ASDSO Dam Safety Toolbox

Erosion & Scour Mitigation: Difference between revisions

From ASDSO Dam Safety Toolbox
Jump to: navigation, search
No edit summary
No edit summary
Line 21: Line 21:
“'''Scour''' – The enlargement of a flow section by the removal of boundary material through the action of fluid motion during a single discharge event. The result of the scouring action may or may not be evident after the passing of the flood event”.<ref name ="USBR">[[Computing Degradation and Local Scour | Computing Degradation and Local Scour, USBR, 1984]]</ref>  
“'''Scour''' – The enlargement of a flow section by the removal of boundary material through the action of fluid motion during a single discharge event. The result of the scouring action may or may not be evident after the passing of the flood event”.<ref name ="USBR">[[Computing Degradation and Local Scour | Computing Degradation and Local Scour, USBR, 1984]]</ref>  


“The two basic factors influencing the extent of degradation in a stream channel are: (1) hydraulic properties including river channel velocities, hydraulic gradient or slope, and depth so flow associated with peak discharges and throughout the range in discharges, and (2) particle size distribution of sediments in the channel bed and banks. A careful evaluation of these factors is essential to any degradation analysis. One additional factor is the combination of streambed and valley controls which may exist in the channel reach subject to degradation. The controls may be rock outcrops, cobbles and boulders in the channel, vegetation growing along the banks, or manmade structures which act to control water levels and retard degradation processes. A control in the channel may in some cases prevent any appreciable degradation from occurring above it. Conversely, a change or removal of an existing control may initiate the degradation process”. <ref name ="USBR"></ref>
“The two basic factors influencing the extent of degradation in a stream channel are: (1) hydraulic properties including river channel velocities, hydraulic gradient or slope, and depth of flow associated with peak discharges and throughout the range in discharges, and (2) particle size distribution of sediments in the channel bed and banks. A careful evaluation of these factors is essential to any degradation analysis. One additional factor is the combination of streambed and valley controls which may exist in the channel reach subject to degradation. The controls may be rock outcrops, cobbles and boulders in the channel, vegetation growing along the banks, or manmade structures which act to control water levels and retard degradation processes. A control in the channel may in some cases prevent any appreciable degradation from occurring above it. Conversely, a change or removal of an existing control may initiate the degradation process”. <ref name ="USBR"></ref>


“Before undertaking any degradation study below a dam, an evaluation is needed of the degree of detail required to complete the study, of the appropriate design data for the dam, and of the future [[environmental]] conditions below the dam." <ref name ="USBR"></ref>
“Before undertaking any degradation study below a dam, an evaluation is needed of the degree of detail required to complete the study, of the appropriate design data for the dam, and of the future [[environmental]] conditions below the dam." <ref name ="USBR"></ref>

Revision as of 22:58, 13 December 2022


Bridge scour at a cylindrical support (USGS, 2016)

Degradation – The long-term process by which streambeds and floodplains are lowered in elevation due to the removal of material from the boundary by flowing water.

Aggradation – The long-term process by which streambeds and floodplains are raised in elevation due to the deposition of material eroded and transported from other areas.

Scour – The enlargement of a flow section by the removal of boundary material through the action of fluid motion during a single discharge event. The result of the scouring action may or may not be evident after the passing of the flood event”.[1]

“The two basic factors influencing the extent of degradation in a stream channel are: (1) hydraulic properties including river channel velocities, hydraulic gradient or slope, and depth of flow associated with peak discharges and throughout the range in discharges, and (2) particle size distribution of sediments in the channel bed and banks. A careful evaluation of these factors is essential to any degradation analysis. One additional factor is the combination of streambed and valley controls which may exist in the channel reach subject to degradation. The controls may be rock outcrops, cobbles and boulders in the channel, vegetation growing along the banks, or manmade structures which act to control water levels and retard degradation processes. A control in the channel may in some cases prevent any appreciable degradation from occurring above it. Conversely, a change or removal of an existing control may initiate the degradation process”. [1]

“Before undertaking any degradation study below a dam, an evaluation is needed of the degree of detail required to complete the study, of the appropriate design data for the dam, and of the future environmental conditions below the dam." [1]

Best Practices Resources

Design Standards No. 13: Embankment Dams (Ch. 7: Riprap Slope Protection) (Bureau of Reclamation)

Design Standards No. 13: Embankment Dams (Ch. 17: Soil-Cement Slope Protection) (Bureau of Reclamation)

Hydraulic Design of Stilling Basins and Energy Dissipators (EM 25) (U.S. Army Corps of Engineers)

Trainings

On-Demand Webinar: Rock Scour Assessment for Dams, Spillways and other Water Conveyance Structures

On-Demand Webinar: Designing Slope Protection for Dams and Levees

On-Demand Webinar: Terminal Structures and Energy Dissipation at Outlet Works and Spillways



Citations:


Revision ID: 5492
Revision Date: 12/13/2022