Sediment Transport: Difference between revisions

From CIRPwiki

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

\frac{q_{b}}{\sqrt{(s - 1) g d^{3}}} = a_{c} \sqrt{θ_{c}} θ_{c w} \exp (- b_{c} \frac{θ_{c r}}{θ_{c w}})

(1)

Suspended load

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

\frac{q_{s}}{\sqrt{(s - 1) g d^{3}}} = U c_{R} \frac{ϵ}{w_{s}} [1 - \exp (- \frac{w_{s} d}{ϵ})]

(2)

The reference sediment concentration is obtained from

c_{R} = A_{c R} \exp (- 4.5 \frac{θ_{c r}}{θ_{c w}})

(3)

where the coefficient $A_{c R}$ is given by

A_{c R} = 3.5 x 1 0^{3} \exp (- 0.3 d_{*})

(4)

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

The sediment mixing coefficient is calculated as

ϵ = h (\frac{k_{b}^{3} D_{b} + k_{c}^{3} D_{c} + k_{w}^{3} D_{w}}{ρ})^{1 / 3}

(5)

Symbol	Description	Units
$q_{b c}$	Bed load transport rate	m³/s
$s$	Relative density	m
$θ_{c}$	Shields parameter due to currents	-
$θ_{c w}$	Shields parameter due to waves and currents	-
$θ_{c w}$	Critical shields parameter	-
$a_{c}$	Empirical coefficient	-
$b_{c}$	Empirical coefficient	-

Retrieved from "https://cirpwiki.info/index.php?title=Sediment_Transport&oldid=3637"

@@ Line 20: / Line 20: @@
 The sediment mixing coefficient is calculated as
-{{Equation|<math> \epsilon = \biggl( \frac{k_b^3 D_b + k_c^3 D_c + k_w^3 D_w}{\rho} \biggr)  </math>|2=5}}
+{{Equation|<math> \epsilon = h \biggl( \frac{k_b^3 D_b + k_c^3 D_c + k_w^3 D_w}{\rho} \biggr)^{1/3}  </math>|2=5}}
 {| border="1"

Sediment Transport: Difference between revisions

Revision as of 21:57, 15 October 2010

Lund-CIRP Transport Equations

Bed load

Suspended load

Navigation menu

Search