Condensation heat transfer for downward flows of superheated steam-air mixture in a circular pipe

被引:2
作者
Murase, Michio [1 ]
Utanohara, Yoichi [1 ]
Goda, Raito [2 ]
Hosokawa, Shigeo [2 ,3 ]
Tomiyama, Akio [2 ]
机构
[1] Inst Nucl Safety Syst Inc, Inst Nucl Technol, 64 Sata, Mihama, Fukui 9191205, Japan
[2] Kobe Univ, Grad Sch Engn, Nada Ku, 1-1 Rokkodai, Kobe, Hyogo 6578501, Japan
[3] Kansai Univ, Suita, Osaka, Japan
来源
NUCLEAR ENGINEERING AND DESIGN | 2021年 / 371卷
关键词
Condensation; Heat transfer; Non-condensable gas; Superheated steam; Vertical pipe; DIFFUSION LAYER MODEL; VAPOR;
D O I
10.1016/j.nucengdes.2020.110948
中图分类号
TL [原子能技术]; O571 [原子核物理学];
学科分类号
0827 ; 082701 ;
摘要
We measured the radial and axial temperature distributions of a saturated steam-air mixture in a vertical circular pipe (diameter, 49.5 mm; cooling height, 610 mm) in our previous study. Those of a superheated steam-air mixture in the same experimental setup were measured in this study. The condensation heat flux qc and heat transfer coefficient hc for the superheated mixture were evaluated, and they were compared with those for the saturated mixture. There was no large difference in qc between the saturated and superheated mixtures. The heat transfer coefficient hc (which was evaluated for the saturation temperature) for the superheated mixture agreed with that for the saturated mixture. hc computed with the diffusion layer model for saturated temperature agreed well with the hc measured for the superheated mixture.
引用
收藏
页数:8
相关论文
共 21 条
[1]   Lesson learned from the SARNET wall condensation benchmarks [J].
Ambrosini, W. ;
Forgione, N. ;
Merli, F. ;
Oriolo, F. ;
Paci, S. ;
Kljenak, I. ;
Kostka, P. ;
Vyskocil, L. ;
Travis, J. R. ;
Lehmkuhl, J. ;
Kelm, S. ;
Chin, Y. -S. ;
Bucci, M. .
ANNALS OF NUCLEAR ENERGY, 2014, 74 :153-164
[2]   MEASUREMENT OF CONDENSATION HEAT-TRANSFER COEFFICIENT INSIDE A VERTICAL TUBE IN THE PRESENCE OF NONCONDENSABLE GAS [J].
ARAKI, H ;
KATAOKA, Y ;
MURASE, M .
JOURNAL OF NUCLEAR SCIENCE AND TECHNOLOGY, 1995, 32 (06) :517-526
[3]  
Colburn AP, 1933, T AM INST CHEM ENG, V29, P174
[4]   Review on condensation on the containment structures [J].
de la Rosa, J. C. ;
Escriva, A. ;
Herranz, L. E. ;
Cicero, T. ;
Munoz-Cobo, J. L. .
PROGRESS IN NUCLEAR ENERGY, 2009, 51 (01) :32-66
[5]   Prediction of steam condensation in the presence of noncondensable gases using a CFD-based approach [J].
Dehbi, A. ;
Janasz, F. ;
Bell, B. .
NUCLEAR ENGINEERING AND DESIGN, 2013, 258 :199-210
[6]   Free convective condensation in a vertical enclosure [J].
Fox, RJ ;
Peterson, PF ;
Corradini, ML ;
Pernsteiner, AP .
NUCLEAR ENGINEERING AND DESIGN, 1997, 177 (1-3) :71-89
[7]  
Green J, 1996, NUCL SAFETY, V37, P26
[8]   A diffusion layer model for steam condensation within the AP600 containment [J].
Herranz, LE ;
Anderson, MH ;
Corradini, ML .
NUCLEAR ENGINEERING AND DESIGN, 1998, 183 (1-2) :133-150
[9]   Review of vapor condensation heat and mass transfer in the presence of non-condensable gas [J].
Huang, Jian ;
Zhang, Junxia ;
Wang, Li .
APPLIED THERMAL ENGINEERING, 2015, 89 :469-484
[10]   Characteristics of film condensation of supersaturated steam-air mixture on a flat plate [J].
Kang, HC ;
Kim, MH .
INTERNATIONAL JOURNAL OF MULTIPHASE FLOW, 1999, 25 (08) :1601-1618
123