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[[de: Information about the Vertical Velocity Profile]]
Author: [mailto:peter.schade@baw.de P. Schade]
==Information about the Vertical Velocity Profile==
==Information about the Vertical Velocity Profile==


This applet displays a vertical and logarithmical profile of current velocity in an infinitely wide channel.
This applet displays a vertical and logarithmical profile of current velocity in an infinitely wide [[channel]].
A watercolumn is divided into several horizontal layers. The applet calculates for each layer a horizontal velocity v which is a function of z, the height of each layer relative to the bottom.
A watercolumn is divided into several horizontal layers. The applet calculates for each layer a horizontal velocity v which is a function of z, the height of each layer relative to the bottom.


==Input measures==
==Input measures==
Bottom Gradient and Water Depth do not need any explanation.
Bottom [[Gradient]] and [[Water depth|Water Depth]] do not need any explanation.


* The Strickler Value defines the bottom shear stress. A higher value stands for a lower stress.
* The Strickler Value defines the bottom [[shear stress]]. A higher value stands for a lower stress.
:Examples:
:Examples:
:sand (Elbe and Weser Estuary): approx. 48 m**(1/3) s**(-1/2)
:sand (Elbe and Weser [[Estuary]]): approx. 48 m**(1/3) s**(-1/2)
:wild creek with rubble: approx. 20 m**(1/3) s**(-1/2)
:wild creek with rubble: approx. 20 m**(1/3) s**(-1/2)
* deltaZ: The watercolumn is divided into several horizontal layers. The user specifies the vertical distance between neighboured layers via the input field deltaZ. For a correct graphical display deltaZ should be smaller than the Log Law's Z0 value.
* deltaZ: The watercolumn is divided into several horizontal layers. The user specifies the vertical distance between neighboured layers via the input field deltaZ. For a correct graphical display deltaZ should be smaller than the Log Law's Z0 value.
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==Output measures==
==Output measures==


* In this model there is a layer directly above the bottom where the velocity is zero. Log Law's Z0 is the height of this layer. Log Law's Z0 depends on Water Depth and Strickler Value.
* In this [[model]] there is a layer directly above the bottom where the velocity is zero. Log Law's Z0 is the height of this layer. Log Law's Z0 depends on [[Water depth|Water Depth]] and Strickler Value.
* V(H) shows the velocity at the water surface.
* V(H) shows the velocity at the [[water surface]].
* V DepthAveraged stands for the depth-averaged velocity. The calculation of the average includes the layers with v=0 m/s as well as the layers with v>0 m/s. The calculation is more accurate by using smaller values of deltaZ.
* V DepthAveraged stands for the depth-averaged velocity. The calculation of the average includes the layers with v=0 m/s as well as the layers with v>0 m/s. The calculation is more accurate by using smaller values of deltaZ.
* The result field at the lower right corner of the applet displays a line with pairs (velocity v and height relative to the bottom z)
* The result field at the lower right corner of the applet displays a line with pairs (velocity v and height relative to the bottom z)
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Calculation of the horizontal velocity v
Calculation of the horizontal velocity v


v = sqrt(g * WaterDepth * BottomGradient) / Kappa * ln(z/z0)
* v = sqrt(g * WaterDepth * BottomGradient) / Kappa * ln(z/z0)


g = 9.81 m/s: gravity
* g = 9.81 m/s: gravity
Kappa = 0.41: Karman constant
* Kappa = 0.41: Karman constant
z0 : zero Level of the logarithmic law with
* z0 : zero Level of the logarithmic law with


z0 = (12./30.*WaterDepth) / 10**(StricklerValue * WaterDepth**(1/6) / 18))
* z0 = (12./30.*WaterDepth) / 10**(StricklerValue * WaterDepth**(1/6) / 18))


The user should consider that this profile is only an approximation. Especially near the bottom the formula simplifies a little bit.
The user should consider that this profile is only an approximation. Especially near the bottom the formula simplifies a little bit.
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back to [[Vertical Velocity Profile|Applet]]
----
[[Overview]]

Latest revision as of 09:30, 21 October 2022

Author: P. Schade

Information about the Vertical Velocity Profile

This applet displays a vertical and logarithmical profile of current velocity in an infinitely wide channel. A watercolumn is divided into several horizontal layers. The applet calculates for each layer a horizontal velocity v which is a function of z, the height of each layer relative to the bottom.

Input measures

Bottom Gradient and Water Depth do not need any explanation.

  • The Strickler Value defines the bottom shear stress. A higher value stands for a lower stress.
Examples:
sand (Elbe and Weser Estuary): approx. 48 m**(1/3) s**(-1/2)
wild creek with rubble: approx. 20 m**(1/3) s**(-1/2)
  • deltaZ: The watercolumn is divided into several horizontal layers. The user specifies the vertical distance between neighboured layers via the input field deltaZ. For a correct graphical display deltaZ should be smaller than the Log Law's Z0 value.

Output measures

  • In this model there is a layer directly above the bottom where the velocity is zero. Log Law's Z0 is the height of this layer. Log Law's Z0 depends on Water Depth and Strickler Value.
  • V(H) shows the velocity at the water surface.
  • V DepthAveraged stands for the depth-averaged velocity. The calculation of the average includes the layers with v=0 m/s as well as the layers with v>0 m/s. The calculation is more accurate by using smaller values of deltaZ.
  • The result field at the lower right corner of the applet displays a line with pairs (velocity v and height relative to the bottom z)

Physics

Calculation of the horizontal velocity v

  • v = sqrt(g * WaterDepth * BottomGradient) / Kappa * ln(z/z0)
  • g = 9.81 m/s: gravity
  • Kappa = 0.41: Karman constant
  • z0 : zero Level of the logarithmic law with
  • z0 = (12./30.*WaterDepth) / 10**(StricklerValue * WaterDepth**(1/6) / 18))

The user should consider that this profile is only an approximation. Especially near the bottom the formula simplifies a little bit.


back to Applet


Overview