A numerical study of heat transfer in bottom-heated and side/top-cooled liquid metal layers with different aspect ratiosShow others and affiliations
2022 (English)In: Annals of Nuclear Energy, ISSN 0306-4549, E-ISSN 1873-2100, Vol. 177, p. 109328-, article id 109328Article in journal (Refereed) Published
Abstract [en]
A liquid metal layer heated from bottom and cooled from both side and top can be encountered in indus-trial applications. A special interest is from safety design of advanced pressurized water reactors that adopt the so-called in-vessel melt retention (IVR) to mitigate severe accident risk. Quantification of heat transfer in a stratified melt pool in the lower head of a reactor pressure vessel (RPV) is of great impor-tance to the qualification of the IVR strategy. The upper liquid metal layer of the stratified melt pool is heated by the lower molten oxide layer (with decay heat) underneath, and cooled by water outside the reactor vessel and by radiation or flooded water at the top. This is essentially a problem of natural convection and heat transfer in a liquid metal layer heated from bottom and cooled from both side and top. The present study is conducted to numerically investigate the heat transfer characteristics of such layer with an emphasis on the influence of the aspect ratio (ratio of radius to height; R/H) of the liq-uid metal layer. Based on the numerical outcomes, three correlations of heat transfer coefficients (for downward, upward and sideward flows) are also developed to account for the impact the aspect ratio. The numerical simulation results show that, under the same Rayleigh number, the bulk temperature and the upward and sideward heat fluxes all increase with R/H, but the downward heat flux decreases with R/H. The Nusselt numbers in all directions decrease with increasing R/H, as a reduced cooling -heating area ratio due to increasing R/H shall suppress the cooling efficiency and the convection. When R/H is larger than a threshold (-8), the heat transfer characteristics are no longer sensitive to R/H. Each correlation of heat transfer coefficient is developed as the product of two terms: a base correlation of heat transfer coefficient that is Ra dependent only, and an aspect ratio factor that considers the effect of aspect ratio R/H. The developed correlations are compared with the numerical simulation results of cases with different aspect ratios and Rayleigh numbers, and good agreements achieved.
Place, publisher, year, edition, pages
Elsevier BV , 2022. Vol. 177, p. 109328-, article id 109328
Keywords [en]
Molten pool, Natural convection, Heat transfer, Aspect ratio, In-vessel retention
National Category
Subatomic Physics Energy Systems
Identifiers
URN: urn:nbn:se:kth:diva-316438DOI: 10.1016/j.anucene.2022.109328ISI: 000834591600004Scopus ID: 2-s2.0-85134311735OAI: oai:DiVA.org:kth-316438DiVA, id: diva2:1688206
Note
QC 20220818
2022-08-182022-08-182024-03-15Bibliographically approved