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The Rural Voice, 2019-03, Page 69 Wood has been a primary construction material for centuries. While it continues to be used commonly in conventional stick frame construction, there has been a trend towards use of other materials such as steel and concrete in many applications. According to two speakers at the recent annual conference of Forests Ontario there’s good reason now to consider wood instead of (or along with) concrete and steel for many construction projects, including multi-storey and commercial buildings, or even small bridges. John Pineau, the Provincial Leader of FPInnovations in Ontario talked about a bridge recently built at the Petawawa Research Forest north of Ottawa. The intent of the bridge is to demonstrate wood construction as an alternative to other materials for use in forest access roads or even by municipalities. Pineau first talked about the much lower carbon footprint of wood compared to other materials. In fact, use of wood actually creates a net sequestration of carbon, while other materials such as steel and concrete may cause a net release of carbon into the atmosphere. He used the example of a cubic metre of wood (which is roughly equivalent to 118 - 2 x 4s, 8 feet long). In production of the wood, trees actually sequester 780 kg of Carbon Dioxide (CO2). For that cubic metre of wood there is CO2 released to the atmosphere through harvest of the trees (10 kg), hauling (7 kg) and milling (32 kg). That results in a net sequestration of 731 kg of CO2 per cubic metre, as long as the wood remains in use in whatever is built. Pineau says the wooden bridge (constructed of prefabricated, engineered wood components) is comparable in both cost and expected life span to an equivalent steel bridge. At roughly 43 feet long and 16 feet wide it meets all standards required and will handle fully loaded logging trucks or heavy military equipment. In addition, the construction and installation process was completed more quickly and at lower cost than for a comparable steel bridge. David Moses, Principal of Moses Structural Engineers, says he sees a shift in building techniques towards greater use of wood, with potential positive environmental impacts. One reason he sees for this happening is the advances in engineered wood products that have happened over the past 40 years. He listed a number of advances, including: nailed laminated decking, improved connectors for timbers, improved machining and CNC techniques, improved adhesives and techniques in manufacturing glue- laminated timbers, development of LVL (laminated veneer lumber), timberstrand products and production of cross- laminated timbers. Also contributing to the trend is recognition of these advanced products and improved wood construction techniques in building codes. For example, the Ontario Building Code was amended in 2012 to allow for construction of wood buildings up to six storeys high. This is humorous in some ways as there are several seven or eight storey wooden buildings in Toronto that are 100 years old. There are much higher recently built wooden buildings elsewhere, including one 13 stories high in Quebec City and the 18- storey Brock Commons building in BC, with other, even higher buildings being planned at various locations. Moses says much of the efforts to reduce carbon emissions from buildings has focused on reducing energy use for heating and cooling. He says there is also large potential for reducing carbon emissions through use of construction materials March 2019 65 Wood is a strong and carbon- positive building material Steve Bowers is a forester, forest owner and member of the Ontario Woodlot Assoc. Woodlots ZZZVYFDRQFD &216(59$7,21 )25(675<6(59,&(6 )RUHVW0DQDJHPHQW3ODQV 0)7,3 7UHH3ODQWLQJ :RRGORW,QYHQWRULHV 7UHH0DUNLQJ  'RQQD/DFH\(PDLOGODFH\#VYFDRQFD