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| | ==During planning== | | ==During planning== |
| − | A first step in considering placement of spawning gravel as a measure would be to assess if the total and distribution of spawning areas are limiting the development of fish population, i.e. diagnosis in the environmental design terminology. The spawning areas are often assessed by visual inspection of the river, i.e. by foot beside the river, by wading or from boat. Aerial photos can also in some cases assist this step. When the spawning areas are identified, they can be mapped in a GIS and the total area and their distribution assessed. For Atlantic salmon, spawning areas are considered being large if more than 10% of the total river has suitable spawning conditions, moderate if between 1-10% and small if less than 1% (Forseth & Harby, 2013). The distribution/spread is considered large if more than 500 meters between identified spawning areas, medium if between 200-500 meters, and small if less than 200 meters. These threshold values are considered indicative for Atlantic salmon, and will be different for other fish species. | + | A hydrologic analysis of flood events before and after regulation will also provide data to support the likelihood that reductions in flood frequencies have reduced, or may in the future reduce, long-term production by causing habitat deterioration. To what extent the habitat has been degraded, can be assessed by habitat mapping (Forseth and Harby 2014). |
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| − | <table style="height: 207px;" border="1" width="764">
| + | Some studies make a distinction between armoured and paved layers, related to the resistance of surface layers to floods, e.g. less than 10 years for armour, more than 100 years for pavement. The break-up of the armour layer has been observed for floods with a recurrence interval of at least 7 to 10 years. When the break-up of the armour layer occurs, there is a significant increase in the bedload discharge. |
| − | <tr style="height: 13px;">
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| − | <td style="height: 13px; width: 264px;"> </td>
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| − | <td style="height: 13px; width: 121px;"><strong> </strong></td>
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| − | <td style="height: 13px; width: 357px; text-align: center; vertical-align: middle;" colspan="3">
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| − | <p><strong>Extent of spawning habitat as a percentage of river area</strong></p>
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| − | </td>
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| − | </tr>
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| − | <tr style="height: 15px;">
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| − | <td style="height: 15px; width: 264px;"> </td>
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| − | <td style="height: 15px; width: 121px;"> </td>
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| − | <td style="text-align: center; vertical-align: middle; height: 15px; width: 103px;">
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| − | <p>Small (<1%)</p>
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| − | </td>
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| − | <td style="text-align: center; vertical-align: middle; height: 15px; width: 129px;">Moderate (1-10%)</td>
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| − | <td style="text-align: center; vertical-align: middle; height: 15px; width: 113px;">Large (>10%)</td>
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| − | </tr>
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| − | <tr style="height: 20px;">
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| − | <td style="height: 46px; width: 264px; text-align: center; vertical-align: middle;" rowspan="3"><strong>Distance between spawning habitats (across all segments)</strong></td>
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| − | <td style="text-align: center; vertical-align: middle; height: 20px; width: 121px;">
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| − | <p>Large (>500m)</p>
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| − | </td>
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| − | <td style="text-align: center; vertical-align: middle; height: 20px; width: 103px;">Small</td>
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| − | <td style="text-align: center; vertical-align: middle; height: 20px; width: 129px;">Small</td>
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| − | <td style="text-align: center; vertical-align: middle; height: 20px; width: 113px;">Moderate</td>
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| − | </tr>
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| − | <tr style="height: 13px;">
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| − | <td style="text-align: center; vertical-align: middle; height: 13px; width: 121px;">Medium (200-500m)</td>
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| − | <td style="text-align: center; vertical-align: middle; height: 13px; width: 103px;">Small</td>
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| − | <td style="text-align: center; vertical-align: middle; height: 13px; width: 129px;">Moderate</td>
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| − | <td style="text-align: center; vertical-align: middle; height: 13px; width: 113px;">
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| − | <p>Large</p>
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| − | </td>
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| − | </tr>
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| − | <tr style="height: 13px;">
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| − | <td style="text-align: center; vertical-align: middle; height: 13px; width: 121px;">Small (<200m)</td>
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| − | <td style="text-align: center; vertical-align: middle; height: 13px; width: 103px;">Moderate</td>
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| − | <td style="text-align: center; vertical-align: middle; height: 13px; width: 129px;">Large</td>
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| − | <td style="text-align: center; vertical-align: middle; height: 13px; width: 113px;">
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| − | <p>Large</p>
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| − | </td>
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| − | </tr>
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| − | </table>
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| − | Hydraulic analysis can support the identification of the best location to place the spawning gravel, in order to meet the preferences of the fish of concern, avoid locations with too slow-flowing water and areas exposed to flushing during high flow conditions.
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| − | A high number of hydro-dynamic tools are available for such analysis with different functionality and data needs, ranging from more simplistic 1-dimensional (1D) hydraulic tools, to highly advanced 3-dimensional (3D) tools solving a range of partial differential equations (Navier-Stokes) in all directions. The all require details description of the bottom topography of the areas the gravel might be placed, and a flow regime the river will undergo. As average flow velocities will not be sufficiently detailed to identify the best locations, 2D- or 3D models will be required. Examples of such models are [[River2D]], HEC-RAS 2D, Flow2D/3D, [[Mike21]] and [[OpenFoam]].
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| | ==During implementation== | | ==During implementation== |
| − | The implementation of the measure would require access to substrate of suitable grain size distribution, shape and of proper mineral composition, preferably similar to the substrate naturally present in spawning areas. In order to transport and place the new material at the right locations in the river, heavy machinery such as dumpers and tractors would be needed. In case where the site is difficult to access, use of helicopters can be the best option. The dumping of the substrate in the river would normally require supervision of a biologist, hydraulician or another experienced person in order to secure the right positioning of the substrate, proper thickness of substrate layer and finish of the surface preparation.
| + | Hydropower operators must normally document that environmental restrictions are followed, and they would have standard monitoring systems (gauging stations) in place. The improvements in the substrate composition and habitat conditions can be measured by for instance measuring the interstitial space. |
| − | | |
| − | The construction work will often require use of heavy machinery. Depending on the location of the river and how accessible it is and the costs, the transport of gravel will typically be made by dumper or by helicopter. If helicopter is used, the gravel can normally be dumped directly into the river, under the supervision of a biologist or another experienced person. If the new material is transported into the site by dumpers, an excavator will normally be needed at the site. This will also require the presence of an experienced person in order to ensure the correct placement and thickness of the gravel.
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| − | | |
| − | The implementation of the measures, i.e. dumping of the gravel, should be made in a time of the year where the fish population of the concern, and the rest of the ecosystem in the river will be least affected by the construction work. This will be individual to the different rivers and species. In addition, the hydrology of the river must be taken into consideration as it is clearly easier to carry out the work during low-flow conditions than during floods. For Scandinavia and species like salmon and trout, the period from July to September is probably the least problematic.
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| − | ==During operation==
| + | Shelter for juvenile salmonids can be measured with a simple method where the number and depth of interstitial species within a given area is counted with use of a rubber tube (Finstad et al. 2009). The number of spaces of varying length are weighed according to their depth and then summed. The number of interstitial spaces within an area of 50 cm * 50 cm, limited by e.g. a steel-frame (Figure 4-5), is counted and the depth registered. The sizes of interstitial spaces are determined based on how far down between the rocks the hose can be inserted. |
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| − | Habitat measures in regulated rivers must often be maintained unless the natural functions related to flow and sediments are restored, such as flood events and connectivity of the sediments. How often the maintenance must be made will differ from river to river and can vary from for instance every 5 years to every 20 years. Rivers with intense growth of moss, algae and macrophytes would need more frequent maintenance than rivers with cold water and low nutrient concentrations (less growth).
| + | The effect of the released environmental flow must be done by assessing the development of the fish population, e.g. by monitoring juvenile fish densities, number of smolts, etc. |
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| | =Classification Table= | | =Classification Table= |
Introduction
Figure 1: The disappearance of floods in Orkla in mid-Norway due to the river regulation. The blue graph is the observed low before regulation, while the orange is the flow after regulation. Note that the data series are shown for different time periods.
Reservoir-based hydropower will normally lead to a dramatic reduction in floods, unless the flood occurs when the reservoir is more or less filled, or the reservoir is small compared to the inflow. Some reservoirs are built for this purpose, i.e. flood protection. The ecological function of floods to the river system will then also disappear. The reduced frequency of flooding events may result in a deterioration of habitat quality, both by the silting of spawning habitats and the clogging of sheltered habitats. Floods act as 'habitat fresheners' as they remobilise the river bed material, if the floods are sufficiently large and flush out finer sediment fractions. In later sections of this document, habitat measures to refresh the substrate have been described, which will reinstate the natural substrate conditions and improve the habitat. Reinstating floods is one way of refreshing the substrate with use of the flow.
Floods can also have other ecological functions, for instance to facilitate migration and to attract fish for spawning. These floods (freshets) are typically smaller than the natural, annual flood, but the river regulation can also reduce these floods. Such freshets are usually named attraction flow to initiate upstream migration and trigger flow to initiate downstream migration. These floods can also be reinstated, and similar to floods to remobilise the substrate, the magnitude, timing and frequency of these should be when the ecological function is maximised, and the losses in power production minimised.
During planning
A hydrologic analysis of flood events before and after regulation will also provide data to support the likelihood that reductions in flood frequencies have reduced, or may in the future reduce, long-term production by causing habitat deterioration. To what extent the habitat has been degraded, can be assessed by habitat mapping (Forseth and Harby 2014).
Some studies make a distinction between armoured and paved layers, related to the resistance of surface layers to floods, e.g. less than 10 years for armour, more than 100 years for pavement. The break-up of the armour layer has been observed for floods with a recurrence interval of at least 7 to 10 years. When the break-up of the armour layer occurs, there is a significant increase in the bedload discharge.
During implementation
Hydropower operators must normally document that environmental restrictions are followed, and they would have standard monitoring systems (gauging stations) in place. The improvements in the substrate composition and habitat conditions can be measured by for instance measuring the interstitial space.
Shelter for juvenile salmonids can be measured with a simple method where the number and depth of interstitial species within a given area is counted with use of a rubber tube (Finstad et al. 2009). The number of spaces of varying length are weighed according to their depth and then summed. The number of interstitial spaces within an area of 50 cm * 50 cm, limited by e.g. a steel-frame (Figure 4-5), is counted and the depth registered. The sizes of interstitial spaces are determined based on how far down between the rocks the hose can be inserted.
The effect of the released environmental flow must be done by assessing the development of the fish population, e.g. by monitoring juvenile fish densities, number of smolts, etc.
Classification Table
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Assessment criteria
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Assessment
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Fish species measure designed for
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Atlantic salmon (salmo salar)
Trout (salmo trutta)
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Which life-stage of fish is measure aimed at?
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Spawning
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Which physical parameter mitigated?
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Substrate
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Section in the regulated system measure designed for
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Bypass section
Upstream of hydropower plant
Downstream outlet
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River type implemented in
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Gravel-bed rivers
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Climatic region suitable for
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C: Temperate (mesothermal) climates
D: Continental (microthermal) climates
E: Polar and alpine (montane) climates
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Level of certainty in effect
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Very certain
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Technology readiness level (maturity)
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TRL9: actual system proven in operational environment (competitive manufacturing in the case of key enabling technologies; or in space)
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