Guinot, Vincent
Soares Frazao, Sandra
[UCL]
Delenne, Carole
Porosity-based shallow water models for the simulation of urban floods incorporate additional energy dissipation terms compared to the usual two-dimensional shallow water equations. These terms account for head losses stemming from building drag. They are usually modelled using turbulence-based equations of state (drag proportional to the squared velocity). However, refined numerical simulations of wave propagation in periodic urban layouts indicate that such drag models do not suffice to reproduce energy dissipation properly. Correct wave propagation speeds, energy dissipation rates and flow fields are obtained by incorporating a new type of source term, active only under transient situations involving positive waves. This source term does not take the form of an equation of state. It can be modelled as an artificial increase in water inertia. In this communication, an experimental validation of this source term model is presented by means of new dam-break flow experiments in idealized, periodic urban layouts. The experimental results validate both the existence and the proposed formulation of this new source term.
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Bibliographic reference |
Guinot, Vincent ; Soares Frazao, Sandra ; Delenne, Carole. Experimental validation of transient source term in porosity-based shallow water models.River Flow 2018 (Lyon-Villeubane, France, du 05/09/2018 au 07/09/2018). In: A. Paquier, Ni. Rivière, River Flow 2018 – Ninth International Conference on Fluvial Hydraulics, EDP Sciences2018, p. 8 pages |
Permanent URL |
http://hdl.handle.net/2078.1/203029 |