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Combined Cycle for Hybrid Vehicles
Technical Paper
2005-01-1171
ISSN: 0148-7191, e-ISSN: 2688-3627
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English
Abstract
Electric hybrid vehicles change the global design of the electrical power on board, but also of the thermal engine. The concept presented is based on recovery and conversion of thermal energy from the engine cooling circuit and the exhaust pipe by a Rankine cycle. The paper presents the choices of thermodynamic fluids permitting to reach appropriate energy efficiency for conversion of heat in electricity. Water, R-245ca, isopentane are compared and different technical options are studied. Potential for improving the net fuel consumption of hybrid vehicles is estimated to be as high as 32%.
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Citation
El Chammas, R. and Clodic, D., "Combined Cycle for Hybrid Vehicles," SAE Technical Paper 2005-01-1171, 2005, https://doi.org/10.4271/2005-01-1171.Also In
References
- Gott, Philip Linna, Jan-Roger Mello, J.P. Global Insight, Inc. “The evolution of power train technology 2008 and beyond” Fisita Mai 2004 Barcelone
- Kalina AI. “Combined cycle and waste heat recovery power systems based on a novel thermodynamic cycle utilizing low-temperature heat for power generation” ASME Paper 83-JPGC-GT-3 New York ASME 1983
- Jonsson Maria Yan Jinyue “Ammonia-water bottoming cycles: a comparison between gas engines and gas diesel engines as prime movers” Fuel and Energy Abstracts 43 2 March 2002 131
- Oomori Hideyo Ogino Shigeru TOYOTA MOTOR Corp “Waste heat recovery of passenger car using a combination of Rankine bottoming cycle and evaporative engine cooling system” SAE 930880
- Hung Tzu-Chen “Waste heat recovery of Organic Rankine cycles using dry fluids” Fuel and Energy Abstracts 43 2 March 2002 116
- Verschoor M.J.E. Brouwer E.P. “Description of the SMR cycle, which combines fluid elements of steam and organic Rankine cycles” Fuel and Energy Abstracts 36 3 1995 210
- Jeong Jinhee Kang Yong Tae “Analysis of a refrigeration cycle driven by refrigerant steam turbine” International Journal of Refrigeration 27 1 January 2004 33 41
- Kane M. Larrain D. Favrat D. Allani Y. “Small hybrid solar system” Energy 28 14 November 2003 1427 1443
- Larjola J. “Electricity from industrial waste heat using high-speed organic Rankine cycle (ORC)” International Journal of Production Economics 41 1-3 October 1995 227 235
- Hung T. C. Shai T. Y. Wang S. K. “A review of organic Rankine cycles (ORCs) for the recovery of low-grade waste heat” Energy 22 7 July 1997 661 667
- Maizza V. Maizza A. “Unconventional working fluids in organic Rankine-cycles for waste energy recovery systems” Applied Thermal Engineering 21 3 1 February 2001 381 390
- Maizza V. Maizza A. “Working fluids in non-steady flows for waste energy recovery systems” Applied Thermal Engineering 16 7 July 1996 579 590
- Yamamoto Takahisa Furuhata Tomohiko Arai Norio Mori Koichi “Design and testing of the Organic Rankine Cycle” Energy 26 3 March 2001 239 251
- Lemmon E.W. McLinden M.O. “Reference fluid thermodynamic and transport properties” NIST standard reference Database 23
- Folker Renken Karre Volker Peter Skotzek “The Starter generator - Systems, functions and components” FISITA paper N° F2004F104 Barcelone May 2004
- Clodic Denis El Chammas Rody “Système permettant de récupérer l'énergie thermique d'un véhicule à moteur thermique en mettant en oeuvre un cycle de Rankine produisant de l'énergie mécanique et/ou électrique au moyen d'une turbine” 9 Apil 2004