Research Portal
Displaying 1 – 10 of 11 results
Faits marquants sur l’énergie marémotrice » caractérisation et modélisation des ressources en énergie marémotrice
The Vectron2 Project: Turbulence Measurements for the In-stream Tidal Energy Industry
March 2019 – November 2021
The Vectron is a new sensor used for measuring turbulence velocity within a tidal turbine’s swept area. The Vectron has been successfully prototyped, where next steps are to take the technology to the ‘industry-ready’ stage of development and the focus of this project.
Faits marquants sur l’énergie marémotrice » technologies
The Pathway Program: Validating reliable environmental monitoring for ocean energy projects
April 2019 – October 2021
OERA created The Pathway Program to solve a critical problem impeding the in-stream tidal energy industry: a lack of reliable and validated technologies and methods to monitor and report fish-turbine interactions in high-flow, highly turbulent environments, leading to regulatory uncertainty and i
Faits marquants sur l’énergie marémotrice » vie marine
Real-Time Detection of Marine Mammals in High Flow Environments
May 2019 – September 2021
The project research goal is to design and test an innovative acoustic sensor system that will feature a wireless magneto-inductive (MI) communications link – to alert users in real time of the presence and location of marine mammals in high noise tidal environments. The research entails a
Faits marquants sur l’énergie marémotrice » technologies
Environmental Monitoring System Development
November 2019 – April 2021
The Pathway Program - Technology Validation: Echosouders & Passive Acoustic Monitoring Device
Faits marquants sur l’énergie marémotrice » caractérisation et modélisation des ressources en énergie marémotrice
Numerical Modeling of Tidal Turbine Behaviour under Real Turbulent Tidal Flow Conditions
December 2015 – December 2016
Researchers investigated and numerically quantified the behaviour of a tidal turbine under turbulent unsteady tidal flow, using flow data collected in the lower Bay of Fundy (Digby area).
Faits marquants sur l’énergie marémotrice » aspects socio-économiques et utilisations traditionnelles » Socioeconomic Studies
Nova Scotia Tidal Research Summary Report – Researching Tidal Energy – Marine Life: The Nova Scotia Experience
October 2015 – May 2016
This report looks at the extensive tidal energy-related research undertaken in the Bay of Fundy over a 10 year period beginning in 2005.
Faits marquants sur l’énergie marémotrice » technologies
On-line Interactive GIS Map Platform: An Enabling Initiative for the Emerging Tidal Energy Industry
April 2015 – April 2016
A proof-of-concept Geographic Information System (GIS) platform was developed aiming at building a decision-making tool that integrates complex spatial information of importance to the tidal energy industry while also being scalable, flexible and accessible. The platform was built on open s
Faits marquants sur l’énergie marémotrice » caractérisation et modélisation des ressources en énergie marémotrice
Characterizing Tidal Flows and Turbine Power Production in Petit Passage using Oceanographic and CFD Models
September 2015 – March 2016
The goal of this project was to identify potential turbine deployment locations in Petit Passage Nova Scotia, using computational fluid dynamics (CFD) and finite volume coastal ocean models (FVCOM).
Faits marquants sur l’énergie marémotrice » plancher océanique, sédiments et domaine benthique
Impacts of Tidal Energy Extraction on Sediment Dynamics in Minas Basin, Bay of Fundy
February 2010 – December 2012
Researchers developed a numerical hydrodynamic and sediment transport model for Minas Basin in the Bay of Fundy, focusing on the sediment dynamics of the tidal inlets and flats.
Faits marquants sur l’énergie marémotrice » plancher océanique, sédiments et domaine benthique
Effects of Energy Extraction on Sediment Dynamics in Intertidal Ecosystems of the Minas Basin
January 2010 – May 2012
This project assessed how the dynamics of sedimentation change when energy is extracted from a macro-tidal system. The differences in tidal prism and energy between neap and spring tidal cycles were used as a proxy for energy extraction by in-stream tidal power devices.