|本期目录/Table of Contents|

[1]席雷,徐亮,高建民,等.蒸汽冷却厚壁通道传热性能的耦合传热研究[J].西安交通大学学报,2017,51(09):32-38.[doi:10.7652/xjtuxb201709005]
 XI Lei,XU Liang,GAO Jianmin,et al.Conjugate Calculation of Heat Transfer Performance of a Steam Cooled ThickWall Ribbed Channel[J].Journal of Xi'an Jiaotong University,2017,51(09):32-38.[doi:10.7652/xjtuxb201709005]
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蒸汽冷却厚壁通道传热性能的耦合传热研究(PDF)

《西安交通大学学报》[ISSN:0253-987X/CN:61-1069/T]

卷:
51
期数:
2017年第09期
页码:
32-38
栏目:
出版日期:
2017-09-10

文章信息/Info

Title:
Conjugate Calculation of Heat Transfer Performance of
a Steam Cooled ThickWall Ribbed Channel
作者:
席雷徐亮高建民赵振王明森
西安交通大学机械制造系统工程国家重点实验室,710049,西安
Author(s):
XI LeiXU LiangGAO JianminZHAO ZhenWANG Mingsen
State Key Laboratory for Manufacturing Systems Engineering, Xi’an Jiaotong University, Xi’an 710049, China
关键词:
带肋通道蒸汽冷却传热性能耦合传热
Keywords:
ribbed channel steam cooling heat transfer performance conjugate heat transfer
分类号:
TK47
DOI:
10.7652/xjtuxb201709005
摘要:
基于厚壁带肋通道蒸汽冷却实验数据,发展了含有内热源项的耦合传热计算方法,研究了雷诺数、热流密度和湍流度对厚壁矩形带肋通道内蒸汽流动及传热特性的影响,同时对比了耦合传热方法和只计算流体域方法之间的差异,并在此基础上对努塞尔数与雷诺数、热流密度和湍流度之间进行数值拟合,得到了厚壁带肋通道的传热关联式。研究结果表明:含有内热源项的耦合传热计算模型可以准确地模拟厚壁带肋通道内蒸汽的流动与传热特性,只计算流体域模型对传热系数的预测较耦合传热模型低10%;热流密度对厚壁带肋通道蒸汽摩擦和传热特性的影响较小,高热流密度使得壁面传热效果变差;雷诺数从10 000~90 000变化时,平均传热系数和综合传热因子分别提高了76%和63%,而湍流度从3%~15%变化时,平均传热系数提高了大约24%,综合传热因子提高了19.8%。该研究可为未来重型燃机叶片冷却结构设计提供参考。
Abstract:
Based on the experimental data of a steam cooled thickwall ribbed channel, a conjugate calculation model was established to investigate the influences of Re, heat flux and turbulence intensity on the flow and heat transfer performance of the thickwall ribbed channel. The difference between the conjugate calculation model and the general isoheatflux model was also analyzed. Then the relationship of Nu with Re, heat flux and turbulence intensity was deduced and developed. The results indicate that the conjugate calculation model is able to accurately predict the flow and heat transfer characteristics of the thickwall ribbed channel, and the local heat transfer coefficients predicted by the general isoheatflux model are about 10% lower than that of the conjugate calculation method. Heat transfer performance of the steamcooled ribbed channel with 3D heat conduction effect decreases with the increasing wall heat flux. The heat transfer coefficients and the thermal enhancement factors of the thickwall ribbed channel heighten by 76% and 63% respectively as Re varies from 10 000 to 90 000, and increase by 24% and 19.8% respectively as the turbulence intensity varies from 3% to 15%.

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备注/Memo

备注/Memo:
陕西省青年自然科学基金资助项目(2015JQ5126);国家自然科学基金资助项目(51106124)
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