Evaporation of water at high mass-transfer rates by natural convection air flow with application to spent-fuel pools

Abstract

A simple model of evaporation from warm pools of water with turbulent, natural convection flow in the vapor phase is presented. The model is applicable from the dilute, low mass-transfer rate regime (room temperature) through the high mass-transfer rate regime (up to 99°C). The model is applied to spent-fuel pool (SFP) heat and mass transfer during emergency conditions (e.g., plant blackout), and, in particular, to Fukushima. Comparisons with previous models are made. A simple analytic formula is presented that is nearly explicit in solving for pool temperature. The formula separates the more temperature-dependent properties from less temperature-dependent ones via a non-dimensional ratio Qu=qu/qu,b, where qu is the arbitrary (but specified) evaporative (latent) heat flux (∼decay heat for SFP) and qu,b is the latent heat flux characteristic of incipient boiling. The latter has a simple, relatively temperature-independent expression, qu,b=(hfg Le2/3h*)/Cp, where h* is the dilute-limit heat transfer coefficient. This formula predicts that for natural convection at 99°C (h*∼10W/m2K) qu,b is approximately 18kW/m2, slightly greater than, but of the same order of magnitude as, pool boiling heat flux at the onset of nucleate boiling. A new blowing factor correlation is presented for high-rate mass-transfer (Bm>1) of air–water vapor (Pr∼0.7, Sc∼0.6) turbulent natural convection flow over a heated horizontal surface for pool temperatures up to 99°C (incipient boiling).