HEAT-TRANSFER MODELING IN THE VERTICAL TUBES OF THE PASSIVE CONTAINMENT COOLING SYSTEM OF THE SIMPLIFIED BOILING WATER-REACTOR

Citation
Le. Herranz et al., HEAT-TRANSFER MODELING IN THE VERTICAL TUBES OF THE PASSIVE CONTAINMENT COOLING SYSTEM OF THE SIMPLIFIED BOILING WATER-REACTOR, Nuclear Engineering and Design, 178(1), 1997, pp. 29-44
Citations number
41
ISSN journal
00295493
Volume
178
Issue
1
Year of publication
1997
Pages
29 - 44
Database
ISI
SICI code
0029-5493(1997)178:1<29:HMITVT>2.0.ZU;2-B
Abstract
The long term containment cooling of GE's passive BWR design is based on a new safety system called PCCS (passive containment cooling system ). Performance of this system relies on the pressure difference betwee n the drywell and wetwell in case of an accident and on the condensati on of steam moving downward inside vertical tubes fully submerged in a water pool initially at room temperature. In this paper a model based on the resolution of momentum equations of both phases, the applicati on of the heat and mass transfer analogy, and the consideration of the presence of a noncondensable gas by diffusion theory in a boundary la yer is presented, Assumptions and approximations taken resulted in new methods to estimate film thickness and heat transport from the gas to the interface. Influence of phenomena such as suction, flow developme nt, film waviness, and droplet entrainment has been accounted for. Bas ed on this formulation, a computer programme called HVTNC (heat transf er in vertical tubes with noncondensables) has been built up. HVTNC re sults have been compared to the experimental data available. Experimen tal trends have been reproduced. Heat transfer has been found to be se verely degraded by the presence of noncondensables whereas high Reynol ds numbers of gas flow have been seen to enhance shear stress and ther efore, heat transmission. The average error of HVTNC is essentially lo cated at regions where only a residual fraction of heat remains to be transferred, so that minor deviations can be anticipated in the overal l heat transfer in the tube. Comparison of HVTNC to other models show a substantial gain of accuracy with respect to earlier models. (C) 199 7 Elsevier Science S.A.