Difference between revisions of "Effects of giving less space to the flow"

From REFORM wiki
Jump to: navigation, search
(Created page with "<Forecasterlink type="getToolInfoBox" code="32" /> =Effects of giving less space to the flow= ==Type== Diagrams of elementary morphological effects ==Rivertypes== <Forecaste...")
 
 
(2 intermediate revisions by the same user not shown)
Line 1: Line 1:
<Forecasterlink type="getToolInfoBox" code="32" />
+
==Description==
=Effects of giving less space to the flow=
+
[[File:Effect of less space for flow.png|300px|thumb]]
==Type==
+
The longitudinal profiles of Figures A to C visualize how less space for the flow affects the main channel of a river reach. The vertical scale is exaggerated with respect to the horizontal scale. The reach can be kilometres to tens of kilometres long.
Diagrams of elementary morphological effects
+
<br />
  
==Rivertypes==
+
The intervention implies essentially that less space is given to the river over a certain length (A). The immediate effect is an increase in water levels along the river (B). This increase is not uniform, but varies from place to place. As a consequence, flow velocities differ from place to place too. The water levels and flow velocities can be calculated using [[1D analytical models for gradually-varied flow]] or [[1D numerical hydrodynamic models]]. The variations in flow velocity and, hence, the variations in the capacity to transport sediment give rise to a pattern of initial erosion and sedimentation along the river (B) that can be calculated using [[1D analytical models for morphology on short time scales]] or [[1D numerical morphodynamic models]]. Sedimentation over a relatively long distance occurs upstream of the intervention, whereas punctuated local erosion occurs immediately downstream of the entrance of the modified part of the river. This erosion advances downstream as a rarefaction wave. Erosion occurs also further downstream, followed by punctuated local sedimentation immediately downstream of the exit of the modified part of the river.
 +
<br />
  
<Forecasterlink type="getRivertypesForTool" code="32"/>
+
Eventually, in the long run, the river reaches a new morphological equilibrium without further trends of erosion or sedimentation (C). Local and upstream bed and water levels have become lower than at the start of the intervention. This means that the response of the river bed is particularly complex upstream of the intervention: sedimentation on a short term but erosion on a long term.
 +
<br />
 +
 
 +
The longitudinal profiles in the diagrams provide a simplified picture. They do not include the response of channel width, bed sediment composition or vegetation. Nonetheless, they offer the key to understanding the relation between local pressures or measures and their effects far upstream and downstream.
 
==Related Pressures==
 
==Related Pressures==
  
Line 19: Line 23:
  
 
<Forecasterlink type="getBqeForTool" code="32" />
 
<Forecasterlink type="getBqeForTool" code="32" />
==Related Ecosystem goods and services==
 
 
<Forecasterlink type="getEgandsForTool" code="32" />
 
==Useful references==
 
  
==Other relevant information==
 
  
 
[[Category:Tools]][[Category:Diagrams of elementary morphological effects]]
 
[[Category:Tools]][[Category:Diagrams of elementary morphological effects]]

Latest revision as of 14:34, 11 December 2015

Description

Effect of less space for flow.png

The longitudinal profiles of Figures A to C visualize how less space for the flow affects the main channel of a river reach. The vertical scale is exaggerated with respect to the horizontal scale. The reach can be kilometres to tens of kilometres long.

The intervention implies essentially that less space is given to the river over a certain length (A). The immediate effect is an increase in water levels along the river (B). This increase is not uniform, but varies from place to place. As a consequence, flow velocities differ from place to place too. The water levels and flow velocities can be calculated using 1D analytical models for gradually-varied flow or 1D numerical hydrodynamic models. The variations in flow velocity and, hence, the variations in the capacity to transport sediment give rise to a pattern of initial erosion and sedimentation along the river (B) that can be calculated using 1D analytical models for morphology on short time scales or 1D numerical morphodynamic models. Sedimentation over a relatively long distance occurs upstream of the intervention, whereas punctuated local erosion occurs immediately downstream of the entrance of the modified part of the river. This erosion advances downstream as a rarefaction wave. Erosion occurs also further downstream, followed by punctuated local sedimentation immediately downstream of the exit of the modified part of the river.

Eventually, in the long run, the river reaches a new morphological equilibrium without further trends of erosion or sedimentation (C). Local and upstream bed and water levels have become lower than at the start of the intervention. This means that the response of the river bed is particularly complex upstream of the intervention: sedimentation on a short term but erosion on a long term.

The longitudinal profiles in the diagrams provide a simplified picture. They do not include the response of channel width, bed sediment composition or vegetation. Nonetheless, they offer the key to understanding the relation between local pressures or measures and their effects far upstream and downstream.

Related Pressures

Related Measures

Related Hymo quality elements

Related Biological quality elements

    No Biological Quality Elements apply to this tool.