Modèle numérique de clapage

Phase de chute

Authors

  • Isabelle Farout-Fréson Laboratoire ROBERVAL UMR CNRS 6253 Laboratoire d’Hydraulique Numérique, BP 20529, F-60205 Compiègne cedex
  • Emmanuel Lefrançois Laboratoire ROBERVAL UMR CNRS 6253 Laboratoire d’Hydraulique Numérique, BP 20529, F-60205 Compiègne cedex
  • Gouri Dhatt Laboratoire ROBERVAL UMR CNRS 6253 Laboratoire d’Hydraulique Numérique, BP 20529, F-60205 Compiègne cedex
  • Philippe Sergent Centre d’Etudes Techniques Maritimes et Fluviales 2 boulevard Gambetta BP 60039 F-60321 Compiègne cedex

DOI:

https://doi.org/10.13052/REMN.16.965-988

Keywords:

mixture, incompressible fluid, variable density, coupled system, hydrodynamics, sediment transport, non linear, settling velocity, dumping, dredged sediment

Abstract

We are interested here in the mixture composed of incompressible fluid and a certain mass of fluidised solid. The proposed model is based on the averaged form of the hydrodynamic biphasic equations, associated with a sediment transport equation with a specific numerical settling velocity sf w adapted for the dumped dredged material case. Both models (hydrodynamics and transport) are coupled considering the variation of density with a forward scheme. Calibrated on the convective descent on three experimental campaigns in canal of dumping of dredged materials, the model gives a very good agreement of convective descent with almost twenty experiments for materials 100% sand, 100% silt or mixture sand/silt without or with a horizontally ambient current (Villaret et al., 1997; Boutin 1999).

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Published

2007-08-16

How to Cite

Farout-Fréson, I. ., Lefrançois, E. ., Dhatt, G. ., & Sergent, P. . (2007). Modèle numérique de clapage: Phase de chute. European Journal of Computational Mechanics, 16(8), 965–988. https://doi.org/10.13052/REMN.16.965-988

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Original Article