CMS-Flow:Variable D50: Difference between revisions

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= Overview =
The standard sediment transport model in CMS is a single-size sediment transport model. This means that only one grain size can be simulated (one transport equation). In many cases the bed material is dominated by a single sediment size with patches of other sediment sizes or materials (e.g. shell hash), which do not contribute significantly to morphology change at specific regions, but do modify the sediment transport through hiding and exposure. In CMS, the spatially variable D50 dataset is used in calculating a hiding and exposure correction to the critical bed shear stress. By assuming that the spatial distribution of the bed material composition is constant in time, the hiding and exposure can be included in a single-sized sediment transport model (Sanchez and Wu 2011). CMS V4.0 has the option to simulate multiple-sized (noncohesive) sediment transport in which the D50 dataset can be used to construct an initial bed grain size distribution at every cell and bed layer. For more information on using the multiple-sized sediment transport option in CMS click [[CMS-Flow_Multiple-sized_Sediment_Transport | here]].


= Hiding and Exposure Correction =
The correction function for the critical shields parameter is defined as
{{Equation|<math> \theta_{ck} = \xi_k \theta_{c50} </math>|2=1}}


The current release version of CMS-Flow (v3.75) is a single-size sediment transport model. In this model, the spatially variable D50 dataset is used in calculating a hiding and exposure correction to the critical bed shear stress. Future versions of CMS will include multiple-sized sediment transport in which the variable D50 will be used to estimate an initial grain size distribution and solve discrete number of sediment size classes and include bed sorting and gradation.
where <math> \xi_k </math>  is the dimensionless hiding and exposure function, <math>\theta_{c50}</math> is the critical Shields parameter of the median sediment grain size <math>d_{50}</math> and <math>\theta_{ck}</math> is the critical Shields parameter for the transport grain size <math>d_{k}</math>. In CMS a formula similar to that of Parker et al. (1982) and others is used given by 
{{Equation|<math> \xi_k = (d_k/d_{50})^{-m} </math>|2=2}}


In many cases the bed material is dominated by a single sediment size with patches of other sediment sizes or materials (e.g. shell hash), which do not contribute significantly to morphology change at specific regions, but do modify the sediment transport through hiding and exposure. By assuming that the spatial distribution of the bed material composition is constant in time, the hiding and exposure can be included in a single-sized sediment transport model. This is done by means of a correction function for the critical shields parameter
where <math>m</math> is an empirical hiding and exposure coefficient. The transport grain size is the grain size which is transported and solved in by the advection diffussion equation. The sediment fall velocity is calculated with the transport grain while the skin friction and critical bed shear stress are calculated with <math>d_{50}</math>.
<math>\theta_{ck} = \xi_k \theta_{c50}</math>


where <math> \xi_k </math>  is the dimensionless hiding and exposure function, <math>\theta_{c50}</math> is the critical Shields parameter of the median sediment grain size <math>d_{50}</math> and <math>\theta_{ck}</math> is the critical Shields parameter for the transport grain size <math>d_{k}</math>. In CMS a formula similar to that of Parker et al. (1995) and others is used given by  <math>\xi_k = (d_k/d_{50})^{-m}</math>, where <math>m</math> is an empirical hiding and exposure coefficient.
= References =
* Parker, G., Klingeman, P.C., and McLean, D.G. (1982). "Bed load and size distribution in paved gravel-bed streams", Journal of the Hydraulic Division, 108(4), 544-571.
 
* Sánchez, A., and Wu, W. (2011). "A Non-equilibrium Sediment Transport  Model for Coastal Inlet Applications", Journal of Coastal Research, [In  Press]  [http://cirp.usace.army.mil/pubs/pdf/JCR_NCK_Symposium-Sanchez.pdf PDF]
 
 
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[[CMS#Documentation_Portal | Documentation Portal]]

Latest revision as of 20:08, 21 January 2011

Overview

The standard sediment transport model in CMS is a single-size sediment transport model. This means that only one grain size can be simulated (one transport equation). In many cases the bed material is dominated by a single sediment size with patches of other sediment sizes or materials (e.g. shell hash), which do not contribute significantly to morphology change at specific regions, but do modify the sediment transport through hiding and exposure. In CMS, the spatially variable D50 dataset is used in calculating a hiding and exposure correction to the critical bed shear stress. By assuming that the spatial distribution of the bed material composition is constant in time, the hiding and exposure can be included in a single-sized sediment transport model (Sanchez and Wu 2011). CMS V4.0 has the option to simulate multiple-sized (noncohesive) sediment transport in which the D50 dataset can be used to construct an initial bed grain size distribution at every cell and bed layer. For more information on using the multiple-sized sediment transport option in CMS click here.

Hiding and Exposure Correction

The correction function for the critical shields parameter is defined as

  (1)

where is the dimensionless hiding and exposure function, is the critical Shields parameter of the median sediment grain size and is the critical Shields parameter for the transport grain size . In CMS a formula similar to that of Parker et al. (1982) and others is used given by

  (2)

where is an empirical hiding and exposure coefficient. The transport grain size is the grain size which is transported and solved in by the advection diffussion equation. The sediment fall velocity is calculated with the transport grain while the skin friction and critical bed shear stress are calculated with .

References

  • Parker, G., Klingeman, P.C., and McLean, D.G. (1982). "Bed load and size distribution in paved gravel-bed streams", Journal of the Hydraulic Division, 108(4), 544-571.
  • Sánchez, A., and Wu, W. (2011). "A Non-equilibrium Sediment Transport Model for Coastal Inlet Applications", Journal of Coastal Research, [In Press] PDF



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