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Faits marquants sur l’énergie marémotrice » infrastructures et pratiques exemplaires

STREEM: Sensor Testing Research for Environmental Effects Monitoring

October 2018 – March 2019

The research goal was to enhance understanding on sensor performance and sensor-to-sensor interactions to inform environmental effects monitoring (EEM) protocol for future tidal turbine deployments.

Faits marquants sur l’énergie marémotrice » infrastructures et pratiques exemplaires

Optimized Combinations of Tidal, Wind and Solar Electricity Generation with Energy Storage to Meet Nova Scotia’s Electrical Demand

August 2018 – March 2019

Wind, solar and tidal-generated electricity each have different, but potentially complimentary, cyclic times.

Faits marquants sur l’énergie marémotrice » infrastructures et pratiques exemplaires

Innovative Solutions for De-risking Species Detections in Tidal Energy Environmental Effects Monitoring Programs

April 2018 – March 2019

With collaboration from Genome Atlantic, this research project is using a new environmental DNA technology to rapidly identify and determine abundance of different fish species in high-flow marine conditions. Experiments were conducted at Dalhousie University’s Aquatron facility. N

Faits marquants sur l’énergie marémotrice » infrastructures et pratiques exemplaires

Feasibility Study: Tidal Sector Service Barge/Drydock

April – November 2018

The study investigates the feasibility of developing a generic, shared-use, multi-function turbine transport deployment and retrieval barge/drydock for use by the Nova Scotia tidal energy sector.

Faits marquants sur l’énergie marémotrice » vie marine

Using Radar to Evaluate Seabird Abundance and Habitat Use at the Fundy Ocean Research Center for Energy Site near Parrsboro, Nova Scotia

April – September 2018

Shore-based seabird surveys conducted at the Fundy Ocean Research Center for Energy (FORCE) in Parrsboro, NS, determine abundance, habitat use and potential risk to seabirds at the site.

Faits marquants sur l’énergie marémotrice » infrastructures et pratiques exemplaires

Using Dry Ports to Support Nova Scotia’s Tidal Industry

March – June 2018

This study investigates two Nova Scotia “dry ports” and their potential in supporting the Bay of Fundy region’s emergent tidal energy industry. The term ‘dry port’ refers to a port where the harbour bottom is mainly exposed at low tide.

Faits marquants sur l’énergie marémotrice » caractérisation et modélisation des ressources en énergie marémotrice

Turbulence and Bottom Stress in Minas Passage and Grand Passage

September 2011 – February 2015

This project aimed to investigate turbulence and bottom stress at two sites being targeted for in-stream tidal power development in Nova Scotia: Minas Passage in the Upper Bay of Fundy and Grand Passage, located between Brier and Long Island in the lower Bay of Fundy.

Faits marquants sur l’énergie marémotrice » caractérisation et modélisation des ressources en énergie marémotrice

Passive Acoustic Monitoring of Cetacean Activity Patterns and Movements Pre- and Post-deployment of TISEC devices in Minas Passage

June 2011 – July 2013

This project aimed to conduct pre- and post- in-stream tidal energy device deployment assessments of marine mammal activity and to assess the potential risk for interaction with turbine infrastructure.

Faits marquants sur l’énergie marémotrice » vie marine

Acoustic Tracking of Fish Movements in the Minas Passage and FORCE Crown Lease Area: Pre-Turbine Baseline Studies

June 2011 – July 2013

This project used animal tracking technology developed by VEMCO, a division of AMIRIX Systems of Halifax, NS. The technology allows researchers to track animal movements and behaviour over a scale of kilometers.

Faits marquants sur l’énergie marémotrice » caractérisation et modélisation des ressources en énergie marémotrice

Cross Coupling between Device Level CFD and Oceanographic Models Applied to Multiple TISECs in Minas Passage

October 2011 – January 2013

This project aimed to develop a link between oceanographic computer models and Computational Fluid Dynamics (CFD) models in order to improve state-of-the-art modelling techniques used for resource assessments and tidal turbine siting for both single and multiple in-stream tidal energy devices.