Bottom Friction: Difference between revisions
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The bed friction coefficient c<sub>b</sub> is related to the Manning’s roughness coefficient ''<math>\eta</math>'' by (Graf and Altinakar 1998) | The bed friction coefficient c<sub>b</sub> is related to the Manning’s roughness coefficient ''<math>\eta</math>'' by (Graf and Altinakar 1998) | ||
''<math>c_b = \left(\frac{\kappa}{ln(z_0}/h + 1\right)} | ''<math>c_b = \left(\frac{\kappa}{ln(z_0}/h + 1 }\right)} |
Revision as of 19:40, 16 July 2014
Bottom Friction
The mean (short-wave averaged) bed shear stress, , is calculated as
(2-8)
where
nonlinear bottom friction enhancement factor [-]
current-related bed shear stress vector [Pa]
The current bed shear stress is given by
(2-9)
where
water density (~1025 kg/m3)
cb = bed friction coefficient [-]
current magnitude = [m/s]
The bottom roughness is specified with either a Manning's roughness coefficient , Nikuradse roughness height ks , or bed friction coefficient cb . It is important to note that the roughness value is held constant throughout the simulation and is not changed according to bed composition and bedforms. This is a common engineering approach which can be justified by the lack of data to initialize the bed composition, and the large error in estimating the bed composition evolution and bedforms. In addition using a constant bottom roughness simplifies the model calibration. In future versions of CMS, it option to automatically estimate the bed roughness from the bed composition and bedforms will be added.
The bed friction coefficient cb is related to the Manning’s roughness coefficient by (Graf and Altinakar 1998)
<math>c_b = \left(\frac{\kappa}{ln(z_0}/h + 1 }\right)}