
Kian Banisoleiman
Lloyd's Register EMEA
Andrew Banks
Ricardo
Dr Elias Chebli
Porsche
Colin Copeland
University of Bath
Michael Dolton
Cummins Turbo Technologies
Dietmar Filsinger
IHI Charging System Inter national GmbH
Dino Imhof
ABB Turbocharging
Steve Johnson
Ford Motor Company
Rogier Lammers
Mitsubishi Turbocharger and Engine Europe B.V.
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Per-Inge Larson
SCANIA Power Train Sweden
Nathan McArdle
BorgWarner
Takashi Mori
IHI Corporation
Takashi Otobe
Honda R&D
Prabhu Ramasamy
Caterpillar
Joerg Seume
Leibniz Universitaet Hannover
Stephen Spence
Queen's University Belfast
Bernd Wietholt
Volkswagen AG
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Turbochargers and Turbocharging XIV – Institution of Mechanical Engineers, ISBN: 978-0-367-67645-2
Design and evaluation of an active inlet swirl control device for automotive turbocharger compressors C. Stuart, S.W. Spence School of Mechanical and Aerospace Engineering, Queen’s University Belfast, UK S. Teichel, A. Starke IHI Charging Systems International GmbH, Heidelberg, Germany ABSTRACT It is widely accepted that large swirl angles (>60°) are required to deliver meaningful surge margin extension at the relatively low pressure ratios typical of automotive turbocharger compressors. However, in order to maintain performance towards choke (and hence the rated power point of the engine), the requirement is for delivery of zero pre-swirl. These constraints cannot be met using traditional variable inlet guide vane systems, as whether flat plate or cambered vanes are chosen, significant losses are to be expected at low and high mass flow rates respectively. Taking the above into account, the primary intention of this study was to develop a device capable of efficiently generating large swirl angles for surge margin extension and compressor efficiency enhancement at low mass flow operating points, without adversely affecting performance at other areas of the compressor map. The chosen concept involved placing an axial fan upstream of a standard automotive turbocharger compressor stage. The fan was designed to act as a variable pre-swirl device, which due to being driven by an electric motor, was capable of operating com pletely independently of the centrifugal impeller. The chosen concept was progressed through 1-D and 3-D design phases to understand the feasibility of the system, before committing to hardware manufacture and an extensive experimental test campaign to validate the numerical findings and test the surge margin extension potential of the device.
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INTRODUCTION
In order to ensure compliance with the increasingly stringent emissions targets being levied by legislators around the world, the uptake of the concept of engine downsizing (as well as additional complementary technologies such as Miller valve timing) in the automotive sector is becoming increasingly prevalent. From the perspective of the turbocharger, these strategies place additional demands upon enhancing compressor performance and stability at low mass flow operating conditions. One approach to achieve this goal that is common in larger scale applications is the application of positive pre-swirl (introduction of a non-zero circumferential velocity component, Vu1, in the same direction as impeller rotation) at compressor inlet through the use of inlet guide vanes. For automotive turbocharging applications, the expected improvements can be summarised as follows. Firstly, improvements in com pressor efficiency can be expected at low mass flow rates due to the alleviation of inci dence based losses. One study utilising an automotive turbocharger compressor [1] cited up to a 3.0%pt improvement in efficiency at a pressure ratio of 2.5 through the application of pre-swirl. Secondly, the possibility to extend the compressor surge
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margin is a particularly attractive benefit. However, due to the relatively modest pres sure ratios of automotive turbocharger compressors, it has been recognised that high levels of swirl are required to achieve a tangible improvement (60°-70° @ PR