CMS-Flow Hydrodnamics: Variable Definitions: Difference between revisions

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Latest revision as of 15:26, 18 February 2015

The instantaneous current velocity u_i is split into:

$u_{i}={\bar {u_{i}}}+{\tilde {u_{i}}}+u_{i}^{'}$

(1)

in which

{\bar {u_{i}}}

= current (wave-averaged) velocity [m/s]

{\tilde {u_{i}}}

= wave (oscillatory) velocity [m/s]with wave-average

{\bar {u_{i}}}=0

below the wave trough

u_{i}^{'}

= turbulent fluctuation [m/s] with ensemble average

\langle u_{i}^{'}\rangle

= 0 and wave average

{\bar {u_{i}^{'}}}

= 0

The wave-averaged total volume flux is defined as

$hV_{i}={\overline {{\int _{z_{b}}^{\eta }}{u_{i}dz}}}$

(2)

where

h

= wave-averaged water depth

h={\bar {\eta }}-z_{b}

(Figure 1) [m]

V_{i}

= total mean mass flux velocity or simply total flux velocity [m/s]

\eta

= instantaneous water level with respect to the Still Water Level (SWL) [m]

{\bar {\eta }}

= wave-averaged water surface elevation with respect to the SWL (Figure 2-1) [m]

z_{b}

= bed elevation with respect to the SWL (Figure 1) [m]

Figure 1. Vertical conventions used for the bed and mean water surface elevation.

The total flux velocity is also referred to as the mean transport velocity (Phillips 1977) and mass transport velocity (Mei 1983). The current volume flux is defined as

$hU_{i}=\int _{z_{b}}^{\bar {\eta }}{\bar {u_{i}}}dz$

(3)

where $U_{i}$ is the depth-averaged current velocity. Similarly, the wave volume flux is defined as by

$Q_{wi}=hU_{wi}={\overline {\int _{\eta _{t}}^{\eta }{\tilde {u_{i}}}dz}}$

(4)

where

U_{wi}

= depth-averaged wave flux velocity [m/s]

\eta _{t}

= wave trough elevation [m]

Therefore the total flux velocity may be written as

$V_{i}=U_{i}+U_{wi}$

(5)

References

Mei, C. 1989. The applied dynamics of ocean surface waves. New York: John Wiley.

Phillips, O. M. 1977. The dynamics of the upper ocean. (2nd Edition). Cambridge, England: Cambridge University Press.

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@@ Line 1: / Line 1: @@
 The instantaneous current velocity u<sub>i</sub>  is split into:
@@ Line 9: / Line 10: @@
 :<math>\bar{u_i}</math> = current (wave-averaged) velocity [m/s]
-:<math>\tilde{u_i}</math> =  wave (oscillatory) velocity with wave-average <math>\bar{\tilde{u_i}} = 0 [m/s]</math>
+:<math>\tilde{u_i}</math> =  wave (oscillatory) velocity [m/s]with wave-average <math>\bar{{u_i}} = 0</math> below the wave trough
-:<math>u_i^'</math> = turbulent fluctuation with ensemble average <math>\langle u_i^' \rangle</math> = 0 and wave average <math>\bar{u_i^'}</math> = 0 [m/s]
+:<math>u_i^'</math> = turbulent fluctuation [m/s] with ensemble average <math>\langle u_i^' \rangle</math> = 0 and wave average <math>\bar{u_i^'}</math> = 0
 The wave-averaged total volume flux is defined as
 {{Equation|
-<math> h V_i = \overline{{\int_z^\eta} {u_i dz }}</math>
+<math> h V_i = \overline{{\int_{z_b}^\eta} {u_i dz }}</math>
 |2}}
 where
-:<math>h</math> = wave-averaged water depth <math>h=\bar{\eta} - z_b </math> [m]
+:<math>h</math> = wave-averaged water depth <math>h=\bar{\eta} - z_b </math> (Figure 1) [m]
-:<math>V_i</math> = total mean mass flux velocity or simply total flux velocity for short [m/s]
+:<math>V_i</math> = total mean mass flux velocity or simply total flux velocity [m/s]
-:<math>u_i</math> = instantaneous current velocity [m/s]
+:<math>\eta</math> = instantaneous water level with respect to the Still Water Level (SWL) [m]
-:<math>\eta</math> = instantaneous water level with respect to the Still Water Level (SWL) [m]
+:<math>\bar{\eta}</math> = wave-averaged water surface elevation with respect to the SWL (Figure 2-1) [m]
+:<math>z_b</math>  = bed elevation with respect to the SWL (Figure 1) [m]
-:<math>z_b</math>  = bed elevation with respect to the SWL [m]
+<center>
+[[File:fig_2_1.png|400px]]
+'''Figure 1. Vertical conventions used for the bed and mean water surface elevation.'''
+</center>
 The total flux velocity is also referred to as the mean transport velocity (Phillips 1977) and mass transport velocity (Mei 1983). The current volume flux is defined as
 {{Equation|
-<math>hU_i = \int^\bar{\eta}_{z} \bar{u_i}dz</math>    (2-3)
+<math>hU_i = \int^\bar{\eta}_{z_b} \bar{u_i}dz</math>|3}}
-|3}}
 where <math>U_i</math> is the depth-averaged current velocity. Similarly, the wave volume flux is defined as by
 {{Equation|
-<math>Q_{wi} = hU_{wi} = \bar{\int \tilde{u_i} dz}</math>
+<math>Q_{wi} = hU_{wi} = \overline{\int_{\eta_t}^\eta \tilde{u_i} dz}</math>
 |4}}
-where <math>U_{wi}</math> is the depth-averaged wave flux velocity [m/s], and <math>\eta_t</math> = wave trough elevation [m]. Therefore the total flux velocity may be written as
+where
+:<math>U_{wi}</math> = depth-averaged wave flux velocity [m/s]
+:<math>\eta_t</math> = wave trough elevation [m]
+Therefore the total flux velocity may be written as
 {{Equation|
 <math>V_i = U_i + U_{wi}</math>
 |5}}
+=References=
+* Mei, C. 1989. The applied dynamics of ocean surface waves. New York: John Wiley.
+* Phillips, O. M. 1977. The dynamics of the upper ocean. (2nd Edition). Cambridge, England: Cambridge University Press.
 ----
 [[CMS#Documentation_Portal | Documentation Portal]]

CMS-Flow Hydrodnamics: Variable Definitions: Difference between revisions

Latest revision as of 15:26, 18 February 2015

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