Exterior winter shot in the mountains of a snow-covered lodge with glulam beams supporting the roof.

Thermal performance

Whistler Day Lodge | Photo credit: KK Law

Wood is a natural insulator

Wood has a lower thermal conductivity compared to concrete, steel-frame and masonry construction and is ideally suited to energy-efficient design. As a natural insulator, it provides some of the world’s coldest climates with warm and comfortable dwellings.

Façade of post-and-beam recreational facility built into the slope of Mount Washington against a backdrop of a snowy mountain and trees.

At home with the thermal benefits of wood

Wood is used in the vast majority of single-family homes and multi-family projects up to six storeys in Canada and for good reason—it’s adaptable to virtually any climate, can be tailored to handle wind and snow loads and is a natural insulator reducing heating and cooling costs. Softwood has about 10 times the thermal insulating ability of concrete and masonry, and 400 times that of solid steel. Unlike concrete and steel, wood’s natural insulating qualities (external link) mean it does not need a thermal break between the structural and exterior envelope.

New energy codes and standards mean wood construction is getting even more energy efficient. Wood and light-frame construction’s versatility offers more insulation options not readily available for other construction types. This includes deeper wall cavities, increased thermal mass (external link), wood-fibre panels and installation outside the framing spaces.

Vancouver Island Mountain Centre | Photo credit: Bob Matheson, courtesy of HDR

Exterior afternoon view of completed BC Passive House Factory, a low rise passive house structure built with light frame and mass timber components, showing wrap around exterior wood slats, wooden walkway, and decorative wooden fencing

Wood’s prefabricated, Passive House advantage

Prefabrication of wood buildings in factory settings can further improve thermal performance by delivering a precise fit that is tested and airtight. With these new approaches, wood buildings are meeting and exceeding the requirements of new energy and voluntary programs, such as Passive House.

Passive House (Passivhaus) is considered to be the most rigorous voluntary energy-based standard in the design and construction industry today. It is a holistic approach to energy efficiency that considers all aspects of a structure. This includes data on local weather and solar orientation along with design, foundation, framing, and insulation systems to reduce or even eliminate thermal bridging (external link). This means using building materials that have low thermal conductivities.

By nature, wood is ideal for this, made up of thousands of open cells that make it difficult to conduct heat. Furthermore, highly energy efficient, airtight buildings can be achieved using prefabricated timber building systems cut and assembled with precision within a controlled environment. Unnecessary framing is eliminated and replaced with insulation to optimize energy performance. Dense recycled wood fibre panels can replace conventional insulation while providing sound reduction while boosting thermal mass.

BC Passive House Factory | Photo credit: Ema Peter Photography

Interior daytime view of Wood Innovation Research Lab showing the large internal space for students and researchers to test state-of-the-art building systems and to study ways to integrate wood into more structural designs for industrial buildings
Interior daytime view of Wood Innovation Research Lab showing the large internal space for students and researchers to test state-of-the-art building systems and to study ways to integrate wood into more structural designs for industrial buildings

New energy-efficient opportunities with mass timber

Mass timber construction uses large prefabricated wood members such as cross-laminated timber (CLT) for wall, floor and roof construction. Glue-laminated timber (glulam) can also be used as beams and columns. Like all wood products, mass timber has good thermal properties and the added thickness provides both insulation and thermal mass. While thermal mass is typically associated with concrete or masonry buildings; mass timber has considerable thermal mass that can offer some whole-building energy benefits (external link).

One example is the University of Northern British Columbia’s Wood Innovation Research Lab (WIRL), the first industrial facility tested and certified to the International Passive House standard in Canada. Constructed using a glulam post and beam system and unique high-performance standing truss wall assembly, the building serves as a research and testing facility for University faculty and students. Sophisticated sensors and thermal monitoring showed significant energy savings.

For projects targeting net-zero energy or other stringent energy performance criteria, mass timber can store solar heat energy during the day and release it at night, reducing energy loads. Hybrid building systems, combining mass timber, concrete or masonry can further boost the energy efficiency (external link) of wood buildings.

Wood Innovation Research Lab | Photo credit: Michael Elkan Photography

Tall stacks of lumber on pallets.

Looking for wood suppliers?

B.C. Wood Supplier Directory connects you with over 400 suppliers of high-quality, eco-friendly wood products, from dimension lumber, engineered, mass timber and specialty products, to furniture, doors and windows, pulp, paper and pellets.

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