Hybrid forced-buoyancy convection in a channel with a backward facing step

The present work integrates and expands the line of inquiry started in Inam and Lappa (2021), Int. J. of Heat and Mass Transfer, 173, 121267 for unsteady mixed forced-buoyancy convection in a channel with a forward facing step by addressing the mirror case where the fluid flowing in a duct undergoes a sudden expansion (i.e., a channel with a backward facing step). By alternatively setting some portions of the lower boundary of the system as isothermal (heated) or adiabatic surfaces, the interplay of forced and buoyancy convection is investigated numerically for a fixed expansion ratio (ER=2) and a variety of conditions corresponding to extended intervals of the Rayleigh number Ra and several values of the Richardson number Ri (Ra >= O(10(4)) and Ri >= O(1)). It is shown that the emerging dynamics involve a variety of concurrent mechanisms, which range from the standard hydrodynamic phenomena typical of isothermal fluids, to specific effects of buoyant nature (driven by the instability of thermal boundary layers and the ensuing emergence of thermal plumes in various parts of the domain). Comparison with the equivalent forward facing step configuration indicates that, besides the differences, these two systems display interesting analogies. (C) 2022 The Authors. Published by Elsevier Ltd.

Automated summary

This study numerically investigates the unsteady mixed forced-buoyancy convection in a channel with a backward facing step. By setting some portions of the boundary as isothermal or adiabatic surfaces, the interplay of forced and buoyancy convection under different conditions is explored. The results reveal a variety of mechanisms involved in this interaction, ranging from standard hydrodynamic phenomena to buoyant effects.