Energy Strategies and Projects

Explore the various initiatives to optimize, upgrade or replace our building’s energy systems, integrate new technology and help UBCO operate as efficiently as possible.

Energy strategies

The Energy Team has been actively working on developing appropriate policies and guidelines that assist in meeting long-term campus energy and carbon goals.

Reports and analytics

Explore UBCO energy consumption data through UBCO’s portfolio manager, data analytics programs, and quarterly and annual reports.

Energy projects

The energy team manages various projects and initiatives to optimize, upgrade, and replace building energy systems, in order to operate as efficiently as possible as the campus grows.

Building Recommissioning

Building recommissioning allows campus buildings to save on energy and operating cost levels, as well as increase comfort levels.

A comprehensive investigation, in consultation with mechanical consultants and FortisBC, that identified deficiencies and opportunities for optimization in the EME’s energy systems and controls. The identified solutions were then implemented in FY 23-24.

To address high concerns of energy usage and poor temperature control, the responsiveness of the building controls was enhanced. This eliminated instances of the building’s heating and cooling operating at the same time, improving energy efficiency and addressing temperature control deficiencies. The project was completed in September 2023 and will be monitored to measure achieved energy savings.

To identify inefficiencies and opportunities in the Library, in order to enhance the performance of existing equipment while requiring minimal repairs and upgrades. The assessment will also highlight opportunities for potential retrofits to improve overall energy efficiency and functionality.

Campus-wide decarbonization

The energy team manages several projects to improve the campus District Energy System and decarbonize at a campus-wide level.

An energy “cluster plant” in the x̌əl sic snpax̌nwixʷtn building will have the potential to provide heating and cooling to several additional buildings with the addition of water source heat pumps. Existing buildings that could one day be served by this system include Administration, Arts, Gym and Hangar, Creative and Critical Studies, and Reichwald Health Sciences Centre.

A Campus as a Living Lab (CLL) initiative that aims to analyze the performance of the campus’s District Energy System plant to identify opportunities to optimize system performance at a campus-wide level.

Installation of 1.5 MW CO₂ Air Source Heat Pump to reduce the reliance of the District Energy System on gas-fired boilers. This project, which is expected to achieve significant decarbonization, is expected to be completed by early 2025.

Thermal Energy Storage (TES) units are under consideration for both the 4-pipe cluster plant in the x̌əl sic snpax̌nwixʷtn building as well as the District Energy System. The use of Thermal Energy Storage (TES) can reduce peak electrical demand charges as well as the amount of equipment required to manage peak loads.

A cluster plant design similar to the one being implemented in the x̌əl sic snpax̌nwixʷtn building is being considered for campus residence buildings as the campus grows. A study has been completed to determine the feasibility and cost of this project.

The return water temperature for Boiler 1 in the Geo-exchange building has been adjusted, increasing the boiler’s efficiency by 8-10% and resulting in approximately 750 GJ of gas savings per year.

Campus-Wide Infrastructure Improvements

A number of infrastructure improvements are underway to support the campus as it grows and develops.

Installation of outdoor and indoor PM2.5 particulate matter sensors as well as building static pressure monitors on campus, in order to measure air quality at the UBCO campus. A handheld PM2.5 meter was also purchased. The Energy Team and Health, Safety and Environment continue to monitor data received to determine the campus’s success at responding to changing air quality during wildfire events, and have installed additional sensors in academic buildings since the project began.

Led by the Energy Team, a campus-wide electrical study was completed to develop a strategy to support the campus’s future needs. The study was completed and presented in 2023.

Energy Efficiency and Building Decarbonization

In addition to exploring decarbonization options at a campus-wide scale, the energy team manages several initiatives to increase energy efficiency and greenhouse gas savings related to individual buildings.

Improved ventilation in multiple labs in several buildings. Labs have been upgraded, or upgrades are underway, in the following buildings:

  • EME (in progress): adjusting set points and installing motion sensors to adjust air flow based on room occupancy. Upgrades are in response to reports identifying deficiencies in HRV and strobic fume exhaust equipment.
  • Science (completed): implemented demand-controlled ventilation and lab-sensing technologies, as well as upgrading multiple fume hoods.
  • Arts and Science (completed): implemented demand-controlled ventilation. The university received a FortisBC rebate of $30,000 to complete this project, which is expected to save about 1500GJ of natural gas and 240 MWh of electricity per year. Completed in 2023.
  • Fipke (completed): Upgraded controls equipment and strategies to standardize air change rates in labs. The university received $90,000 in funding from FortisBC to complete this project, which is expected to save 2,677 GJ of natural gas and over 541 MWh electricity per year. Completed in 2023.

Increasing the efficiency of heating in the Science building by using heat recovered from exhaust air to pre-heat water used by the Water Source Heat Pumps. This project is estimated to save 1,500 GJ of natural gas and 70 tons of C0₂ equivalent emitted per year, as well as $20,000 in heating costs per year. This project is currently being implemented.

Assess multiple controls upgrades and end-of-life equipment replacements that could be initiated to further decarbonize the building’s operation.

Updated the air handler unit that serves the Commons lecture theatre from 24/7 operation to a schedule based on room occupancy, resulting in savings of approximately 150 MWh electricity per year.

Replaced inefficient high-pressure sodium lighting with LED lighting and dimmable controls, resulting in electricity savings of 150 MWh per year.

Developed a sequence of operations to enable a night-time flush in buildings. This procedure pre-cools buildings in order to reduce loads on mechanical cooling systems and delays the cooling peak to later in the day, increasing energy efficiency.