A model of heat transfer from a cylinder in high-speed slip flow and determination of temperature jump coefficients using hot-wires

Abstract

In small-scale, low-density or high-speed flows, the mean free path of the gas and its molecular interaction with a solid interface are key properties for the analysis of heat transfer mechanisms occurring in many flow processes ranging from micro-scale to aerospace applications. Here, we specifically examine the effects of temperature jump at the gas-solid interface on the convection from a cylinder in the high-speed slip flow regime. By employing the classical Smoluchowski temperature jump condition, we derive a simple model that explicitly predicts the heat flux (Nusselt number Nu) from the surface of a small heated cylinder simulating a hot-wire as a function of the Knudsen number (Kn) and the thermal (or energy) accommodation coefficient (σT) of the gas molecules interacting with the surface. The model, derived analytically and verified empirically by numerical simulations, helps clarifying coupled gas rarefaction and temperature effects on the heat transfer from a cylinder in high-speed flow. In addition, we employ the model reversely to propose a novel methodology to compute gas-surface thermal accommodation or temperature jump coefficients from hot-wire measurements.