Sediment Transport: Difference between revisions

Lund-CIRP

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

{\frac {q_{b}}{\sqrt {(s-1)gd^{3}}}}=a_{c}{\sqrt {\theta _{c}}}\theta _{cw}\exp {{\biggl (}-b_{c}{\frac {\theta _{cr}}{\theta _{cw}}}}{\biggr )}

(1)

Suspended load

The current-related suspended load transport with wave stirring is given by

{\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 ]}

(2)

The reference sediment concentration is obtained from

c_{R}=A_{cR}\exp {{\biggl (}-4.5{\frac {\theta _{cr}}{\theta _{cw}}}}{\biggr )}

(3)

where the coefficient $A_{cR}$ is given by

A_{cR}=3.5x10^{3}\exp {{\bigl (}-0.3d_{*}}{\bigr )}

(4)

with $d_{*}=d{\sqrt {(s-1)g\nu ^{-2}}}$ being the dimensionless grain size and $\nu$ the kinematic viscosity of water.

The sediment mixing coefficient is calculated as

\epsilon =h{\biggl (}{\frac {k_{b}^{3}D_{b}+k_{c}^{3}D_{c}+k_{w}^{3}D_{w}}{\rho }}{\biggr )}^{1/3}

(5)

van Rijn

Watanabe

The equilibrium total load sediment transport rate of Watanabe (1987) is given by

q_{t*}=A{\biggl [}{\frac {(\tau _{b,max}-\tau _{cr})U_{c}}{\rho g}}{\biggr ]}

(6)

where $\tau _{b,max}$ is the maximum shear stress, $\tau _{cr}$ is the critical shear stress of incipient motion, and $A$ is an empirical coefficient typically ranging from 0.1 to 2.

The critical shear stress is determined using

\tau _{cr}=(\rho _{s}-\rho )gd\phi _{cr}

(6)

In the case of currents only the bed shear stress is determined as $\tau _{c}={\frac {1}{8}}\rho gf_{c}U_{c}^{2}$ where $f_{c}$ is the current friction factor. The friction factor is calculated as $f_{c}=0.24log^{-2}(12h/k_{sd})$ where $k_{sd}$ is the Nikuradse equivalent sand roughness obtained from $k_{sd}=2.5d_{50}$ .

If waves are present, the maximum bed shear stress $\tau _{b,max}$ is calculated based on Soulsby (1997)

\tau _{max}={\sqrt {(\tau _{m}+\tau _{w}\cos {\phi })^{2}+(\tau _{w}\sin {\phi })^{2}}}

(6)

where $\tau _{m}$ is the mean shear stress by waves and current over a wave cycle, math> \tau_w </math> is the mean wave bed shear stress, and $\phi$ is the angle between the waves and the current. The mean wave and current bed shear stress is

\tau _{m}=\tau _{c}[1+1.2({\frac {\tau _{w}}{\tau _{c}+\tau _{c}}})^{3.2}]

(6)

The wave bed shear stress is given by $\tau _{w}={\frac {1}{2}}\rho gf_{w}U_{w}^{2}$ where $f_{w}$ is the wave friction factor, and $U_{w}$ is the wave orbital velocity amplitude based on the significant wave height.

The wave friction factor is calculated as (Nielsen 1992) $f_{w}=\exp {5.5(R^{-0.2}-6.3}$ where

Soulsby-van Rijn

The equilibrium sediment concentration is calculated as (Soulsby 1997)

C_{*}={\frac {A_{sb}+A_{ss}}{h}}{\biggl [}{\biggl (}U_{c}^{2}+0.018{\frac {U_{rms}^{2}}{C_{d}}}{\biggr )}^{0.5}-u_{cr}{\biggr ]}^{2.4}

(7)

Symbol	Description	Units
$q_{bc}$	Bed load transport rate	m³/s
$s$	Relative density	-
$\theta _{c}$	Shields parameter due to currents	-
$\theta _{cw}$	Shields parameter due to waves and currents	-
$\theta _{cw}$	Critical shields parameter	-
$a_{c}$	Empirical coefficient	-
$b_{c}$	Empirical coefficient	-
$U_{c}$	Current magnitude	m/s

References

Camenen, B., and Larson, M. (2005). "A bed load sediment transport formula for the nearshore," Estuarine, Coastal and Shelf Science, 63, 249-260.
Camenen, B., and Larson, M., (2008). "A General Formula for Non-Cohesive Suspended Sediment Transport," Journal of Coastal Research, 24(3), 615-627.
Soulsby, D.H. (1997). "Dynamics of marine sands. A manual for practical applications," Thomas Telford Publications, London, England, 249 p.
Watanabe, A. (1987). "3-dimensional numerical model of beach evolution," Proceedings Coastal Sediments '87, ASCE, 802-817.

@@ Line 36: / Line 36: @@
 In the case of currents only the bed shear stress is determined as <math> \tau_{c} = \frac{1}{8}\rho g f_c U_c^2 </math> where <math> f_c </math> is the current friction factor. The friction factor is calculated as <math> f_c = 0.24log^{-2}(12h/k_{sd}) </math> where <math> k_{sd} </math> is the Nikuradse equivalent sand roughness obtained from <math> k_{sd} = 2.5d_{50} </math>.
-If waves are present, the maximum bed shear stress \tau_{b,max} is calculated based on Soulsby (1997)
+If waves are present, the maximum bed shear stress <math>\tau_{b,max} </math> is calculated based on Soulsby (1997)
-{{Equation|<math> \tau_{max} = \sqrt{(\tau_m + \tau_w \cos{\phi})^2 } + (\tau_w \sin{\phi})^2</math>|2=6}}
+{{Equation|<math> \tau_{max} = \sqrt{(\tau_m + \tau_w \cos{\phi})^2  + (\tau_w \sin{\phi})^2 } </math>|2=6}}
+where <math> \tau_m </math> is the mean shear stress by waves and current over a wave cycle, math> \tau_w </math> is the mean wave bed shear stress, and <math> \phi </math> is the angle between the waves and the current. The mean wave and current bed shear stress is
+{{Equation|<math> \tau_{m} = \tau_c [1 + 1.2( \frac{\tau_w}{\tau_c + \tau_c} )^{3.2}] </math>|2=6}}
+The wave bed shear stress is given by <math> \tau_{w} = \frac{1}{2}\rho g f_w U_w^2 </math> where <math> f_w </math> is the wave friction factor, and <math> U_w </math> is the wave orbital velocity amplitude based on the significant wave height.
+The wave friction factor is calculated as (Nielsen 1992) <math>f_w = \exp{5.5(R^{-0.2}-6.3}</math> where
 == Soulsby-van Rijn ==

Sediment Transport: Difference between revisions

Revision as of 03:37, 16 January 2011

Lund-CIRP

Bed load

Suspended load

van Rijn

Watanabe

Soulsby-van Rijn

References

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Sediment Transport: Difference between revisions

Revision as of 03:37, 16 January 2011

Lund-CIRP

Bed load

Suspended load

van Rijn

Watanabe

Soulsby-van Rijn

References

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