Abstract
Wear due to sediment particles in fluid flows, also termed ‘hydroabrasion’ or simply ‘abrasion’, is an omnipresent issue at hydraulic structures as well as in bedrock rivers. However, interactions between flow field, particle motion, channel topography, material properties and abrasion have rarely been investigated on a prototype scale, leaving many open questions as to their quantitative interrelations. Therefore, we investigated hydroabrasion in a multi-year field study at two Swiss Sediment Bypass Tunnels (SBTs). Abrasion depths of various invert materials, hydraulics and sediment transport conditions were determined and used to compute the abrasion coefficients kv of different abrasion models for high-strength concrete and granite. The results reveal that these models are useful to estimate spatially averaged abrasion rates. The kv‑value is about one order of magnitude higher for granite than for high-strength concrete, hence, using material-specific abrasion coefficients enhances the prediction accuracy. Three-dimensional flow structures, i.e., secondary currents occurring both, in the straight and curved sections of the tunnels cause incision channels, while also longitudinally undulating abrasion patterns were observed. Furthermore, hydroabrasion concentrated along joints and protruding edges. The maximum abrasion depths were roughly twice the mean abrasion depths, irrespective of hydraulics, sediment transport conditions and invert material.
Highlights
Reservoir sedimentation is a phenomenon of increasing evidence both, in Alpine regions and worldwide
Sediment Bypass Tunnels (SBTs) and its modelling for fixed planar beds subjected to supercritical flows with high scale effects and the mechanistic saltation abrasion models are applicable to both, laboratory and bedload transport prototype scale. rates
Based on the obtained field data, a well-known mechanistic saltation abrasion model and itsofrecently modified versionoriginates were calibrated forfrom high-strength concretes
Summary
Reservoir sedimentation is a phenomenon of increasing evidence both, in Alpine regions and worldwide. This negatively affects the multifold purposes of reservoirs, e.g., water supply, irrigation, hydropower and flood protection. As the worldwide reservoir sedimentation volume exceeds the increase of reservoir capacity, the net storage capacity has been decreasing since about the turn of the millenium [1,2,3,4,5]. Sediment bypass tunnels (SBTs) are an effective countermeasure against reservoir sedimentation for small- to medium-sized reservoirs with high water availability, as e.g., typical in geologically young and erosive mountains, such as the Alps, Andes and Himalayas [8,9].
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