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Numerical simulation of turbid-density current using v2̄ - f turbulence model

Mehdizadeh, A ; Sharif University of Technology | 2005

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  1. Type of Document: Article
  2. DOI: 10.1115/IMECE2005-80263
  3. Publisher: 2005
  4. Abstract:
  5. The deposition behavior of fine sediment is an important phenomenon, and yet unclear to engineers concerned about reservoir sedimentation. An elliptic relaxation turbulence model (v2̄ - f model) has been used to simulate the motion of turbid density currents laden whit fine solid particles. During the last few years, the v2̄ - f turbulence model has become increasingly popular due to its ability to account for near-wall damping without use of damping functions. In addition, it has been proved that the v2̄ - f model to be superior to other RANS methods in many fluid flows where complex flow features are present. Due to low Reynolds number turbulence of turbidity current,(its critical Reynolds no. is about 1000), the k - ε model, which was standardized for high Reynolds number and isotropic turbulence flow, cannot simulate the anisotropy and non-homogenous behavior near wall. In this study, turbidity current with uniform velocity and concentration enters the channel via a sluice gate into a lighter ambient fluid and moves forward down-slope. The model has been verified with experimental data sets. Moreover, results have been compared with the standard k - ε turbulent model. Results show that the k - ε model has the poor result on this current. In addition, results show that the coarse particles settle down rapidly and make the higher deposition rate. The deposition of particles and the effects of their fall velocity on concentration distribution, height of body, and entrainment coefficient are also investigated. Copyright © 2005 by ASME
  6. Keywords:
  7. Coarse particles ; Density currents ; Reservoir sedimentation ; Turbulence model ; Computer simulation ; Current density ; Damping ; Mathematical models ; Reynolds number ; Turbidity ; Turbulence ; Velocity measurement ; Turbulent flow
  8. Source: 2005 ASME International Mechanical Engineering Congress and Exposition, IMECE 2005, Orlando, FL, 5 November 2005 through 11 November 2005 ; Volume 261 FED , 2005 , Pages 619-627 ; 08888116 (ISSN); 0791842193 (ISBN); 9780791842195 (ISBN)
  9. URL: https://asmedigitalcollection-asme-org.ezp2.semantak.ir/IMECE/proceedings/IMECE2005/42193/619/312233