Sediment Transport: Difference between revisions
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{{Equation|<math> A_{cR} = 3.5x10^3 \exp{ \bigl( - 0.3 d_{*} } \bigr) </math>|2=4}} | {{Equation|<math> A_{cR} = 3.5x10^3 \exp{ \bigl( - 0.3 d_{*} } \bigr) </math>|2=4}} | ||
with <math> d_{*} = \sqrt{(s-1) g \nu^{-2}} | with <math> d_{*} = d \sqrt{(s-1) g \nu^{-2}} </math> being the dimensionless grain size and <math> \nu </math> the kinematic viscosity of water. | ||
The sediment mixing coefficient is calculated as | The sediment mixing coefficient is calculated as | ||
Revision as of 21:57, 15 October 2010
Lund-CIRP Transport Equations
Camenen and Larson (2005, 2007, and 2008) developed a general sediment transport formula for bed and suspended load under combined waves and currents.
Bed load
The current-related bed load transport with wave stirring is given by
| (1) |
Suspended load
The current-related suspended load transport with wave stirring is given by
| (2) |
![{\displaystyle {\frac {q_{s}}{\sqrt {(s-1)gd^{3}}}}=Uc_{R}{\frac {\epsilon }{w_{s}}}{\biggl [}1-\exp {{\biggl (}-{\frac {w_{s}d}{\epsilon }}}{\biggr )}{\biggr ]}}](https://en.wikipedia.org/api/rest_v1/media/math/render/svg/b9bca4dde04b4aead4577a94ddb5fcb9e0f6f090)
The reference sediment concentration is obtained from
| (3) |
where the coefficient is given by
| (4) |
with being the dimensionless grain size and the kinematic viscosity of water.
The sediment mixing coefficient is calculated as
| (5) |
| Symbol | Description | Units |
|---|---|---|
| Bed load transport rate | m3/s | |
| Relative density | m | |
| Shields parameter due to currents | - | |
| Shields parameter due to waves and currents | - | |
| Critical shields parameter | - | |
| Empirical coefficient | - | |
| Empirical coefficient | - |
