FLUME EXPERIMENTS

Experiments were conducted in a 6.05 × 0.61 × 0.61 m recirculating flume set at a fixed slope of 0.001 m/m. To simulate a bank toe, a 4.88 m long inclined insert was installed along one side of the flume immediately downstream of the flow straighteners. The bank toe was 0.45m wide for a 30° slope and 0.41 m wide for a 15° slope. Bank and artificial vegetation was scaled by a Froude scaling factor of 4.35 from a prototype streambank representing the toe of a compound bank.

MEASUREMENTS

In order to characterize the depth-averaged velocity , it was assumed that the von Kàrmàn-Prandtl law of the wall was valid and hence velocity was measured at ~0.6 × the flow depth (0.6d) at 7 cross-stream locations within the 9 cross-sections. Near-boundary velocity was measured at 7 or 9 cross-stream locations within 7 cross-sections. Velocities were measured over five minutes at 25 Hz with a 10 MHz Nortek acoustic Doppler velocimeter (ADV). Data were filtered and processed using the WinADV software.

Key variables:

q = angle of bank toe (°)
u, v and w = velocity vectors in the streamwise, lateral, and vertical directions (m/s)
P = cross-sectional area of plant (m²)
D = vegetation planform density (#/m)
Q = discharge (m³/s)

SAMPLING DESIGN

Vegetation was installed in two patterns: low density (D_lo) of 202 plants per m² and high density (D_hi) of 615 plants per m², which scale to 8 and 24 plants per m², respectively.

Vegetation was in two forms: low projected area (P_lo) and high projected area (P_hi). P_lo plants were made of 450 mm long, 4.54 mm diameter acrylic rods, scaled down from 2 m tall, 20 mm diameter woody stems. P_hi consisted of the same acrylic rods affixed with ten 28-gauge wire “branches” and ten 25 × 35 mm “leaves” made of contact paper (875 mm² total) spaced to reflect a pattern of projected area found by Wilson et al. (2006).

Fifteen experimental runs
were conducted
for each slope:

12 with vegetation

and

3 non-vegetated
control runs.

PRELIMINARY RESULTS

• Vegetation density (D) and projected area (P) are important to include when considering streambank hydraulics. Both D and P decrease streamwise velocity along the bank toe and increase velocity in the main channel. They also alter turbulence patterns across the channel.


• Plant form impacts turbulence, and thus erosion, along the bank toe. Findings from this study suggest P is more influential than D in increasing turbulence along the already vulnerable bank toe. Higher turbulence may increase erosion and promote channel widening. Therefore, once plants leaf out in the spring, the risk of erosion along the bank toe-channel margin may increase.


• Vegetation slows and redirects water. This result supports findings from previous research. However, an important finding of this study are observations of a change in flow direction as P increases. This suggests that after leaf out occurs, patterns of scour and deposition may change. Increases in D did not have the same influence.

Download a video of an artificial leaf caught in eddy downstream of the vegetation. (Right click and select Save Link As... if using Firefox)

Download a video of a high density, low projected area flume run. (Right click and select Save Link As... if using Firefox)

REFERENCES

Wilson, C. A. M. E., Yagci, O., Rauch, H.-P., and Stoesser, T. (2006). "Application of the drag force approach to model the flow-interaction of natural vegetation." Int. J. River Basin Mgmt., 4(2), 137-146.

PUBLICATIONS

Poster for Ecosystems Informatics IGERT Annual Meeting 2009, Oregon State University, Corvallis, OR, May 2009

Proceedings paper for the 33rd IAHR Congress, Vancouver, BC, August 2009

SUPPORT

NSF IGERT graduate fellowship (NSF award 0333257) in the Ecosystem Informatics IGERT program at Oregon State University

USDA-ARS National Sedimentation Laboratory at Oxford, Mississippi