Buoyancy effects on film boiling heat transfer over a sphere at low velocities

TL;DR

This paper develops a theoretical model for film boiling over a sphere that incorporates buoyancy effects, showing how these effects influence vapor layer thickness and heat transfer at low velocities.

Contribution

It introduces a novel analytical model that accounts for buoyancy in the vapor phase during film boiling over a sphere, extending previous studies.

Findings

Vapor boundary layer thickness increases with sphere size and water temperature.

Heat transfer coefficient decreases as vapor layer thickens.

Buoyancy significantly delays flow separation at velocities below 0.5 m/s.

Abstract

A theoretical model is developed for the forced convection film boiling phenomenon over a heated sphere moving vertically downwards in the water. Unprecedented to the previous analytical studies, this model accounts for the buoyancy effects while solving the momentum, and energy equations in the vapor phase to obtain the velocity, and the temperature distribution in terms of the vapor boundary layer thickness. To calculate the vapor boundary layer thickness an energy balance is applied at the vapor-liquid interface. The flow of liquid around the sphere is considered to be governed by the potential theory, and the energy equation in liquid is then solved for the known velocity distribution. We find that the vapor boundary layer thickness increases with an increase in the sphere, and the bulk water temperature, and a decrease in the free stream velocity. This further results in a decrease in the film boiling heat transfer coefficient. The present study concludes that at low free stream velocities ($< 0.5$ m/s) buoyancy becomes significant in delaying the separation, and when the velocity is further reduced the separation angle approaches $180^{\circ}$.