An experimental study of the hydraulic characteristics beneath a partial ice cover

Peters, Mitchel

11 January 2016

While many studies have been conducted in channels that are fully open or entirely covered with ice, little has been examined in channels with border ice. To begin filling in this gap in knowledge, experiments were conducted in the Hydraulics Research Testing Facility at the University of Manitoba in a 1.2m wide, 14m long flume to assess the impact of Froude number, coverage ratio and bed-to-ice roughness ratio on the hydraulic characteristics of channels with border ice cover. Acoustic Doppler velocimetry was used to collect detailed 3D velocity data over a cross section of the flume which facilitated the analysis of velocity and turbulence intensity fields as well as the shear stress distribution. The data collected thus far represents the most complete experimental dataset of measured water velocities in a channel with a border ice cover. / February 2016

Border ice

Hydraulics

Velocity distribution

Turbulence intensity

Shear stress

2-D modeling of freeze-up processes on the Athabasca River downstream of Fort McMurray, Alberta

Wojtowicz, Agata

Unknown Date

No description available.

2-D model

Athabasca River

Fort McMurray

freeze-up

ice regime

ice cover

CRISSP2D

River2D

bridging

border ice

2-D modeling of freeze-up processes on the Athabasca River downstream of Fort McMurray, Alberta

Wojtowicz, Agata

06 1900

This study is part of a three year project aimed to assess the effects of industrial water withdrawals on the ice regime of the Athabasca River. A 2-D numerical model was used to provide quantitative data for this effort. Freeze-up monitoring was carried out over two years along 80-km of the river from Fort McMurray to Bitumount. Summer bathymetric and winter ice surveys were conducted along with discharge measurements on a 5-km long detailed study reach that exhibited the full range of ice cover initiation processes. The data collected was used to build a CRISSP2D river ice process model for the simulation of freeze-up processes. An extensive parametric assessment was carried out to evaluate the capabilities of the model. Although it was not possible to simulate bridging, the simulated border ice agreed very well with field observations. Limitations of the model are addressed and future research recommendations are included. / Water Resources Engineering

2-D model

Athabasca River

Fort McMurray

freeze-up

ice regime

ice cover

CRISSP2D

River2D

bridging

border ice