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Numerical Simulation of Boiling Heat Transfer in Water Jacket of DI Engine
ISSN: 0148-7191, e-ISSN: 2688-3627
Published April 12, 2010 by SAE International in United States
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Heat transfer plays an important role in the conceptual and detail design of cooling system of modern DI engine and has considerable influence over their operational performance and durability. The consequential demand for higher possible heat transfer rates has lead to the very promising concept of providing for a controlled transition from pure single-phase convection to subcooled boiling flow in some high thermal load regions. In order to achieve controlled boiling over a wide range of operation conditions, the detailed flow and heat transfer analysis is essential. CFD simulation incorporating the boiling model is an effective approach for such analysis. Four different boiling heat transfer models are proposed and developed within CFD framework, two based on Division Description Method (DDM), and another two based on Superposition Method (SM). The calculation results and the test validation show that Boiling Model A based on DDM and Modified BDL (Boiling Departure Lift-off) Model based on SM are in better satisfactory agreement with the experimental data than other two models under the same conditions and could be used for calculating the boiling heat transfer in cooling water jacket of DI engine. And CFD code adopted is SC/Tetra V7® developed by Software CRADLE Co. LTD.
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CitationDong, F., Fan, Q., Cai, Y., Jiang, S. et al., "Numerical Simulation of Boiling Heat Transfer in Water Jacket of DI Engine," SAE Technical Paper 2010-01-0262, 2010, https://doi.org/10.4271/2010-01-0262.
- Yu Xiumin Chen Haibo Huang Haizhen Chen Qun Gao Ying 2008 “Development of Numerical Simulation on Flow and Heat Transfer in Internal Combustion Engine Cooling System” Chinese Journal of Mechanical Engineering 44 162 167
- Hawley J G Wilson M Campbell N A F Hammond G P Leathard M J 2004 “Predicting boiling heat transfer using computational fluid dynamics” IMechE 218 509 520
- Bo, T. “CFD Homogeneous Mixing Flow Modelling to Simulate Subcooled Nucleate Boiling Flow,” SAE Technical Paper 2004-01-1512 2004
- Solver Reference of User's Guide of SC/Tetra Version 7.0 Software Cradle Co. Ltd 2008
- Collier J G Thome J R 1994 “Convective Boiling and Condensation” 3rd Oxford University Press
- Rohsenow, W.M. 1952 “A Method of Correlating Heat Transfer Data for Surface Boiling of Liquid” Trans. ASME 74 969
- Guglielmini G. Nannei E. Pisoni C. 1980 “Survey of Heat Transfer Correlations in Forced Convection Boiling” Wärme-und Stofffübertragung
- Bowring W R 1962 “Physical Model of Bubble Detachment and Void Volume in Subcooled Boiling” OECD Halden Reactor Project Report No. HPR-10
- Bergles A E Rohsenow W M 1984 “The determination of forced convection surface boiling heat transfer” Trans. ASME J. Heat Transfer 86 365 372
- Steiner Helfried Kobor Alexander Gebhard Ludwig 2005 “A Wall Heat Transfer Model for Subcooled Boiling Flow” International Journal of Heat and Mass Transfer” 48 4161 4173
- Abou-Ziyan Hosny Z. 2004 “Forced Convection and Subcooled Flow Boiling Heat Transfer in Asymmetrically Heated Ducts for T-Section” Energy Conversion and Management 45 1043 1065
- Incropera Frank P. DeWitt David P. 2006 “Fundamentals of Heat and Mass Transfer” 5th John Wiley & Sons