Download
1 / 30
310 likes | 589 Views
2. Problem. Bars are essentially passive in current meandering models and they therefore the models cannot be used to predict channel response to changes in discharge or sediment supplyCreating meandering channels in the laboratory has proven difficult without strength channels braid, channels with
E N D
1. 1
2. 2 Problem Bars are essentially passive in current meandering models and they therefore the models cannot be used to predict channel response to changes in discharge or sediment supply
Creating meandering channels in the laboratory has proven difficult without strength channels braid, channels with cohesive materials stop migrating
Bank erosion occurs faster than bars can create new floodplain
Open chutes on the inside of bars are the locus for braiding
3. 3 Outline Experimental design and methods
Experiments on the necessary conditions for meandering
Experiments on bar morphology and sediment supply
Ongoing experiments at RFS
Experiments at OSL
What next
4. 4 Hypotheses If slope, discharge, and channel dimensions are appropriate (following Parker, 1977), gravel-bed meanders also require:
Bank strength to slow bank erosion to allow time for the bars to grow
Fine sediment (sand) to fill chutes and the downstream end of bars
Overbank flows to allow the bar to grow to the floodplain elevation
5. 5 Hypotheses If slope, discharge, and channel dimensions are appropriate (following Parker, 1977), gravel-bed meanders also require:
Bank strength to slow bank erosion to allow time for the bars to grow -
Provided by alfalfa sprouts
Fine sediment (sand) to fill chutes and the downstream end of bars Lightweight plastic sediment
Overbank flows to allow the bar to grow to the floodplain elevation - Test both a variable hydrograph and a steady hydrograph
6. 6 Experimental conditions Flume is 16.5 m long and 6.1 m wide
Basin slope = 0.0046
Basin filled with sand with a D50 of 0.85 mm
Initial channel geometry = 40 cm X 1.9 cm
Froude number = 0.55, Reynolds number = 4500
Feed sand (scaled gravel) and lightweight plastic (scaled sand)
7. 7 Measurements Coarse and fine feed fed independently
Discharge measured with a v-notch weir
Topography measured with laser-camera system
Overhead cameras record position every five minutes
Water surface profiles measured with point gauges (now using TiO2 and laser-camera system)
Velocity measured with both floats, dyes
Load cell to measure sediment flux at the downstream end (did not work in first experiment).
8. 8 The life cycle of alfalfa at RFS Seed flume with low flow on
Water by hand and with low flow until seeds germinate
After germination turn on grow lights-12-14 hours a day
From seed to sprout takes about one week
Alfalfa starts to die after about 20 hours of run time (over the course of about 3 days)
After the alfalfa dies, start over again
Building too cold in winter for alfalfa
9. 9 The experiment Consists of a 71 hour, variable peak hydrograph (1.8 + 2.7 l/s + early tests up to 4.5 l/s) and a 64 hour steady peak hydrograph (1.8 l/s)
The variable experiments used plastic feed with a median diameter of 350 microns and specific gravity=1.5
The steady flow experiments used plastic feed with a median diameter of 350 microns and specific gravity=1.3
Sprouts seeded at ~1.2 sprouts/cm2
Coarse feed turned off periodically to prevent aggradation at upstream end of the flume
10. 10 Time-lapse video
11. 11 Bars migrated both downstream and laterally
Curvature developed from upstream to downstream
Curvature redeveloped following cutoffs
The bend wavelength was about 14 channel widths
12. 12 Width stabilized after 40 hours
High flow tests caused channel width to increase
Sinuosity increased in first 50 hours, and reached a quasi-steady value
Meandering maintained during steady peak flow, but flow was overbank
13. 13 Sediment dynamics
14. 14 Close up of a bar
