V51E-3073
Entrainment of Air into Vertical Jets in a Crosswind

Friday, 18 December 2015
Poster Hall (Moscone South)
Stephen Solovitz1, Karen K. Roberts1, Graham Freedland2, Elizabeth Camp2, Raul Bayoan Cal2 and Larry G Mastin3, (1)Washington State University Vancouver, Vancouver, WA, United States, (2)Portland State University, Portland, OR, United States, (3)USGS Cascades Volcano Observatory, Vancouver, WA, United States
Abstract:
During volcanic eruptions, ash concentration must be determined for aviation safety, but the limiting threshold is difficult to distinguish visually. Computational models are typically used to predict ash concentrations, using inputs such as plume height, eruptive duration, and wind speeds. The models also depend on empirical parameters, such as the entrainment of atmospheric air as a ratio of the air inflow speed and the jet speed. Entrainment of atmospheric air plays a critical role in the behavior of volcanic plumes in the atmosphere, impacting the mass flow rate, buoyancy, and particle concentration of the plume. This process is more complex in a crosswind, leading to greater uncertainty in the model results. To address these issues, a laboratory-scale study has been conducted to improve the entrainment models. Observations of a vertical, unconfined jet are performed using Particle Image Velocimetry, while varying jet density using different compressed gases and Reynolds number. To test the effects of a crosswind on plume entrainment rates, these are then compared with similar jet experiments in a wind tunnel. A series of jet geometries, jet speeds and tunnel speeds are considered. The measured velocities are used to determine the entrainment response, which can be used to determine ash concentration over time as atmospheric air is entrained into the plume. We also quantify the mean and the fluctuations in flow velocity.