Research Portal
Displaying 11 – 20 of 40 results
Clean Tech » Emerging Concepts and Technologies Research Program
Design and Construction of an On-Demand, Submerged Combustion, Direct-Contact Water Heater operating on Hydrogen for use in the Agricultural Sector
September 2023 – September 2024
Transitioning to a green hydrogen economy requires end-use applications. Some water heating units that currently operate on propane or natural gas may be able to safely operate on hydrogen-enriched natural gas mixtures (HENG) with up to 20–30% hydrogen with no modification.
Clean Tech » Emerging Concepts and Technologies Research Program
Green ammonia derived membranes & sorbents for direct air capture of carbon dioxide
September 2023 – September 2024
Carbon dioxide (CO2) induced global warming is an existential threat, prompting efforts to reduce net emissions of this greenhouse gas (GHG) to zero. But as CO2 levels are already dangerously high, removal of CO2 remains necessary even once the net-zero target is achieved.
Clean Tech » Emerging Concepts and Technologies Research Program
Heat Pump and Phase Change Thermal Energy Storage Feasibility Study
September 2023 – September 2024
The Applied Energy Research Lab at NSCC will lead a consortium of private and public sector partners to develop and evaluate electricity demand response solutions using air source heat pumps (ASHP) with advanced phase change material thermal energy storage (PCM-TES).
Clean Tech » Emerging Concepts and Technologies Research Program
Empowering Sustainable Livestock Practices: Advanced Sensors for GHG Monitoring
September 2023 – September 2024
Livestock industry accounts for approximately 14.5% of total global greenhouse gas (GHG) emissions. The primary sources of GHG emissions from ruminant animals are enteric fermentation and manure disposal, which are inherent and essential parts of the animal food cycle.
Tidal Energy » Tidal Resource Characterization and Modelling
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.
Tidal Energy » Tidal Resource Characterization and Modelling
How Does Sound Travel in High Energy Environments? Effectiveness of Acoustic Monitoring Systems and Turbine Audibility Assessment
April 2017 – December 2020
The researchers are designing and implementing a long-term acoustic monitoring program to support tidal energy development in the Bay of Fundy. Specialized acoustic instrumentation was deployed for a two-month period in Grand Passage to advance understanding how turbulence affects the abilit
Tidal Energy » Tidal Resource Characterization and Modelling
Reducing Costs of Tidal Energy through a Comprehensive Characterization of Turbulence in Minas Passage
October 2017 – March 2020
Turbulence is a significant issue at every site being considered for in-stream tidal energy development.
Tidal Energy » Tidal Resource Characterization and Modelling
Multi-Scale Turbulence Measurement in the Aquatron Laboratory
July 2018 – July 2019
This project has two primary objectives - to characterize the flow and turbulence in the Aquatron facility pool tank using turbulence sensors calibrated against a traceable standard; and to test technologies for investigating the horizontal variability of turbulence in real-world tidal channels.
Tidal Energy » Tidal Resource Characterization and Modelling
Remote Acoustic Measurements of Turbulence in High-Flow Tidal Channels during High Wave Conditions
April 2018 – April 2019
Many of the high-flow tidal channels targeted for worldwide in-stream hydro-electric development are impacted by surface gravity waves incident from a large exterior basin (e.g. the Bay of Fundy/Gulf of Maine/North Atlantic).
Tidal Energy » Tidal Resource Characterization and Modelling
Turbine Wake Characterization
November 2017 – March 2019
Turbine wake characterization is a key endeavour to the development of in-stream tidal turbine arrays. In a sense, a turbine’s footprint includes its wake, wherein flow speeds are less and turbulence is elevated compared to the ambient surroundings. It is thus desired to not just deli