标题:Fluid-Solid Interaction Heat Transfer Analysis of Cylinder Head in Consideration of Boiling and In-Cylinder Local Heat Transfer
作者:Liu X.; Li M.; Zheng Q.; Li S.; Li G.
作者机构:[Liu, X] School of Energy and Environmental Engineering, Hebei University of Technology, Tianjin, 300401, China, School of Energy and Power Engineerin 更多
通讯作者:Li, S(13352067329@189.cn)
通讯作者地址:[Li, S] School of Energy and Environmental Engineering, Hebei University of TechnologyChina;
来源:Neiranji Gongcheng/Chinese Internal Combustion Engine Engineering
出版年:2017
卷:38
期:6
页码:139-144
DOI:10.13949/j.cnki.nrjgc.2017.06.022
关键词:Boiling heat transfer; Cylinder head; Diesel engine; Fluid-structure interaction; In-cylinder local heat transfer
摘要:Based on the gas-side local heat transfer boundary conditions of cylinder head and cylinder liner obtained by the in-cylinder heat transfer model and the water-side heat transfer boundary conditions obtained by the homogeneous flow boiling heat transfer model, a heat transfer calculation of the structural temperature field coupled with the gas-side and water side boundary conditions was carried out on an in line 6 cylinder diesel engine for commerical vehicles, and the state of boiling heat transfer in cylinder head water channel was evaluated. Results show that the simulation results of the cylinder head temperature are in good agreement with the measured values. The maximum cylinder head temperature is located at the bridge zone between two exhaust valves on the cylinder head fire deck. The gas heat transfer coefficient and gas temperature between the exhaust valves are at a high value, while the in-cylinder local heat transfer is significant. The cooling water at the center of the cylinder head fire deck and in the water channel near the exhaust valve is in a state of partially developed nucleate boiling. © 2017, Chinese Society for Internal Combustion Engines(CSICE). All right reserved.
收录类别:SCOPUS
资源类型:期刊论文
原文链接:https://www.scopus.com/inward/record.uri?eid=2-s2.0-85043269053&doi=10.13949%2fj.cnki.nrjgc.2017.06.022&partnerID=40&md5=78c30cbc5c139c53fb7f5114af3a8558
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