Research Portal
Displaying 1 – 7 of 7 results
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 field
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
Environmental Monitoring System Development
November 2019 – April 2021
The Pathway Program - Technology Validation: Echosouders & Passive Acoustic Monitoring Device
Finite Element Analysis to Assess Fish Mortality from Interactions with Tidal Turbine Blades
February – December 2017
The research project used finite element analysis (FEA) to simulate the impact of a tidal turbine blade on fish, and assess whether mortality of marine life can be expected in such an event.
Geoscience » Source Rock & Depositional Environment
Mid Cretaceous Sand Supply to Offshore SW Nova Scotia: Tectonic Diversion of Labrador Rivers during Naskapi Member Deposition
September 2015 – September 2017
This study tests the hypothesis that tectonic diversion of Labrador rivers during the Aptian resulted in sand supply through the Bay of Fundy to the Shelburne sub-basin, allowing shales to accumulate farther east in the Scotian Basin.
FORCE Data Management System/User Interface
April – June 2017
This project defined a Data Management System (DMS) and user interface solution for use by FORCE.
Impact of Channel Blockage on the Performance of Axial and Cross-Flow Hydrokinetic Turbines
April 2017
This work investigates the effect of channel blockage on how axial and cross-flow turbines perform. The objective is to fill a gap in the literature on suitable blockage corrections for cross-flow turbines.