CMS-Flow:Transport Formula
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
| math \frac{q_{b | ({{{2}}}) |
{\sqrt{(s-1)gd^3}} = a_c \sqrt{\theta_c} \theta_{cw}\exp{ \biggl ( -b_c \frac{\theta_{cr}}{\theta_{cw}}} \biggr ) /math|2=1}}
Suspended load
The current-related suspended load transport with wave stirring is given by
| math \frac{q_s}{\sqrt{ (s-1) g d^3 | ({{{2}}}) |
= U c_R \frac{\epsilon}{w_s} \biggl[ 1 - \exp{ \biggl( - \frac{w_s d}{\epsilon}} \biggr) \biggr] /math|2=2}}
The reference sediment concentration is obtained from
| {{{1}}} | ({{{2}}}) |
{\theta_{cw}}} \biggr) /math|2=3}}
where the coefficient mathA_{cR}/math is given by
| {{{1}}} | (4) |
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
| {{{1}}} | (5) |
van Rijn
Watanabe
The equilibrium total load sediment transport rate of Watanabe (1987) is given by
| {{{1}}} | (6) |
where math \tau_{b,max} /math is the maximum shear stress, math \tau_{cr} /math is the critical shear stress of incipient motion, and math A /math is an empirical coefficient typically ranging from 0.1 to 2.
The critical shear stress is determined using
| {{{1}}} | (6) |
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 math\tau_{b,max} /math is calculated based on Soulsby (1997)
| {{{1}}} | (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
| {{{1}}} | (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) mathf_w = \exp{5.5R^{-0.2}-6.3}/math where
where math R /math is the relative roughness defined as math R = A_w/k_{sd} /math and math A_w /math is semi-orbital excursion math A_w = U_w T / (2 \pi) /math.
Soulsby-van Rijn
The equilibrium sediment concentration is calculated as (Soulsby 1997)
| {{{1}}} | ({{{2}}}) |
{h} \biggl[ \biggl( U_c^2 + 0.018 \frac{U_{rms}^2}{C_d} \biggr)^{0.5} - u_{cr} \biggr]^{2.4} /math|2=7}}
| Symbol | Description | Units |
|---|---|---|
| math q_{bc} /math | Bed load transport rate | msup3/sup/s |
| math s /math | Relative density | - |
| math \theta_{c} /math | Shields parameter due to currents | - |
| math \theta_{cw} /math | Shields parameter due to waves and currents | - |
| math \theta_{cw}/math | Critical shields parameter | - |
| math a_c /math | Empirical coefficient | - |
| math b_c /math | Empirical coefficient | - |
| math U_c /math | 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. (2007). A unified sediment transport formulation for coastal inlet applications, ERDC/CHL-TR-06-7, US Army Engineer Research and Development Center, Coastal and Hydraulics Laboratory, Vicksburg, MS.
- 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.