蒸汽发生器,传热,压降,螺旋管摘 要
在采用一体化布置的高温气冷堆中,为了使预应力混凝土压力容器体积不致过大,蒸汽发生器应尽量紧凑,严格限制受热面空间布置,并要求其具有较高的功率密度。因此,一体化布置的高温气冷反应堆主要选用直流型多头螺旋管式蒸汽发生器。
本文从实际工程设计出发,对多头螺旋管式蒸汽发生器的设计进行了研究,提出了多头螺旋管束受热面结构的设计方法,推荐了螺旋管内外的传热系数和压降的计算关系式。根据所提出设计方法和螺旋管内外的传热系数和压降的计算关系式对260MW蒸汽发生器进行了设计计算。
由于螺旋管具有占地面积小、传热系数大、结构紧凑、易于清洗、污垢热阻小等优点,不仅在核反应堆,而且在直流锅炉、急冷锅炉、各种石油化工设备中的换热器,热交换器都有相当广泛的应用。因此本文得到的结果不仅适用于高温气冷反应堆的蒸汽发生器,而且适用于各种工业设备中的螺旋管式换热器和螺旋管式热交换器。
参考文献
1 OECD(The organition for Economic Co-operation and Development )Paris.Nuclear Energy in perspective.1989,12(19)
2 Д.М.斯科洛夫等著.李耀鑫等译.反应堆材料学.原子能出版社,1989
3 庄耀民译.新能源开发方案.水利电力出版社,1989
4 Shepherd.L.R.The Future oj The High-Temperature Reactor.J.Br.Nuclear Engergy Society.1997,16(2)
5 France.G.et al.Desigh Features oj the Dragon Reactor Experiment.The Journal oj the British Nuclear Energy Society.1996,5(3)
6 吴宗鑫.我国高温气冷堆的发展.核动力工程. 2000,21(1)
7 居怀明.10MW高温气冷堆蒸汽发生器稳定性实验研究.核动力工程. 2000,21(6)
8 居怀明.HTR-10蒸汽发生器密度波型不稳定性分析.清华大学学报. 1998,38(5)
9 M.F.Hu,S.W.Qian.Investigation on Shell-Side Fluid Flow in NTIC-DDB Shell and Tube Heat Exchangers by Stream Analysis Method.Multi-phase Flow and Heat Transfer Second International Symposium .New York,Washington,Philadelphia,London,1989
10 嵇训达.我国板翅式换热器技术进展. 低温与特气,1998(1)
11 赵淑芝.换热器技术新进展.石油化工动态.1996(4)
12 Gilli.P.V. Heat Transfer and Pressure Drop for Cross Flow Through Banks of Multistar Helical Tube with Uniform Inclination and Uniform Longitudinal Pitches. Nuclear Science and Engineering.1965(22)
13 林宗虎,陈立勋.锅内过程.西安交通大学出版社,1990
14 Rogers G.F.C. Heat Transfer and Pressure Loss in Helical-Coiled Tubes with Turbulent Flow. Int. J. Heat Mass Transfer,1964(7)
15 Schmidt.E.F.Chem.Ing.Tech.1968,39(13)
16 徐济筠.沸腾传热和气液两相流.原子能出版社,2000
17 Chen,J.C. A correlation for Boiling heat transfer to Saturated Fluids 18 y.1987,78(2) 1963
19 鲁锺in convection Flow.in 6th National Heat Transfer Conference,Boston,琪.气液两相流动和沸腾传热.清华大学出版社,2002
20 Kohler W, Kaster W. Heat Transfer and Pressure Loss in Riffled Tubes. 8th Int. Heat Transfer Conference,U.S.A.,1986
21 Davis M.R, Fungtam asan B. Two-phase Flow through Pipe Branch Junctions. Int. J of Multiphase Flow.1990,16(5)
22 Choi S.H, Shin S, Cho Y.I. The Effect of the Reynolds Number and Width Ratio on the Flow Distribution in Manifolds of Liquid Cooling Modules for Electronic Packaging. International Communication of Heat and Mass Transfer. 1993,20(5)
23 电站锅炉水动力计算方法编写小组.电站锅炉水动力计算方法.上海发电设备成套所,1984
24 鲍亦龄,陆慧琳.锅炉水动力学及锅内设备.哈尔滨工业大学出版社,1988
25 周云龙.高温气冷堆蒸汽发生器两相流不稳定性.西安交通大学博士学位论文.1991
26 容銮恩,袁镇福.电站锅炉原理.中国电力出版社,1997
27 尾花英朗(日).热交换器设计手册.石油工业出版社,1981
28 王丰.液体和气体的热物理性质表.科学出版社,1982
29 钟史明,汪孟乐,范仲元.具有火用 参数的水和水蒸气性质参数手册.水利电力出版社,1984
30 严家录,余晓福.水和水蒸气热力性质图表.高等教育出版社,1995
31 Hans W. Fricker Design and Manufacturing Experience for the German Thorium High-Temperature Reactor 300MW(e) Steam Generator. Nuclear Technology. 1976,28(3)
32 Takao Hayashi. Comparison of Heat Transport Capability of a Steam Generator(SG) in a High-Temperature Gas-Cooled Reactor With That of an SG in Other Types of Reactors. Nuclear Technolog
微信
QQ1:3097331788 QQ2:2601997959 QQ3:2993773635
