Experimental study of primary and secondary side coupling natural convection heat transfer characteristics of the passive residual heat removal system in AP1000

Zhimin QIU , Daogang LU , Jingpin FU , Li FENG , Yuhao ZHANG

Front. Energy ›› 2021, Vol. 15 ›› Issue (4) : 860 -871.

PDF (1682KB)
Front. Energy ›› 2021, Vol. 15 ›› Issue (4) : 860 -871. DOI: 10.1007/s11708-021-0744-1
RESEARCH ARTICLE
RESEARCH ARTICLE

Experimental study of primary and secondary side coupling natural convection heat transfer characteristics of the passive residual heat removal system in AP1000

Author information +
History +
PDF (1682KB)

Abstract

Passive residual heat removal heat exchanger (PRHR HX), which is a newly designed equipment in the advanced reactors of AP1000 and CAP1400, plays an important role in critical accidental conditions. The primary and secondary side coupling heat transfer characteristics of the passive residual heat removal system (PRHRS) determine the capacity to remove core decay heat during the accidents. Therefore, it is necessary to investigate the heat transfer characteristics and develop applicable heat transfer formulas for optimized design. In the present paper, an overall scaled-down natural circulation loop of PRHRS in AP1000, which comprises a scaled-down in-containment refueling water storage tank (IRWST) and PRHR HX models and a simulator of the reactor core, is built to simulate the natural circulation process in residual heat removal accidents. A series of experiments are conducted to study thermal-hydraulic behaviors in both sides of the miniaturized PRHR HX which is simulated by 12 symmetric arranged C-shape tubes. For the local PRHR HX heat transfer performance, traditional natural convection correlations for both the horizontal and vertical bundles are compared with the experimental data to validate their applicability for the specific heat transfer condition. Moreover, the revised natural convection heat transfer correlations based on the present experimental data are developed for PRHR HX vertical and lower horizontal bundles. This paper provides essential references for the PRHRS operation and further optimized design.

Graphical abstract

Keywords

passive residual heat removal heat exchanger (PRHR HX) / C-shape tube / revised heat transfer correlations / coupled natural convection

Cite this article

Download citation ▾
Zhimin QIU, Daogang LU, Jingpin FU, Li FENG, Yuhao ZHANG. Experimental study of primary and secondary side coupling natural convection heat transfer characteristics of the passive residual heat removal system in AP1000. Front. Energy, 2021, 15(4): 860-871 DOI:10.1007/s11708-021-0744-1

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Lin C G. The Advanced Passive Pressurized Water Reactor AP1000. Beijing: Atomic Energy Press, 2008
[2]

Reyes J N. Final report of NRC AP600 research conducted at Oregon State University. NUREG/CR-6641, 1999
[3]

Yonomoto T, Kukita Y, Schultz R R. Heat transfer analysis of the passive residual heat removal system in ROSA/AP600 experiments. Nuclear Technology, 1998, 124(1): 18–30
[4]

Men Q M, Wang X S, Zhou X, Heat transfer analysis of passive residual heat removal heat exchanger under natural convection condition in tank. Science and Technology of Nuclear Installations, 2014: 279791
[5]

Lu D G, Zhang Y H, Fu X L, Experimental investigation on natural convection heat transfer characteristics of C-shape heating rods bundle used in PRHR HX. Annals of Nuclear Energy, 2016, 98: 226–238
[6]

Zhang Y H, Lu D G, Wang Z Y, Experimental investigation on pool-boiling of C-shape heat exchanger bundle used in PRHR HX. Applied Thermal Engineering, 2017, 114: 186–195
[7]

Tao J Q, Gu H H, Xiong Z Q, Investigation on transient thermal hydraulics of reduced scale passive residual heat removal heat exchanger in tank. Annals of Nuclear Energy, 2019, 130: 402–410
[8]

Liu Y B, Wang X S, Men Q M, Heat transfer analysis of passive residual heat removal heat exchanger under tube outside boiling condition. Science and Technology of Nuclear Installations, 2017: 3497103
[9]

Kang M G. Experimental investigation of tube length effect on nucleate pool boiling heat transfer. Annals of Nuclear Energy, 1998, 25(4–5): 295–304
[10]

Yang S M, Tao W Q. Heat Transfer. Beijing: Higher Education Press, 2006 (in Chinese)
[11]

Zhang Y H, Yuan Y L, Feng L, Application of the modified heat transfer formulas for the C-type heat exchanger in passive heat removal system of CAP1400. Applied Thermal Engineering, 2019, 159: 113876
[12]

Bergles A E, Rohsenow W M. The determination of forced-convection surface-boiling heat transfer. Journal of Heat Transfer, 1964, 86(3): 365–372
[13]

Popiel C O, Wojtkowiak J. Experiments on free convective heat transfer from side walls of a vertical square cylinder in air. Experimental Thermal and Fluid Science, 2004, 29(1): 1–8
[14]

Churchill S W, Chu H H S. Correlating equations for laminar and turbulent free convection from a vertical plate. Interactional Journal of Heat and Mass Transfer, 1975, 18(11): 1323–1329
[15]

McAdams W H. Heat Transmission. 3rd ed. New York: McGraw-Hill, 1954
[16]

Churchill S W. Laminar free convection from a horizontal cylinder with a uniform heat flux density. Letters in Heat and Mass Transfer, 1974, 1(2): 109–111
[17]

Ghiaasiaan S M. Convective Heat and Mass Transfer. New York: Cambridge University Press, 2011

RIGHTS & PERMISSIONS

Higher Education Press

AI Summary AI Mindmap
PDF (1682KB)

5012

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/