Riverine

Capturing energy from river currents.

Riverine energy technologies extract the kinetic energy from flowing water in rivers to generate electricity. Although not technically a marine resource, as part of the natural hydrological cycle, water from drainage basins, groundwater springs, and snow melt feed rivers that flow towards lakes, seas, and oceans. This movement of water downstream can be used to generate electricity via riverine turbines or hydroelectric dams.

Riverine Turbines

Riverine turbines capture the kinetic energy from the flowing water in rivers, streams, canals, and creeks to generate electricity. These turbines can be mounted on the ground, attached to a fixed or floating structure, or suspended within the water column. Riverine turbines are similar to those used for tidal energy, except that they are designed to extract energy from water that flows in only one direction.

_{Photo Credit: Ocean Renewable Power Company (ORPC)}

Hydroelectric Dams

Hydroelectric dams store large volumes of water which, when allowed to flow downstream, spin turbines that then generate electricity. The power extracted from the water depends on the volume of dammed water and the height between the source and the turbines.
Please note: Very little of the content in Tethys deals with the environmental effects of hydroelectric dams, as this topic falls outside of Tethys’ scope.

_{Photo Credit: Martina Nolte / Creative Commons CC-by-sa-3.0 de}

The main environmental concern is collision between turbine blades and marine organisms due to natural animal movements, attraction to the device, or inability to avoid turbines within strong currents. It should be noted that these turbines spin much slower than propellers on ships, and that marine mammals are typically less common in most rivers. There is some concern that noise from the turbines can affect animals that use sound for communication, social interaction, orientation, predation, and evasion. As with all electricity generation, there is a slight concern that electromagnetic fields generated by power cables and moving parts may affect animals that use Earth's natural magnetic field for orientation, navigation, and hunting. Likewise, chemicals, such as anti-corrosion paint and small amounts of oil and grease, may enter the waterbody during spills and affect water quality. Large-scale changes in flow (from arrays) may alter the natural physical system, potentially affecting ecosystem processes, though this may be seen as a benefit for flood protection.

Marine and Wind Energy Environmental Documents

Tethys is a knowledge hub that contains documents on the environmental effects of wind and marine energy. The table below contains all of the documents in the Tethys Knowledge Base associated with Riverine.

Total: 107

Type of Content

Technology

Stressor

Receptor

Searches title and abstract.

Title	Author	Date	Content Type	Technology	Stressor	Receptor
Hydrokinetic Power for Energy Access in Rural Ghana	Miller, V., Ramde, E., Gradoville, R.	February 2011	Journal Article	Marine Energy, Riverine		Human Dimensions, Legal & Policy
Hydrokinetic Energy Projects and Recreation: A Guide to Assessing Impacts	Bowers, R., Harn, J., Rosebrough, S.	December 2010	Report	Wave, Tidal, Riverine, Ocean Current, Marine Energy		Recreation & Tourism, Human Dimensions
River, Tidal, and Ocean Current Hydrokinetic Energy Technologies: Status and Future Opportunities in Alaska	Johnson, J., Pride, D.	November 2010	Report	Riverine, Marine Energy		Sediment Transport, Physical Environment, Fish
Evaluation of Small Axial Flow Hydrokinetic Turbines for Remote Communities	Anyi, M., Kirke, B.	June 2010	Journal Article	Marine Energy, Riverine		Human Dimensions, Social & Economic Data
Run of River Hydrokinetic Renewable Energy Presentation: Clean, Domestic, Scalable, Continuous, Competative Power	Free Flow Power	April 2010	Presentation	Riverine, Marine Energy
An Estimation Of Survival And Injury Of Fish Passed Through The Hydro Green Energy Hydrokinetic System, And A Characterization Of Fish Entrainment Potential At The Mississippi Lock And Dam No. 2 Hydroelectric Projects	Normandeau Associates Inc	December 2009	Report	Marine Energy, Riverine	Collision	Fish
Lock and Dam No. 2 Hydroelectric Project	Hydro Green Energy	August 2009	Project Site	Marine Energy, Riverine
In-Stream Tidal Energy Potential of Puget Sound, Washington	Polagye, B., Kawase, M., Malte, P.	January 2009	Journal Article	Marine Energy, Riverine, Tidal		Physical Environment
Hydrodynamic Effects of Kinetic Power Extraction by In-Stream Tidal Turbines	Polagye, B.	January 2009	Thesis	Marine Energy, Riverine, Tidal	Changes in Flow	Physical Environment
River Current Energy Conversion Systems: Progress, Prospects and Challenges	Khan, M., Iqbal, M., Quaicoe, J.	October 2008	Journal Article	Riverine, Marine Energy		Human Dimensions
Environmental Assessment for Mississippi River Lock and Dam No. 2 Hydroelectric Project	City of Hastings	September 2008	Report	Riverine, Marine Energy		Human Dimensions, Environmental Impact Assessment
A Review of the Application of Lifecycle Analysis to Renewable Energy Systems	Lund, C., Biswas, W.	April 2008	Journal Article	Wind Energy, Wave, Tidal, Riverine, Marine Energy		Life Cycle Assessment, Human Dimensions
Evaluation of Blade-Strike Models for Estimating the Biological Performance of Kaplan Turbines	Deng, Z., Carlson, T., Ploskey, G.	November 2007	Journal Article	Marine Energy, Riverine	Collision	Fish, Pelagic Fish
A New Tool to Forecast Fish Movement and Passage	Goodwin, R., Nestler, J., Anderson, J.	August 2007	Magazine Article	Riverine, Marine Energy		Fish
Potential Impacts Of Hydrokinetic And Wave Energy Conversion Technologies On Aquatic Environments	Cada, G., Ahlgrimm, J., Bahleda, M.	April 2007	Journal Article	Marine Energy, Riverine, Wave
Efforts to Reduce Mortality to Hydroelectric Turbine-Passed Fish: Locating and Quantifying Damaging Shear Stresses	Cada, G., Loar, J., Garrison, L.	February 2006	Journal Article	Marine Energy, Riverine	Collision	Fish
Evaluation of Blade-Strike Models for Estimating the Biological Performance of Large Kaplan Turbines	Deng, Z., Carlson, T., Ploskey, G.	November 2005	Report	Marine Energy, Riverine	Collision	Fish, Pelagic Fish
Use of Pressure-Sensitive Film to Quantify Sources of Injury to Fish	Cada, G., Smith, J., Busey, J.	January 2005	Journal Article	Riverine, Marine Energy	Collision	Fish
Comparison of Blade-Strike Modeling Results with Empirical Data	Ploskey, G., Carlson, T.	March 2004	Report	Riverine, Marine Energy	Collision	Fish
Identifying the Effects on Fish of Changes In Water Pressure during Turbine Passage	Becker, J., Abernethy, C., Dauble, D.	September 2003	Magazine Article	Riverine, Marine Energy	Changes in Flow	Fish
Life-Cycle Assessment of Electricity Generation Options: The Status of Research in the Year 2001	Gagnon, L., Bélanger, C., Uchiyama, Y.	November 2002	Journal Article	Marine Energy, Riverine, Wind Energy, Land-Based Wind		Human Dimensions, Life Cycle Assessment
Evaluation of the Effects of Turbulence on the Behaviour of Migratory Fish	Odeh, M., Noreika, J., Haro, A.	March 2002	Report	Riverine, Marine Energy	Changes in Flow	Fish
Evaluation of Juvenile Salmon Behavior at Bonneville Dam, Columbia River, using a Multibeam Technique	Johnson, R., Moursund, R.	September 2000	Journal Article	Marine Energy, Riverine		Fish, Pelagic Fish
Laboratory Studies on the Effects of Shear on Fish	Nietzel, D., Richmond, M., Dauble, D.	September 2000	Report	Marine Energy, Riverine	Changes in Flow	Fish, Pelagic Fish
Downstream Migration of Fish Through Dams of Hydroelectric Power Plants	Pavlov, D., Lupandin, A., Kostin, V.	January 1999	Book	Riverine, Marine Energy	Collision	Fish
A Review of Studies Related to the Effects of Propeller-Type Turbine Passage on Fish Early Life Stages	Cada, G.	January 1990	Journal Article	Marine Energy, Riverine	Collision	Fish
Annapolis Tidal Station	Nova Scotia Power Corporation	January 1984	Project Site	Marine Energy, Riverine, Tidal