Difference between revisions of "Bannwil test case"

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[[Category:Test cases]]
 
[[Category:Test cases]]
 
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{{Fact box for Bannwil}}
{| class="wikitable" style="width:250px; float:right;"
+
{{Relevant SMTDs for Bannwil}}
! colspan="2" style="text-align: center; background-color:#2cb4da; color:#ffffff;" |Relevant measures (demonstration purposes only)
 
|-
 
|[[Suitable measures::Mitigating reduced annual flow and low flow measures]]
 
|-
 
|[[Suitable measures::Mitigating reduced flood peaks, magnitudes, and frequency]]
 
|-
 
|[[Suitable measures::Mitigating rapid, short-term variations in flow (hydro-peaking operations)]]
 
|-
 
|[[Suitable measures::Cleaning of substrate - ripping, ploughing and flushing]]
 
|-
 
|[[Suitable measures::Removal of weirs]]
 
|-
 
|[[Suitable measures::Construction of a 'river-in-the-river']]
 
|-
 
|[[Suitable measures::Environmental design of embankments and erosion protection ]]
 
|-
 
|[[Suitable measures::Restoration of the riparian zone vegetation]]
 
|-
 
|[[Suitable measures::Placement of dead wood and debris]]
 
|-
 
|[[Suitable measures::Minimizing sediment arrival to reservoir]]
 
|-
 
|[[Suitable measures::Sensory, behavioural barriers (electricity, light, sound, air-water curtains)]]
 
|-
 
|[[Suitable measures::Skimming walls (fixed or floating)]]
 
|-
 
|[[Suitable measures::Bypass combined with other solutions]]
 
|-
 
|[[Suitable measures::Fish guidance structures with narrow and wide bar spacing]]
 
|-
 
|[[Suitable measures::Other types of fine screens]]
 
|-
 
|[[Suitable measures::Pool-type fishways]]
 
|-
 
|[[Suitable measures::Baffle fishways]]
 
|-
 
|[[Suitable measures::Fish lifts, screws and locks]]
 
|-
 
! colspan="2" style="text-align: center; background-color:#2cb4da; color:#ffffff;" |Relevant MTDs (demonstration purposes only)
 
|-
 
|[[Suitable MTDs::3D fish tracking system]]
 
|-
 
|[[Suitable MTDs::3D sensorless, ultrasound fish tracking]]
 
|-
 
|[[Suitable MTDs::Barotrauma detection system]]
 
|-
 
|[[Suitable MTDs::Current meter]]
 
|-
 
|[[Suitable MTDs::Differential pressure sensor base artificial lateral line probe, iRon]]
 
|-
 
|[[Suitable MTDs::Structure from motion (SfM)]]
 
|-
 
|[[Suitable MTDs::BASEMENT]]
 
|-
 
|[[Suitable MTDs::Cassiopee]]
 
|-
 
|[[Suitable MTDs::COSH-tool]]
 
|-
 
|[[Suitable MTDs::HEC-RAS]]
 
|-
 
|[[Suitable MTDs::OpenFOAM]]
 
|-
 
|[[Suitable MTDs::Radio frequency identification with passive integrated transponder (PIT tagging)]]
 
|-
 
|[[Suitable MTDs::River2D]]
 
|-
 
|[[Suitable MTDs::Sediment simulation in intakes with Multiblock option (SSIIM)]]
 
|-
 
|[[Suitable MTDs::TELEMAC]]
 
|-
 
|[[Suitable MTDs::Acoustic telemetry]]
 
|-
 
|[[Suitable MTDs::Radio telemetry]]
 
|}
 
 
 
 
 
 
 
{| class="wikitable" style="float:right;"
 
! colspan="2" style="text-align: center;background-color:#2cb4da; color:#ffffff;" | Fact box: Bannwil
 
|-
 
| Country
 
| Switzerland
 
|-
 
| River
 
| Aare
 
|-
 
| Operator
 
| BKW Energie AG
 
|-
 
| Capacity
 
| 28.5 MW
 
|-
 
| Head
 
| 5.5 - 8.5 m
 
|-
 
| Inter-annual discharge
 
| 260 m³/s
 
|-
 
| Turbine(s)
 
| 3 Bulb turbines
 
|}
 
  
 
=Introduction=
 
=Introduction=
The hydropower plant (HPP) is on the river Aare and located in Bannwil, some 46 km downstream of Lake Biel. There are two upstream HPPs on the Aare river below Lake Biel, HPP Brügg at the lake outflow and HPP Flumenthal about 12 km from Bannwil.
+
The Bannwil hydropower plant (HPP) is a run-of-the-river HPP on the river Aare located in the community of Bannwil, some 46 km downstream of Lake Biel. There are two upstream HPPs on the Aare river below Lake Biel, HPP Brügg at the lake outflow and HPP Flumenthal about 12 km from Bannwil.
  
 
The river Aare is a 291 km long tributary of the Rhine and the longest river within Switzerland. The Aare River passes through three major lakes: Lake of Brienz, Lake of Thun and Lake of Biel.
 
The river Aare is a 291 km long tributary of the Rhine and the longest river within Switzerland. The Aare River passes through three major lakes: Lake of Brienz, Lake of Thun and Lake of Biel.
  
In total there are 10 hydropower plants between Lake of Biel and the junction with the Rhine river.The other nine HPPs as well as two nuclear power plants are located downstream of the Bannwil HPP.
+
There are in total 12 HPPs on the Aare river stretch between Lake Biel and the junction with the Rhine river, and two nuclear power plants with water abstraction for cooling.
 +
 
 +
The altitude of the lowest and highest points of this river reach are ca. 312 m a.s.l. and 429 m a.s.l., respectively. The average altitude of the whole catchment amounts to 1060 m a.s.l. and the whole catchment area is 17687 km<sup>2</sup>, of which 1.4 % are covered by glaciers. On the river Aare, the mean monthly discharge increases from February to June and then decreases from July to October. The multi-year annual discharge amounts to 268 m<sup>3</sup>/s.
  
The altitude of the lowest and highest points of this river reach are ca. 312 m a.s.l. and 429 m a.s.l., respectively. The average altitude of the whole catchment amounts to 1060 m a.s.l. and the whole catchment area is 17687 km2, of which 1.4 % are covered by glaciers. On the river Aare, the mean monthly discharge increases from February to June and then decreases from July to October. The annual discharge in 2015 was 260 m3/s.
 
 
=About the hydropower plant=
 
=About the hydropower plant=
The run-of-river hydropower plant is located in Bannwil, downstream of Lake Biel and the HPP Brügg and Flumenthal. There are 9 more power plants between HPP Brügg and the junction with Rhine river as well as two nuclear power plants with water abstraction for cooling.
 
 
The weir is located on the right side of the river, while the Powerhouse is located on the left side. The reservoir is about 7 km long. With thre bulb turbines, the HPP has an installed capacity of 28.5 MW and an average annaul production of 150 GWh. The gross head amounts to 5.5 - 8.5 m depending on the up- and downstream water level with a designed discharge of 450 m3/s. The annual Production is about 150 GWh.
 
  
 +
The Bannwil weir is located on the right side of the river, while the powerhouse is located on the left side. The reservoir impoundment is about 7 km long. With three bulb turbines, HPP Bannwil has an installed capacity of 28.5 MW and an average annaul production of 150 GWh. The gross head amounts to 5.5 - 8.5 m, depending on the up- and downstream water levels, with a designed discharge of 450 m<sup>3</sup>/s.
 
===The Operator: BKW===
 
===The Operator: BKW===
The HPP Bannwil is operated by the BKW group. The Group plans, builds and operates infrastructure to produce and supply energy to businesses, households and the public sector, and offers digital business models for renewable energies. [https://www.bkw.ch/en/about-us/company/about-us/ Read more.]
+
HPP Bannwil is operated by the BKW group. The group plans, builds and operates infrastructure to produce and supply energy to businesses, households and the public sector, and offers digital business models for renewable energies. [https://www.bkw.ch/en/about-us/company/about-us/ Read more.]
  
 
=Pressures on the water body's ecosystem=
 
=Pressures on the water body's ecosystem=
The river Aare is located in the Rhine river catchment, which was historically one of the most important Atlantic salmon (Salmo Salar) rivers in Europe. The upstream migration of Salmons in the Rhine catchment became almost impossible after hydropower plant constructions. This includes the river Aare. All of the occurring fish species present in the Aare river (total of 44 fish species) face potentially high mortality during downstream migration or difficulties during upstream migration.
+
The river Aare is located in the Rhine river catchment, which was historically one of the most important Atlantic salmon (''Salmo salar'') rivers in Europe. The upstream migration of salmons in the Rhine catchment became almost impossible after intense hydropower plant constructions, including the Aare river catchment. All of the occurring fish species present in the Aare river (total of 44 fish species) face potentially high mortality during downstream migration or difficulties during upstream migration.
  
 
Furthermore, the river Aare is highly influenced by hydropower and considered as a heavily modified water body. Moreover, there are three nuclear power plants on the Aare river, two of them reintroducing the used cooling water, which induces an increase of the river water temperature. The river has a moderate ecological potential. Measures for sediment control, fish migration, flow changes, habitat in-channel and morphology off-channel have been implemented in the water body.
 
Furthermore, the river Aare is highly influenced by hydropower and considered as a heavily modified water body. Moreover, there are three nuclear power plants on the Aare river, two of them reintroducing the used cooling water, which induces an increase of the river water temperature. The river has a moderate ecological potential. Measures for sediment control, fish migration, flow changes, habitat in-channel and morphology off-channel have been implemented in the water body.
Line 127: Line 25:
 
=Test case topics=
 
=Test case topics=
 
===Fish population===
 
===Fish population===
There are a total of 44 fish species in the river Aare, some of which are: Eel (Anguilla anguilla), brown trout (Salmo trutta), chub (Squalius cephalus), grayling (Tymallus Thymallus), spirlin (Alburnus alburnus), common barbel (Barbus Barbus). Salmon is expected in the next 10 - 20 years.
+
There are a total of 44 fish species in the river Aare, amongst which eel (Anguilla anguilla), brown trout (Salmo trutta), chub (Squalius cephalus), grayling (Tymallus thymallus), spirlin (Alburnus alburnus), and common barbel (Barbus barbus). Salmon is expected to come back in the next 10-20 years after construction and upgrading of fish passes at HPPs on the Rhine river.
  
 
===Upstream migration===
 
===Upstream migration===
The current fish pass is pool design with bottom and top openings. The entrance is located at the left side of river shortly downstream of the powerhouse. The bottom slope of the technical fish pass is on average 6 %. Most of the head difference is accomplished in the first half of the fishway. It consists of chambers with a spiral fishway. The upper part of the fishway consists of near horizontal canal that lead to the exit roughly 100 m upstream of the HPP. The mean discharge in the fishway amounts to 350 l/s.
+
The current fish pass is a pool-type design with bottom and top openings. The entrance is located on the left shore shortly downstream of the powerhouse. The bottom slope of the technical fish pass is on average 6 %. Most of the head difference is accomplished in the first half of the fishway consisting of pools placed spirally. The upper part of the fishway consists of a nearly horizontal channel that leads to the exit roughly 100 m upstream of the HPP axis. The mean discharge in the fishway amounts to 350 l/s.
  
The fish pass needs to be restructured to accommodate larger fish in the near future. Current plans include replacing the lower part with a vertical fish pass design and the upper part with a nature like open channel.
+
The fish pass needs to be restructured to accommodate larger fish in the near future. Current plans include replacing the lower part with a vertical slot pass and the upper part with a nature like open channel pass.
 +
 
 +
===Downstream migration===
 +
There is no specific measures implemented at HPP Bannwil. Fish can pass through the turbines and/or over the weirs when they are in operation. Weir discharge occurs on average (1935-2015) for about 42 days per year.
  
 
=Research objectives and tasks=
 
=Research objectives and tasks=
At Bannwil, downstream fish migration measures are investigated by means of field and numerical studies. The current situation and the efficiency of spill flow or water release as an operational measure at the HPP Bannwil will be investigated through field monitoring and 3-D numerical modelling in the area near the powerhouse and weir. Applying this model to different structural and/or operational scenarios will allow to come up with solutions to improve fish migration at reduced energy losses. Dynamic pressure fluctuations experienced by fish during the turbine and spillway passages will be studied at HPP Bannwil using a Barotrauma Detection System (BDS) developed at TUT. Based on the data a CFD-model will be developed, which can then be used to evaluate the fish passage in order to judge the possibility of adapting the hydropower operation for certain time periods
+
At Bannwil HPP, downstream fish migration measures are investigated by means of field and CFD studies. The current situation and the efficiency of spill flow or water release as an operational measure at HPP Bannwil are investigated through field monitoring and 3-D numerical modelling in the areas near the powerhouse and weir. Applying this model to different structural and/or operational scenarios gives hints to solutions to improve fish migration at reduced energy losses. Dynamic pressure fluctuations experienced by fish during the turbine and spillway passages are studied at HPP Bannwil using a Barotrauma Detection System (BDS) developed at TUT. Based on the data, a CFD-model will be developed, which can then be used to evaluate the fish passage in order to judge the possibility of adapting the hydropower operation for certain time periods.
 
===Research tasks===
 
===Research tasks===
The research tasks and field studies conducted at Bannwil are:
+
The research tasks and field studies conducted at HPP Bannwil are:
  
 
* Velocity & hydraulic measurements
 
* Velocity & hydraulic measurements
* 3D Turbine & HPP models with Biological Performance Assessment and Barotrauma Detection System
+
* 3D turbine & HPP CFD models with Biological Performance Assessment and Barotrauma Detection System
 
* Fish monitoring; Survey of fish movement using ARIS Sonar and radio telemetry techniques
 
* Fish monitoring; Survey of fish movement using ARIS Sonar and radio telemetry techniques
 
* Variant Study
 
* Variant Study
 +
 
=Results=
 
=Results=
 +
 +
The results of the studies on downstream fish migration at HPP Bannwil indicate that no fish injury is expected during fish spillway passage since fish terminal velocity is higher than the weir velocity. However, due to back-roll in the stilling basin of spillway, fish might be exposed to increased predation or strike to baffle blocks. Numerical model results also indicate that hydraulic conditions at potential positions of a fish guidance structure in front of the turbines are unfavorable.
 +
 +
Analysis of the Biological Performance Assessment (BioPA) based on the CFD simulation of the turbines indicate that the average fish friendliness scores of the HPP Bannwil are 9.1 and 8.5 out of 10 at an acclimation depth of 5 m and 10 m, respectively. The former i.e. 5 m is more realistic for the HPP regarding the depth of the river. For an absolute fish survival rating, this factor plays an important role.
 +
 +
=Gallery=
 +
<gallery mode=packed>
 +
HPP Bannwil River Aare.jpg|Aerial view of Bannwil HPP; flow direction from top to bottom.
 +
HPP Bannwil River Aare2.jpg|View of Bannwil HPP from downstream [1].
 +
HPP Bannwil River Aare3.jpg|View of Bannwil HPP from downstream [2].
 +
Bannwil Layout.png|Layout of the Bannwil HPP and surrounding area; flow direction from bottom to top.
 +
</gallery>

Latest revision as of 14:03, 8 June 2021

Fact box: Bannwil
Country Switzerland
River Aare
Operator BKW Energie AG
Capacity 28.5 MW
Head 5.5 - 8.5 m
Inter-annual discharge 268 m3/s
Turbine(s) 3 Bulb turbines
Detailed report Click for pdf
Relevant solutions Applied in test case?
Bypass combined with other solutions -
Environmental design of embankments and erosion protection Yes
Fish guidance structures with wide bar spacing -
Fish refuge under hydropeaking conditions -
Operational measures (turbine operations, spillway passage) -
Pool-type fishways Yes
Sensory, behavioural barriers (electricity, light, sound, air-water curtains) -
Skimming walls (fixed or floating) -
Vertical slot fishways -
Relevant MTDs Applied in test case?
Acoustic Doppler current profiler (ADCP) Yes
Acoustic Doppler velocimetry (ADV) -
Acoustic telemetry -
Agent based model -
Barotrauma detection system Yes
BASEMENT -
CASiMiR -
Fish Protection System (induced drift application) -
FLOW-3D Yes
HEC-RAS -
OpenFOAM -
Particle image velocimetry (PIV) -
Radio frequency identification with passive integrated transponder (PIT tagging) -
Radio telemetry Yes
Sediment simulation in intakes with Multiblock option (SSIIM) -
Shelter measurements -
Structure from motion (SfM) -
TELEMAC -
Visible implant elastomer -

Introduction

The Bannwil hydropower plant (HPP) is a run-of-the-river HPP on the river Aare located in the community of Bannwil, some 46 km downstream of Lake Biel. There are two upstream HPPs on the Aare river below Lake Biel, HPP Brügg at the lake outflow and HPP Flumenthal about 12 km from Bannwil.

The river Aare is a 291 km long tributary of the Rhine and the longest river within Switzerland. The Aare River passes through three major lakes: Lake of Brienz, Lake of Thun and Lake of Biel.

There are in total 12 HPPs on the Aare river stretch between Lake Biel and the junction with the Rhine river, and two nuclear power plants with water abstraction for cooling.

The altitude of the lowest and highest points of this river reach are ca. 312 m a.s.l. and 429 m a.s.l., respectively. The average altitude of the whole catchment amounts to 1060 m a.s.l. and the whole catchment area is 17687 km2, of which 1.4 % are covered by glaciers. On the river Aare, the mean monthly discharge increases from February to June and then decreases from July to October. The multi-year annual discharge amounts to 268 m3/s.

About the hydropower plant

The Bannwil weir is located on the right side of the river, while the powerhouse is located on the left side. The reservoir impoundment is about 7 km long. With three bulb turbines, HPP Bannwil has an installed capacity of 28.5 MW and an average annaul production of 150 GWh. The gross head amounts to 5.5 - 8.5 m, depending on the up- and downstream water levels, with a designed discharge of 450 m3/s.

The Operator: BKW

HPP Bannwil is operated by the BKW group. The group plans, builds and operates infrastructure to produce and supply energy to businesses, households and the public sector, and offers digital business models for renewable energies. Read more.

Pressures on the water body's ecosystem

The river Aare is located in the Rhine river catchment, which was historically one of the most important Atlantic salmon (Salmo salar) rivers in Europe. The upstream migration of salmons in the Rhine catchment became almost impossible after intense hydropower plant constructions, including the Aare river catchment. All of the occurring fish species present in the Aare river (total of 44 fish species) face potentially high mortality during downstream migration or difficulties during upstream migration.

Furthermore, the river Aare is highly influenced by hydropower and considered as a heavily modified water body. Moreover, there are three nuclear power plants on the Aare river, two of them reintroducing the used cooling water, which induces an increase of the river water temperature. The river has a moderate ecological potential. Measures for sediment control, fish migration, flow changes, habitat in-channel and morphology off-channel have been implemented in the water body.

Test case topics

Fish population

There are a total of 44 fish species in the river Aare, amongst which eel (Anguilla anguilla), brown trout (Salmo trutta), chub (Squalius cephalus), grayling (Tymallus thymallus), spirlin (Alburnus alburnus), and common barbel (Barbus barbus). Salmon is expected to come back in the next 10-20 years after construction and upgrading of fish passes at HPPs on the Rhine river.

Upstream migration

The current fish pass is a pool-type design with bottom and top openings. The entrance is located on the left shore shortly downstream of the powerhouse. The bottom slope of the technical fish pass is on average 6 %. Most of the head difference is accomplished in the first half of the fishway consisting of pools placed spirally. The upper part of the fishway consists of a nearly horizontal channel that leads to the exit roughly 100 m upstream of the HPP axis. The mean discharge in the fishway amounts to 350 l/s.

The fish pass needs to be restructured to accommodate larger fish in the near future. Current plans include replacing the lower part with a vertical slot pass and the upper part with a nature like open channel pass.

Downstream migration

There is no specific measures implemented at HPP Bannwil. Fish can pass through the turbines and/or over the weirs when they are in operation. Weir discharge occurs on average (1935-2015) for about 42 days per year.

Research objectives and tasks

At Bannwil HPP, downstream fish migration measures are investigated by means of field and CFD studies. The current situation and the efficiency of spill flow or water release as an operational measure at HPP Bannwil are investigated through field monitoring and 3-D numerical modelling in the areas near the powerhouse and weir. Applying this model to different structural and/or operational scenarios gives hints to solutions to improve fish migration at reduced energy losses. Dynamic pressure fluctuations experienced by fish during the turbine and spillway passages are studied at HPP Bannwil using a Barotrauma Detection System (BDS) developed at TUT. Based on the data, a CFD-model will be developed, which can then be used to evaluate the fish passage in order to judge the possibility of adapting the hydropower operation for certain time periods.

Research tasks

The research tasks and field studies conducted at HPP Bannwil are:

  • Velocity & hydraulic measurements
  • 3D turbine & HPP CFD models with Biological Performance Assessment and Barotrauma Detection System
  • Fish monitoring; Survey of fish movement using ARIS Sonar and radio telemetry techniques
  • Variant Study

Results

The results of the studies on downstream fish migration at HPP Bannwil indicate that no fish injury is expected during fish spillway passage since fish terminal velocity is higher than the weir velocity. However, due to back-roll in the stilling basin of spillway, fish might be exposed to increased predation or strike to baffle blocks. Numerical model results also indicate that hydraulic conditions at potential positions of a fish guidance structure in front of the turbines are unfavorable.

Analysis of the Biological Performance Assessment (BioPA) based on the CFD simulation of the turbines indicate that the average fish friendliness scores of the HPP Bannwil are 9.1 and 8.5 out of 10 at an acclimation depth of 5 m and 10 m, respectively. The former i.e. 5 m is more realistic for the HPP regarding the depth of the river. For an absolute fish survival rating, this factor plays an important role.

Gallery