This content is not included in
your SAE MOBILUS subscription, or you are not logged in.
Thermodynamic Analysis of an Electricity-Cooling WHR Cogeneration System Aboard Ships using Siloxanes as Working Fluids
Technical Paper
2014-01-1946
ISSN: 0148-7191, e-ISSN: 2688-3627
Annotation ability available
Sector:
Language:
English
Abstract
Cogeneration system has become a valuable alternative approach for cascade waste heat recovery (WHR). In this paper, a novel electricity-cooling cogeneration system (ECCS) based on organic Rankine cycle-absorption refrigeration cycle (ORC-ARC) combined system is proposed to recover the waste heat of marine engine. ORC was adopted in the higher temperature cycle, in which alternatives D4, MDM and MM were selected as the working fluids. An ARC was adopted in the lower temperature cycle to recover the heat of the working fluid at the regenerator outlet in ORC. It aims to satisfy refrigeration requirement aboard ship, in which a binary solution of ammonia-water is used as the working pairs. Electricity output, cooling capacity, total exergy output, primary energy ratio (PER) and exergy efficiency are chosen as the objective functions. The results show that the additional cooling capacity is up to 10.9 MW, and such an ECCS has improved the exergy efficiency by 51% compared to the basic ORC. D4 shows the best performance and it is considered as the most promising working fluid in the three investigated alternatives.
Recommended Content
Technical Paper | The Development of the 6CX-ET Series of Small, High-Performance Turbocharged Marine Diesel Engines |
Technical Paper | The Development of Fixed Radial Air-Cooled Engines |
Technical Paper | The Recycling Potential of Brazilian Vehicles |
Authors
Citation
Liang, Y., Shu, G., Tian, H., Wei, H. et al., "Thermodynamic Analysis of an Electricity-Cooling WHR Cogeneration System Aboard Ships using Siloxanes as Working Fluids," SAE Technical Paper 2014-01-1946, 2014, https://doi.org/10.4271/2014-01-1946.Also In
References
- Saidur , R. , Rezaei , M. , Muzammil , W. K. , Paria , S. , Hasanuzzaman , M. Technologies to recover exhaust heat from internal combustion engines Renewable and Sustainable Energy Reviews 16 8 5649 5659 2012
- Shu , G. , Liang , Y. , Wei , H. , Tian , H. , Zhao , J. , Liu , L. A review of waste heat recovery on two-stroke IC engine aboard ships Renewable and Sustainable Energy Reviews 19 385 401 2013
- Tian , H. , Shu , G. , Wei , H. , Liang , X. , Liu , L. Fluids and parameters optimization for the organic Rankine cycles (ORCs) used in exhaust heat recovery of Internal Combustion Engine (ICE) Energy 47 1 125 136 2012
- Kang S.H. Design and experimental study of ORC (organic Rankine cycle) and radial turbine using R245fa working fluid Energy 41 1 514 524 2012
- Li , Y.R. , Wang , J.N. , and Du , M.T. Influence of coupled pinch point temperature difference and evaporation temperature on performance of organic Rankine cycle Energy 42 1 503 509 2012
- Desai , N.B. , and Bandyopadhyay , S. Process integration of organic Rankine cycle Energy 34 10 1674 1686 2009
- Wei , D. , Lu , X. , Lu , Z. , and Gu , J. Performance analysis and optimization of organic Rankine cycle (ORC) for waste heat recovery Energy Conversion and Management 48 4 1113 1119 2007
- Madhawa Hettiarachchi , H.D. , Golubovic , M. , Worek , W.M. , and Ikegami , Y. Optimum design criteria for an Organic Rankine cycle using low-temperature geothermal heat sources Energy 32 9 1698 1706 2007
- Saleh , B. , Koglbauer , G. , Wendland , M. , and Fischer , J. Working fluids for low temperature organic Rankine cycles Energy 32 7 1210 1221 2007
- Yamamoto , T. , Furuhata , T. , Arai , N. , and Mori , K. Design and testing of the organic rankine cycle Energy 26 3 239 251 2001
- Liu , B.T. , Chien , K.H. , and Wang , C.C. Effect of working fluids on organic Rankine cycle for waste heat recovery Energy 29 8 1207 1217 2004
- Hung , T.C. , Shai , T.Y. , and Wang , S.K. A review of organic rankine cycles (ORCs) for the recovery of low-grade waste heat Energy 22 7 661 667 1997
- Hung , T.C. Waste heat recovery of organic Rankine cycle using dry fluids Energy Conversion and Management 42 5 539 553 2001
- Lai , N.A. , Wendland , M. , and Fischer , J. Working fluids for high-temperature organic Rankine cycles Energy 36 1 199 211 2011
- Drescher , U. , and Brüggemann , D. Fluid selection for the Organic Rankine Cycle (ORC) in biomass power and heat plants Applied Thermal Engineering 27 1 223 228 2007
- Strobl , D.I.W. , and Obieglo , A. The turbosteamer: a system introducing the principle of cogeneration in automotive applications MTZ worldwide 69 5 20 27 2008
- Fernández , F.J. , Prieto , M.M. , and Suárez , I. Thermodynamic analysis of high-temperature regenerative organic Rankine cycles using siloxanes as working fluids Energy 36 8 5239 5249 2011
- Siddiqi , M.A. , and Atakan B. Alkanes as fluids in Rankine cycles in comparison to water, benzene and toluene Energy 45 1 256 263 2012
- Wilcock , D.F. Vapor pressure-viscosity relations in methylpolysiloxanes Journal of the American Chemical Society 68 4 691 696 1946
- Angelino , G. , and Invernizzi , C. Cyclic methylsiloxanes as working fluids for space power cycles Journal of Solar Engineering, ASME 115 3 130 137 1993
- Sulzer RTA 96C Engine Selection and Project Manual Wartsila June 2001
- Dzida , M. On the possible increasing of efficiency of ship power plant with the system combined of marine diesel engine, gas turbine and steam turbine, at the main engine-steam turbine mode of cooperation Polish Maritime Research 16 1 47 52 2009
- Liang , Y. , Shu , G. , Tian , H. , Liang , X. , Wei , H. , Liu , L. Analysis of an electricity-cooling cogeneration system based on RC-ARS combined cycle aboard ship Energy Conversion and Management 76 1053 1060 2013
- Kong , X.Q. , Wang , R.Z. , and Huang , X.H. Energy efficiency and economic feasibility of CCHP driven by stirling engine Energy Conversion and Management 45 9 1433 1442 2004
- Ahmadi , P. , Dincer , I. , and Rosen , M.A. Exergo-environmental analysis of an integrated organic Rankine cycle for trigeneration Energy Conversion and Management 64 447 453 2012
- Huangfu , Y. , Wu , J.Y. , Wang , R.Z. , Kong , X.Q. , Wei , B.H. Evaluation and analysis of novel micro-scale combined cooling, heating and power (MCCHP) system Energy Conversion and Management 48 5 1703 1709 2007
- Balli , O. , Aras , H. , and Hepbasli , A. Thermodynamic and thermoeconomic analyses of a trigeneration (TRIGEN) system with a gas-diesel engine: Part I - Methodology Energy Conversion and Management 51 11 2252 2259 2010
- Perrot , P. A to Z of Thermodynamics Oxford University 0-19-856552-6 1998