CMS-Flow:Wind Pressure: Difference between revisions

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Wind

In CMS-Flow the wind shear stress is calculated as \begin{equation} \tag{1} \tau_{Wi} = \rho_a C_d |W| W_i \end{equation}

where $W$ is the 10-min average wind speed at a height of 10 m, $C_{d}$ is the drag coefficient, and $\rho _{a}$ is the atmospheric density (~1.2 kg/m^3).

The wind drag coefficient $C_{d}$ is calculated using the Hsu (1988)

\begin{equation} \tag{2} C_d = \biggl ( \frac{\kappa}{14.56 - 2 \ln W} \biggr ) ^2 \end{equation}

For measurements of wind speed made at heights other than 10 m, an approximation of the 10-m wind speed is (Shore Protection Manual 1984)

\begin{equation} \tag{3} W = W_z \biggl ( \frac{10}{z} \biggr )^{1/7} \end{equation}

Pressure

The atmospheric pressure is included in the momentum equations as an additional pressure gradient term \begin{equation} \tag{4} \frac{h}{\rho_0} \frac{\partial p_a }{\partial x_j} \end{equation}

Symbol Index

Symbol	Description	Units
$\tau _{W}$	Wind shear stress	Pa
$\rho _{a}$	Atmospheric density (~1.2 kg/m^3)	kg/m^3
$C_{d}$	Wind drag coefficient	none
$W$	10-min averaged wind speed at 10 m above the sea surface	m/sec
$\theta$	Wind direction	m/sec

References

Hsu, S.A. (1988) Coastal meteorology. Academic Press, San Diego, CA.

Shore Protection Manual (1984) 4th ed., 2nd Vol, U.S. Army Engineer Waterways Experiment Station, U.S. Government Printing Office, Washington, DC.

Documentation Portal

Retrieved from "https://cirpwiki.info/index.php?title=CMS-Flow:Wind_Pressure&oldid=7565"

@@ Line 2: / Line 2: @@
 == Wind ==
 In CMS-Flow the wind shear stress is calculated as
-       {{Equation| <math> \tau_{Wi} = \rho_a C_d |W| W_i </math> |2=1}}
+\begin{equation} \tag{1} \tau_{Wi} = \rho_a C_d |W| W_i \end{equation}
 where <math>W</math> is the 10-min average wind speed at a height of 10 m, <math>C_d</math> is the drag coefficient, and <math>\rho_a</math> is the atmospheric density (~1.2 kg/m^3).
@@ Line 8: / Line 8: @@
 The wind drag coefficient <math> C_d </math> is calculated using the Hsu (1988)
-      {{Equation| <math> C_d = \biggl ( \frac{\kappa}{14.56 - 2 \ln W} \biggr ) ^2 </math> |2=2}}
+\begin{equation} \tag{2} C_d = \biggl ( \frac{\kappa}{14.56 - 2 \ln W} \biggr ) ^2 \end{equation}
 For measurements of wind speed made at heights other than 10 m, an approximation of the 10-m wind speed is (Shore Protection Manual 1984)
-      {{Equation| <math> W = W_z \biggl ( \frac{10}{z} \biggr )^{1/7} </math> |2=3}}
+\begin{equation} \tag{3} W = W_z \biggl ( \frac{10}{z} \biggr )^{1/7} \end{equation}
 == Pressure ==
 The atmospheric pressure is included in the momentum equations as an additional pressure gradient term
-     {{Equation|  <math> \frac{h}{\rho_0} \frac{\partial p_a }{\partial x_j} </math> |2=4}}
+\begin{equation} \tag{4} \frac{h}{\rho_0} \frac{\partial p_a }{\partial x_j} \end{equation}
 == Symbol Index ==