Numerical investigation of vertical plunging jet using a hybrid multifluid-VOF multiphase CFD solver

Authors

Olabanji Y. Shonibare, Michigan Technological University
Kent E. Wardle, Argonne National Laboratory

Document Type

Article

Publication Date

1-1-2015

Abstract

© 2015 Olabanji Y. Shonibare and Kent E. Wardle. A novel hybrid multiphase flow solver has been used to conduct simulations of a vertical plunging liquid jet. This solver combines a multifluid methodology with selective interface sharpening to enable simulation of both the initial jet impingement and the long-time entrained bubble plume phenomena. Models are implemented for variable bubble size capturing and dynamic switching of interface sharpened regions to capture transitions between the initially fully segregated flow types into the dispersed bubbly flow regime. It was found that the solver was able to capture the salient features of the flow phenomena under study and areas for quantitative improvement have been explored and identified. In particular, a population balance approach is employed and detailed calibration of the underlying models with experimental data is required to enable quantitative prediction of bubble size and distribution to capture the transition between segregated and dispersed flow types with greater fidelity.

Publication Title

International Journal of Chemical Engineering

Recommended Citation

Shonibare, O., & Wardle, K. (2015). Numerical investigation of vertical plunging jet using a hybrid multifluid-VOF multiphase CFD solver. International Journal of Chemical Engineering, 2015. http://doi.org/10.1155/2015/925639
Retrieved from: https://digitalcommons.mtu.edu/michigantech-p/12694