Heat transfer analysis of the bent cooling channels in SSRF light-blocked components

Heat transfer analysis of the bent cooling channels in SSRF light-blocked components

下载PDF

导出

摘要 The front end light-blocked components of the third generation of synchrotron radiation facility,which are subjected to high heat load,are cooled with flowing water through the cooling channels.The convective heat transfer coefficient and the flow resistance(or pressure drop) are two important parameters for evaluating the heat transfer performance of the cooling channels and should be strictly quantified.In this research,two typical bent cooling channels in Shanghai Synchrotron Radiation Facility(SSRF) were modeled and their in-pipe turbulent flows were simulated.The two criteria obtained under different channel water velocities met the SSRF technical requirements.To reduce the total pressure drop,arc transitions were proposed to replace the right angle transitions in the cooling channels.At the same time,an experiment was performed to measure the convective heat transfer coefficient of a typical bent channel unit.The experimental results were in good agreement with the simulation ones. The front end light-blocked components of the third generation of synchrotron radiation facility,which are subjected to high heat load,are cooled with flowing water through the cooling channels.The convective heat transfer coefficient and the flow resistance（or pressure drop） are two important parameters for evaluating the heat transfer performance of the cooling channels and should be strictly quantified.In this research,two typical bent cooling channels in Shanghai Synchrotron Radiation Facility（SSRF） were modeled and their in-pipe turbulent flows were simulated.The two criteria obtained under different channel water velocities met the SSRF technical requirements.To reduce the total pressure drop,arc transitions were proposed to replace the right angle transitions in the cooling channels.At the same time,an experiment was performed to measure the convective heat transfer coefficient of a typical bent channel unit.The experimental results were in good agreement with the simulation ones.

作者 JIN Jianfeng CHEN Haibo XIAO Weiling CHENG Wenlong WANG Naxiu

机构地区 Department of Modern Mechanics Beijing Institute of Space Long March Vehicle Department of Thermal Science and Energy Engineering Shanghai Institute of Applied Physics

出处《Nuclear Science and Techniques》 SCIE CAS CSCD 2012年第6期321-327,共7页 核技术（英文）

基金 Supported by Natural Science Foundation of China(10975130)

关键词冷却通道 SSRF 弯曲通道传热分析上海同步辐射装置对流换热系数光阻流动阻力 Convective heat transfer coefficient Pressure drop Numerical simulation Experimental test

分类号 TL503.91 [核科学技术—核技术及应用]

引文网络
相关文献

参考文献9

1Kuzay T, Collins J, Koons J. Int J Heat Mass Tran, 1999, 42:1189-1204.
2Jaski Y, Trakhtenberg E, Collins J. Thermo-mechanical analysis of high-heat-load components for the canted- undulator front end. 1st international workshop on mechanical engineering design of synchrotron radiation equipment and instrumentation, Wurenlingen, Switzerland, July, 2000.
3Benson C, Trakhtenberg E, Jaski Y. Mechanical design of a front end for canted undulators at the advanced photon source. Eighth international conference on synchrotron radiation instrumentation, San Francisco, California, USA, August, 2003, 466469.
4Takiya T, Mochizuki T, Kitamura H. Development of enhanced heat transfer coolant channels for the spring-8 front end components. Spring-8 annual report, Harima Science Garden City, Hyogo, Japan, 1998, 164-166.
5Collins J, Conley C, Attig J. Enhanced heat transfer using wire-coil inserts for high-heat-load applications. The 2nd international workshop on mechanical engineering design of synchrotron radiation equipment and instrumentation, Argonne, Illinois, USA, September, 2002.
6Sharma S, Doose C, Rotela E. An evaluation of enhanced cooling techniques for high-heat-load absorbers. The 2nd international workshop on mechanical engineering design of synchrotron radiation equipment and instrumentation, Argonne, Illinois, USA, September, 2002.
7Yang S M, Tao W Q. Heat transfer theory. Beijing, Higher Education Press, 2007, 162 165.
8Yuan J T, Tong L L, Cao X W. Nucl Sci Tech, 2010, 21: 370-374.
9Li Y, Yan C Q, Sun Z N, et al. Nucl Sci Tech, 2011, 22: 122-128.

1P．Heinrich,项钟庸,徐国群.轻型长寿铜冷却壁的设计改进及其在大型高炉上的试验[J].世界钢铁,2003,3(6):41-45.
2吉桂明.SGT6-8000H燃气轮机的应用[J].热能动力工程,2011,26(2):151-151.
3是成之.美国BENTLY公司转速表的特点[J].电气技术,1989(3):56-59.
4马玉辉,田夫,王晓放.基于OpenFOAM的旋转弯曲通道内流动的数值模拟[J].科学技术与工程,2010,10(16):3858-3863.
5今给黎孝一郎,骆巧珍.装有可调喷嘴的MET—SR—VG型增压器的开发[J].国外内燃机车,1992(1):11-15.
6谭云松,张国华.MET湿法烟气脱硫技术应用实例[J].应用能源技术,2013(4):25-27.
7Axcelis公司推出全新Integra RS干法光阻去除清洗系统[J].电子工业专用设备,2008,37(9):68-69.
8Heinr.,P,温宏权.优化高炉冷却的椭圆形单通道铜冷却壁[J].世界钢铁,2001,1(5):17-20.
9孙国富,顾启泰,刘学斌.Principle and Implementation of an MC4044-Based Phase Locked Loop for Constant Speed Control[J].Tsinghua Science and Technology,2000,5(4):409-413. 被引量：1
10黄汉豪.太阳能路灯[J].能量转换利用研究动态,2002,13(6):21-21.

Nuclear Science and Techniques

2012年第6期

浏览历史

内容加载中请稍等...

Heat transfer analysis of the bent cooling channels in SSRF light-blocked components

参考文献9

相关作者

相关机构

相关主题

浏览历史