Biology:Fish ladder

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Short description: Structure to allow fish to migrate upriver around barriers
Pool-and-weir fish ladder at Bonneville Dam on the Columbia River

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FERC Fish Ladder Safety Sign

A fish ladder, also known as a fishway, fish pass, fish steps, or fish cannon is a structure on or around artificial and natural barriers (such as dams, locks and waterfalls) to facilitate diadromous fishes' natural migration as well as movements of potamodromous species.[1] Most fishways enable fish to pass around the barriers by swimming and leaping up a series of relatively low steps (hence the term ladder) into the waters on the other side. The velocity of water falling over the steps has to be great enough to attract the fish to the ladder, but it cannot be so great that it washes fish back downstream or exhausts them to the point of inability to continue their journey upriver.

History

Denil Fishway on Salmon Creek, Montana

Written reports of rough fishways date to 17th-century France, where bundles of branches were used to make steps in steep channels to bypass obstructions.

A 1714 construction of an old channel bypassing a dam, "originally cut for the passage of fish up and down the river", is mentioned in the 1823 U.S. Circuit Court Case Tyler v. Wilkinson. This example predates the 1880 fish ladder at Pawtuxet Falls. The 1714 channel "wholly failed for this purpose" and, in 1730, a mill was built in its place. The channel and its mill usage became an important legal case in U.S. water law.[2]

A pool and weir salmon ladder was built around 1830 by James Smith, a Scottish engineer on the River Teith, near Deanston, Perthshire in Scotland. Both the weir and salmon ladder are there today and many subsequent salmon ladders built in Scotland were inspired by it.[3]

A version was patented in 1837 by Richard McFarlan of Bathurst, New Brunswick, Canada, who designed a fishway to bypass a dam at his water-powered lumber mill.[4] In 1852–1854, the Ballisodare Fish Pass was built in County Sligo in Ireland to draw salmon into a river that had not supported a fishery. In 1880, the first fish ladder was built in Rhode Island, United States, on the Pawtuxet Falls Dam. The ladder was removed in 1924, when the City of Providence replaced the wood dam with a concrete one.

As the Industrial Age advanced, dams and other river obstructions became larger and more common, leading to the need for effective fish by-passes.[5]

Types

Pool and weir
One of the oldest styles of fish ladders. It uses a series of small dams and pools of regular length to make a long, sloping channel for fish to travel around the obstruction. The channel acts as a fixed lock to gradually step down the water level; to head upstream, fish must jump over from box to box in the ladder.
Baffle fishway
Uses a series of symmetrical close-spaced baffles in a channel to redirect the flow of water, allowing fish to swim around the barrier. Baffle fishways need not have resting areas, although pools can be included to provide a resting area or to reduce the velocity of the flow. Such fishways can be built with switchbacks to minimize the space needed for their construction. Baffles come in variety of designs. The most common design is the Larinier pass, named after the French engineer who designed them. They are suitable for coarse fish as well as salmonids, and can be built large enough to be used by canoes.[6] The original design for a Denil fishway was developed in 1909 by a Belgian scientist, G. Denil; it has since been adjusted and adapted in many ways. The Alaskan Steeppass, for example, is a modular prefabricated Denil-fishway variant originally designed for remote areas of Alaska. Baffles have been installed by Project Maitai in several waterways in Nelson, New Zealand, to improve fish passage as part of general environmental restoration.
Fish elevator (or fish lift)
Breaks with the ladder design by providing a sort of elevator to carry fish over a barrier. It is well suited to tall barriers. With a fish elevator, fish swim into a collection area at the base of the obstruction. When enough fish accumulate in the collection area, they are nudged into a hopper that carries them into a flume that empties into the river above the barrier. On the Connecticut River, for example, two fish elevators lift up to 500 fish at a time, 52 feet (15.85 m), to clear the Holyoke Dam. In 2013, the elevator carried over 400,000 fish.[7]
Rock-ramp fishway
Uses large rocks and timbers to make pools and small falls that mimic natural structures. Because of the length of the channel needed for the ladder, such structures are most appropriate for relatively short barriers. They have a significant advantage in that they can provide fish spawning habitat.[8]
Vertical-slot fish passage
Similar to a pool-and-weir system, except that each "dam" has a narrow slot in it near the channel wall. This allows fish to swim upstream without leaping over an obstacle. Vertical-slot fish passages also tend to handle reasonably well the seasonal fluctuation in water levels on each side of the barrier. Recent studies suggest that navigation locks have a potential to be operated as vertical slot fishways to provide increased access for a range of biota, including poor swimmers.[9][10]
Fish siphon
Allows the pass to be installed parallel to a water course and can be used to link two watercourses. The pass utilises a syphon effect to regulate its flow. This style is particularly favoured to aid flood defence.
Fish cannon
A wet, flexible pneumatic tube uses air pressure to suck in salmon one at a time and gently shoot them out into the destination water. The system was originally designed by Bellevue, Washington company Whooshh to safely move apples.[11][12][13]
Borland Fish Lift
This is similar to a canal lock. At the downstream end of the obstruction, fish are attracted to a collecting pool by an outflow of water through a sluice gate. At fixed intervals, the gate is closed, and water from the upper level fills the collecting pool and an inclined shaft, lifting the fish up to the upstream level. Once the shaft is full, a sluice at the top level opens, to allow fish to continue their journey upstream. The top sluice then closes, and the shaft empties for the process to begin again. A number of Borland fish lifts have been built in Scotland, associated with hydro-electric dams, including one at Aigas Dam on the River Beauly.[14]

Effectiveness

This fish failed to enter the narrow opening in the fish ladder in Akerselva, Norway

Fish ladders have a mixed record of effectiveness. They vary in effectiveness for different types of species, with one study showing that only three percent of American Shad make it through all the fish ladders on the way to their spawning ground.[15] Effectiveness depends on the fish species' swimming ability, and how the fish moves up and downstream. A fish passage that is designed to allow fish to pass upstream may not allow passage downstream, for instance.[16] Fish passages do not always work. In practice a challenge is matching swimming performance data to hydrodynamic measurements.[17][18] Swim tests rarely use the same protocol and the output is either a single-point measurement or a bulk velocity. In contrast, physical and numerical modelling of fluid flow (i.e. hydrodynamics) deliver a detailed flow map, with a fine spatial and temporal resolution. Regulatory agencies face a difficult task to match hydrodynamic measurements and swimming performance data.

Culverts

During the last three decades,[when?] the ecological impact of culverts on natural streams and rivers has been recognised. While the culvert discharge capacity derives from hydrological and hydraulic engineering considerations,[19] this results often in large velocities in the barrel, which may prevent fish from passing through.

Baffles may be installed along the barrel invert to provide some fish-friendly alternative.[20][21][22] For low discharges, the baffles decrease the flow velocity and increase the water depth to facilitate fish passage. At larger discharges, baffles induce lower local velocities and generate recirculation regions. However, baffles can reduce drastically the culvert discharge capacity for a given afflux,[23] thus increasing substantially the total cost of the culvert structure to achieve the same design discharge and afflux. It is believed that fish-turbulence interplay may facilitate upstream migration, albeit an optimum design must be based upon a careful characterisation of both hydrodynamics and fish kinematics.[18][24][25] Finally the practical engineering design implications cannot be ignored, while a solid understanding of turbulence typology is a basic requirement to any successful boundary treatment conducive of upstream fish passage.[26]

See also

Citations

  1. "What is a Fish Ladder?". Michigan: Michigan Department of Natural Resources. http://www.michigan.gov/dnr/0,4570,7-153-10364_52259_19092-46291--,00.html. 
  2. Mason, William P.. "Tyler v. Wilkinson". Harvard Law School Library. https://opencasebook.org/casebooks/510-open-source-property/resources/3.3.2.2-tyler-v-wilkinson/. 
  3. "James Smith (1789-1850) - Graces Guide". https://www.gracesguide.co.uk/James_Smith_(1789-1850). 
  4. Mario Theriault, Great Maritime Inventions 1833–1950, Goose Lane, 2001, p. 45
  5. Office Of Technology Assessment Washington DC (1995) Fish passage technologies : protection at hydropower facilities Diana Publishing, ISBN:1-4289-2016-1.
  6. "How fish climb". Canal and River Trust. 22 December 2020. https://canalrivertrust.org.uk/enjoy-the-waterways/fishing/caring-for-our-fish/how-fish-climb. 
  7. "2013 Connecticut River Migratory Fish". United States Fish and Wildlife Service. http://www.fws.gov/r5crc/fish/old13.html. 
  8. Aadland, Luther P. (2010). Reconnecting Rivers: Natural Channel Design in Dam Removals and Fish Passage. Minnesota Department of Natural Resources. http://www.dnr.state.mn.us/eco/streamhab/reconnecting_rivers.html. 
  9. Silva, S.; Lowry, M.; Macaya-Solis, C.; Byatt, B.; Lucas, M. C. (2017). "Can navigation locks be used to help migratory fishes with poor swimming performance pass tidal barrages? A test with lampreys". Ecological Engineering 102: 291–302. doi:10.1016/j.ecoleng.2017.02.027. 
  10. Quaranta, E.; Katopodis, C.; Revelli, R.; Comoglio, C (2017). "Turbulent flow field comparison and related suitability for fish passage of a standard and a simplified low‐gradient vertical slot fishway". River Research and Applications 33 (8): 1295–1305. doi:10.1002/rra.3193. https://iris.polito.it/bitstream/11583/2678527/1/Quaranta%20et%20al._final%20version.pdf. 
  11. 'Salmon Cannon' Fires Fish Over Dams At 22mph 13 August 2014 www.youtube.com, accessed 15 January 2022
  12. "Whoosh: 'Salmon Cannon' Shoots Fish Upstream to Spawn". 13 November 2014. https://www.livescience.com/48752-salmon-cannon-fish-spawning.html. 
  13. "What is the 'salmon cannon' and how do the fish feel about it?". The Guardian. 15 August 2019. https://www.theguardian.com/environment/2019/aug/15/salmon-cannon-fish-dam. 
  14. Wood, Emma (2005). "Power from the Glens". Scottish and Southern Energy. p. 8. http://www.scottish-southern.co.uk/sseinternet/assets/569CABFE-1165-4ED8-9419-CF3B5A64BC98.pdf. 
  15. Waldman, John. "Blocked Migration: Fish Ladders On U.S. Dams Are Not Effective". Yale School of Forestry and Environmental Sciences. http://e360.yale.edu/feature/blocked_migration_fish_ladders_on_us_dams_are_not_effective/2636/. 
  16. Kraft, Amy (February 20, 2013). "Upstream Battle: Fishes Shun Modern Dam Passages, Contributing to Population Declines". Scientific American. http://www.scientificamerican.com/article/upstream-battle-fishes-shun-modern-dam-passages-population-declines/. 
  17. Katopodis, C.; Gervais, R. (2016). "Fish Swimming Performance Database and Analyses". DFO CSAS Research Document No. 2016/002, Canadian Science Advisory Secretariat, Fisheries and Oceans Canada, Ottawa, Canada: 1–550. 
  18. 18.0 18.1 Wang, H.; Chanson, H. (2017). "How a better understanding of Fish-Hydrodynamics Interactions might enhance upstream fish passage in culverts". Civil Engineering Research Report No. CE162: 1–43. http://espace.library.uq.edu.au/view/UQ:696033. 
  19. Chanson, H. (2004). The Hydraulics of Open Channel Flow: An Introduction. Butterworth-Heinemann, 2nd edition, Oxford, UK. ISBN 978-0-7506-5978-9. 
  20. Olsen, A.; Tullis, B. (2013). "Laboratory Study of Fish Passage and Discharge Capacity in Slip-Lined, Baffled Culverts". Journal of Hydraulic Engineering 139 (4): 424–432. doi:10.1061/(asce)hy.1943-7900.0000697. ISSN 0733-9429. 
  21. Chanson, H.; Uys, W. (2016). "Baffle Designs to Facilitate Fish Passage in Box Culverts: A Preliminary Study". 6th IAHR International Symposium on Hydraulic Structures, Hydraulic Structures and Water System Management: 295–304. doi:10.15142/T300628160828. ISBN 978-1-884575-75-4. https://espace.library.uq.edu.au/view/UQ:396517. 
  22. Cabonce, J.; Fernando, R.; Wang, H.; Chanson, H. (2017). Using Triangular Baffles to Facilitate Upstream Fish Passage in Box Culverts: Physical Modelling. Hydraulic Model Report No. CH107/17, School of Civil Engineering, The University of Queensland, Brisbane, Australia, 130 pages. ISBN 978-1-74272-186-6. http://espace.library.uq.edu.au/view/UQ:653838. 
  23. Larinier, M. (2002). "Fish Passage through Culverts, Rock Weirs and Estuarine Obstructions". Bulletin Français de la Pêche et de la Pisciculture 364 (18): 119–134. doi:10.1051/kmae/2002097. 
  24. Wang, H.; Chanson, H. (2017). "Baffle Systems to Facilitate Upstream Fish Passage in Standard Box Culverts: How About Fish-Turbulence Interplay?". 37th IAHR World Congress, IAHR & USAINS, Kuala Lumpur, Malaysia 3: 2586–2595. http://espace.library.uq.edu.au/view/UQ:678859. 
  25. Wang, H.; Chanson, H. (2018). "Modelling Upstream Fish Passage in Standard Box Culverts: Interplay between Turbulence, Fish Kinematics, and Energetics". River Research and Applications 34 (3): 244–252. doi:10.1002/rra.3245. http://espace.library.uq.edu.au/view/UQ:719818/UQ719818_preprint_OA.pdf. 
  26. Chanson, H. (2019). "Utilising the Boundary Layer to Help Restore the Connectivity of Fish Habitats and Populations. An Engineering Discussion". Ecological Engineering 141 (105613): 105613. doi:10.1016/j.ecoleng.2019.105613. https://espace.library.uq.edu.au/view/UQ:8e04f63/UQ8e04f63_graphical.pdf. 

General and cited references

External links