Energy Projects

ÂÜÀòÉäÇø Solar panels
ÂÜÀòÉäÇø Solar panels

ÂÜÀòÉäÇø is a national leader in bioenergy and has made great strides towards energy conservation and reduction of fossil fuel use.  Our many energy initiatives include the Bioenergy Plant, the Sustainable Communities Demonstration Project, lighting upgrades and energy-saving Passive House architecture

Wood Pellet Project 

In the spring of 2009, ÂÜÀòÉäÇø installed Canada’s first university-owned wood pellet heating system. With much higher energy efficiency than the previous fossil fuel-based heating system, this project reduces emissions by 140 tons of CO2/year. The facility also serves as a valuable demonstration site for public education, with more than 700 political leaders, industry officials, and community residents visiting during the first year alone.  

Biomass Gasification Project  

ÂÜÀòÉäÇø’s biomass gasification system began heating the Prince George campus in March 2011. The system supplies heat to the core campus buildings and offsets about 85% of previous fossil fuel consumption. This $15 million project was funded by the federal and provincial governments, and hog fuel is provided by Lakeland sawmill located in Prince George. In addition to being carbon-neutral, the cost of acquiring hog fuel is only about 35% of the cost of natural gas.   

ÂÜÀòÉäÇø’s bioenergy plant won the Best Campus Case Study Award from The Association for the Advancement of Sustainability in Higher Education (AASHE) in 2011. The plant is also certified to the prestigious LEED Platinum standard and emits among the lowest emissions of any bioenergy plant in North America. As an additional sustainability benefit of the Bioenergy Plant, ash resulting from the process is collected and used as a fertilizer at a local farm. 

Free cooling  

Our facilities staff has identified several opportunities to bring in cool outdoor air rather than run air conditioners to keep campus electrical equipment cool.  Working with the Energy Manager and local engineering consultants, we have been able to implement these initiatives to save both electricity and potable water for cooling. A recent example is the free cooling project that was completed in 2020 for the data centre in the Administration Building. 

Sustainable communities demonstration project  

In 2014, ÂÜÀòÉäÇø began work on the Sustainable Communities Demonstration Project (SCDP), which further expanded our bioenergy supply on campus. The SCDP involved installing a low-temperature district heating system that connected our student housing, daycare, Enhanced Forestry Lab, and take-offs for future buildings, with the existing biomass gasification plant. The SCDP is built with future expansion in mind; opportunities such as installing low-temperature heating options (e.g. geothermal), or a food producing greenhouse may be achievable with this new infrastructure.  

 The SCDP became operational in September 2016, when the first of ÂÜÀòÉäÇø’s student housing was switched over to bioenergy. In the summer of 2017, ÂÜÀòÉäÇø’s second housing building and the daycare were also switched over to bioenergy. 

Lighting upgrades  

ÂÜÀòÉäÇø has completed several lighting upgrade projects in partnership with BC Hydro since the Energy Management program began in 2010. Lighting upgrades are done by area, where significant savings are obtained from replacing older technology such as fluorescent tubes with LED lighting. In addition, motion sensors, scheduling, and network controls are integrated as part of these upgrades to optimize energy savings. 

Continuous optimization 

Working with BC Hydro and an external consultant, ÂÜÀòÉäÇø has seen significant energy reductions through the Continuous Optimization Program. The program involves investigating existing building systems to identify opportunities for optimization and energy savings. The first round of the program took place between 2013 and 2017, tackling nine buildings on campus. Eight of those nine buildings were selected for a second round of the program, which was completed in 2023. 

Heat exchanger upgrades 

ÂÜÀòÉäÇø is undertaking a multi-year series of heat exchanger upgrade projects. The main intent of the projects is to replace aging inefficient heat exchanger systems with newer more efficient systems. This entails replacing large inefficient plate-and-frame heat exchangers with smaller, more efficient brazed plate heat exchangers. Additionally, this often entails replacing large inefficient fixed speed pumps with fewer, smaller variable speed drive pumps. The redesigns can also entail decoupling systems so that they can be run independently, so for example, a pump can be switched off if its system is off where previously it might have been running all the time. The projects have also allowed for more efficient yet robust piping design, while also being maintenance friendly. All these tweaks, large and small, for each system that is upgraded, ultimately improve the efficiency of each system which will then result in less electricity and fuel demand. An additional important benefit is the lowering of the return water temperature (by allowing more heat transfer through temperature differential rather than higher flow rate) – it is anticipated that the lower return temperature will allow for the use of the primary district water loop for heat recovery.  

Electrification  

ÂÜÀòÉäÇø continues to investigate and implement electrification projects to help reduce fossil fuel consumption. A recent example that was completed was the installation of a hybrid heat pump system in the Maintenance Building in March 2024 to replace the previous aging and inefficient propane furnace. The heat pump will be used for cooling and heating, only backed up by propane in very cold ambient temperatures. 

ÂÜÀòÉäÇø Solar panels 

ÂÜÀòÉäÇø has 25 solar panels (16 of which were donated from the Highglen Montessori Elementary School and School District 57) on the roof of the Conference Centre (Building 6) which produces roughly 5000 kilowatts of electricity per year which is about $1100 worth of electricity. On a good day with maximum sunshine, it can power 145 laptops at one point in time. Most houses use roughly 10,000 kwh over the course of a year. 

Passive House Buildings 

In July 2018, ÂÜÀòÉäÇø completed work on the Wood Innovation Research Lab (WIRL), a Passive House certified laboratory that promotes research excellence in wood engineering. As an industrial building in a northern climate with a large bay door for deliveries and a sophisticated dust-extraction system, WIRL itself is an engineering marvel – and the first of its type to exceed the exacting international standard. Certified Passive House buildings use up to 90 per cent less energy for heating and cooling when compared with standard buildings and use up to 70 per cent less energy overall. WIRL set a new standard for air tightness, securing the second best North American result of any building using the internationally recognized passive house standard. The testing protocol involves both pressurizing and depressurizing the building and measuring the number of air changes per hour that result. With a score of 0.07, WIRL surpassed the Passive House requirement by nearly a factor of 10. 

In April of 2021, the Facilities Management Building, the newest building established on ÂÜÀòÉäÇø’s Prince George campus, earned the prestigious Passive House designation. This is the second successful Passive House certified build for ÂÜÀòÉäÇø.