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Non-Pressure Treated Wood

For most treated wood, preservatives are applied in special facilities using pressure. However, sometimes this isn’t possible, or the need for treated wood was not apparent until after construction or building occupancy. In those cases, preservatives can be applied using methods that do not involve pressure vessels.

Some of these treatments can only be done by licensed applicators. When using wood preservatives, as with all pesticides, the label requirements of the Pest Management Regulatory Agency (in Canada) or the EPA (in the USA) must be followed.

Five categories of non-pressure treatments

Treatment during Engineered Wood Product Manufacture

Some engineered wood panel products, such as plywood and laminated veneer lumber (LVL) are able to be treated after manufacture with preservative solutions, whereas thin strand based products (OSB, OSL) and small particulate and fibre-based panels (particleboard, MDF) are not. The preservatives must be added to the wood elements before they are bonded together, either as a spray on, mist or powder.

Products such as OSB are manufactured from small, thin strands of wood. Powdered preservatives can be mixed in with the strands and resins during the blending process just prior to mat forming and pressing. Zinc borate is commonly used in this application. By adding preservatives to the manufacturing process it’s possible to obtain uniform treatment throughout the thickness of the product. 

In North America, plywood is normally protected against decay and termites by pressure treatment processes. However, in other parts of the world insecticides are often formulated with adhesives to protect plywood against termites.

Surface pre-treatment

This is anticipatory preservative treatment applied by dip, spray or brush application to all of the accessible surfaces of some wood products during the construction process. The intent is to provide a shell of protection to vulnerable wood products, components or systems in their finished form. One example would be spraying house framing with borates for resistance to drywood termites and wood boring beetles in some cases. Such treatments may also be applied to lumber, plywood and OSB to provide additional protection against mould growth.

Sub-surface pre-treatment (Depot treatment)

This is preservative treatment applied at discrete locations, not to the entire piece, during the manufacturing process or during construction. The intent is to pro-actively provide protection only to the parts of the wood product, component or systems that might be exposed to conditions conducive to decay. One example would be placing borate rods into holes drilled in the exposed ends of glulam beams projecting beyond a roof line.

Supplementary treatment

This is preservative treatment applied at discrete locations to treated wood in service to compensate for either incomplete initial penetration of the cross section, or depletion of preservative effectiveness over time. The intent is to boost the protection in previously-treated wood, or to address areas exposed by necessary on-site cutting of treated wood products. One example would be the application of a ready-made bandage to utility poles that have suffered depletion of the original preservative loading. Another example is field-cut material for preserved wood foundations.

Remedial treatment

This is preservative treatment applied to residual sound wood in products, components or systems where decay or insect attack is known to have begun. The intent is to kill existing fungi or insects and/or prevent decay or insects from spreading beyond the existing damage. One example would be roller or spray application of a borate/glycol formulation on sound wood left in place adjacent to decayed framing (which should be cut out and replaced with pressure-treated wood).

Formats of non-pressure treatments

Non-pressure treatments come in three different forms: solids, liquids/pastes, and fumigants. Unlike pressure-treatment preservatives, which rely on pressure for good penetration, these rely on the mobility of the active ingredients to penetrate deep enough in wood to be effective. The active ingredients can move in the wood via capillarity or can diffuse in water and/or air within the wood. This mobility not only allows the active ingredients to move into the wood but can also allow them to move out under certain conditions. This means the conditions within and around the structure must be understood so the loss of preservative and consequent loss of protection can be minimized. Borates, fluorides and copper compounds are particularly suitable for use as solids, liquids and pastes. Methyl isothiocyanate (and its precursors), methyl bromide, and sulfuryl fluoride are the only widely used fumigant treatments. Methyl bromide was phased out, except for very limited uses, in 2005.

Solids

The major advantage of solids in these applications is that they maximize the amount of water-soluble material that can be placed into a drilled hole, due to the high percentage of active ingredients contained in commercially-available rods. The major disadvantage is the requirement for sufficient moisture and the time needed for the rod to dissolve. The earliest and best-known solid preservative system is the fused borate rod, originally developed in the 1970s for supplementary and remedial treatment of railroad ties. These have since been used successfully on utility poles, timbers, millwork (window joinery), and a variety of other wood products. A mixture of borates is fused into glass at extremely high temperatures, poured into a mould and allowed to set. Placed into holes in the wood, the borate dissolves in any water contained in the wood and diffuses throughout the moist region. Mass flow of moisture along the grain may speed up distribution of the borate. Secondary biocides such as copper can be added to borate rods to supplement the efficacy of the borates against decay and insects. While all preservatives should be treated with respect, many users feel more comfortable dealing with borate and copper/borate rods because of their low toxicity and low potential for entry into the body.

Fluorides are also currently available in a rod form. The rod is produced by compressing sodium fluoride and binders together, or by encapsulation in a water-permeable tubing. Fluorides diffuse more rapidly than borates in water and may also move in the vapour phase as hydrofluoric acid.

Zinc borate (ZB) is a powder used to protect strand-based products. It is blended with the resins and stands during the manufacturing processes for OSB and other strand based products becomes well dispersed throughout. Zinc borate has very low water solubility and can protect strand based products from decay and termites.

Liquids, Pastes and Gels

Liquids can be sprayed or brushed on to surfaces, or poured or pumped into drilled holes. Pastes are most often brushed or troweled on, then covered with polyethylene-backed kraft paper creating a “bandage.” Pastes can also be packed into drilled holes or incorporated into ready-to-use bandages for wrapping around poles. Borates and fluorides are commonly used in these formulations because they diffuse very rapidly in wet wood. Copper moves more slowly because it reacts with the wood. For dryer wood, glycols can be added to borate formulations to improve penetration. Over-the-counter wood preservatives available for brush application are based on either copper naphthenate (a green colour), or zinc naphthenate (clear). Both are dissolved in mineral spirits-type solvents. In addition, water-borne borate/glycol formulations can also be purchased over-the-counter as roll-on liquids.

Fumigants

These treatments are typically delivered as liquids or solids; they change to a gas upon exposure to air, and become mobile in the wood as a gas. Some solid and liquid fumigants are packed in permeable capsules or aluminum tubes. Methyl isothiocyanate (MIT), and chemicals that produce this compound as they break down, are used for utility poles and timbers. This compound adsorbs to wood and can provide several years of residual protection. Sulfuryl fluoride and methyl bromide are used for tent fumigation of houses to eradicate drywood termites.

Repairing Cuts in the Treated Shell

Pressure-treated wood in the ground can undergo significant internal decay within just six or seven years if cuts, bolt holes and notches are not brush treated with a field-cut preservative. Common over-the-counter agents for this purpose include copper naphthenate (a green colour), or zinc naphthenate (clear). Both are dissolved in mineral spirits-type solvents. Other brush-on agents include water-borne borate/glycol formulations which can also be purchased at building supply outlets.

Forgetting this critical step will almost certainly shorten the life span of the product and will void any warranties on the product. Although brush-on application of wood preservatives isn’t nearly as effective as pressure-treatment, the field-cut preservatives are usually applied to the end grain, whereby the solution will soak in further than if applied to the side grain.

In FPInnovations’ field tests of these preservatives, copper naphthenate performed best. Zinc naphthenate (2% zinc), which is colourless, was not as effective but may be suitable for above-ground applications where the decay hazard is lower and if the dark green colour of copper naphthenate is undesirable. Note that the dark green of the copper-based product will fade after a few years.

Article

Preservative-treated wood is typically pressure-treated, where the chemicals are driven a short distance into the wood using a special vessel that combines pressure and vacuum. Although deep penetration is highly desirable, the impermeable nature of dead wood cells makes it extremely difficult to achieve anything more than a thin shell of treated wood. Key results of the pressure-treating process are the amount of preservative impregnated into the wood (called retention), and the depth of penetration. These characteristics of treatment are specified in results-based standards. Greater preservative penetration can be achieved by incising – a process that punches small slits into the wood. This is often needed for large or difficult to treat material to meet results-based penetration standards.

Pressure treatment processes vary depending on the type of wood being treated and the preservative being used. In general, wood is first conditioned to remove excess water from the wood. It is then placed inside a pressure vessel and a vacuum is pulled to remove air from inside the wood cells. After this, the preservative is added and pressure applied to force the preservative into the wood. Finally, the pressure is released and a final vacuum applied to remove and reuse excess preservative. After treatment some preservative systems, such as CCA, require an additional fixation step to ensure that the preservative is fully reacted with the wood.

Information on the different types of preservatives used can be found under Durability by Treatment

Article

Ottawa, Ontario – September 17, 2024 — The Canadian Wood Council (CWC) and Woodsure (A division of Axis Insurance Managers Inc.) are pleased to announce a new partnership between their WoodWorks and Woodsure programs respectively. This strategic collaboration is expected to help support the increased adoption of wood construction in Canada.

The positive influences of design innovation, advanced materials, new building codes, and the evolving priorities of society are driving change in the construction sector; in particular, these influences are driving the expanded use of advanced wood construction.

However, as with the adoption of any new technology, perceived unknowns can create barriers that need to be to overcome. One such barrier is access to insurance for this new class of technologically advanced wood buildings.

This partnership aims to empower architects, builders, and developers to choose wood with confidence, knowing they have access to robust insurance solutions that understand the complexities of wood construction. Together, we can significantly enhance the acceptance, safety, and growth of mass timber construction, recognizing it as a strategically preferred material for sustainable building practices.

Statements from Key Stakeholders

Rick Jeffery, President & CEO, Canadian Wood Council:

“We are thrilled to welcome Woodsure as a partner of our WoodWorks program. This collaboration is a natural extension of our mutual commitment to supporting wood construction, fostering growth of the wood construction sector, and encouraging increased adoption of sustainable building practices. By combining our efforts, we are confident that this partnership will have a positive impact on the industry.”

Roland Waldmeier, National Senior Vice President, Construction, Contracting, and Real Estate, Axis Insurance Managers Inc.

“We believe that insurance should not only keep pace with, but also actively support, the mass timber and wood frame industries. These sectors are vital to both social and economic objectives in Canada. Therefore, it is important for us to continually develop innovative insurance solutions that foster growth in the Canadian wood industry. By providing the necessary capacity, we make it easier for projects to secure the coverage they need.”

Connie Rowley, Senior Vice President, Woodsure:

“Supporting the mass timber industry with specialized insurance products is crucial for accelerating the adoption of wood construction. By offering tailored insurance solutions, insurers can provide the necessary capacity and confidence for developers to invest in mass timber projects. This support not only mitigates financial risks, but also fosters innovation and sustainability in construction. Enhanced insurance products can address concerns related to fire safety, structural integrity, and long term reliability, thereby reassuring stakeholders and encouraging broader acceptance of this eco-friendly building material. Consequently, this leads to a more sustainable construction industry and helps in reducing the carbon footprint.”

Article

Wood WORKS! BC has released a new educational video, Fire Performance Demonstration Workshop 2.0 – Understanding fire design: applications. Changes to the NBCC mean new considerations for fire, with Encapsulated Mass Timber Construction (EMTC) in tall buildings as a new construction type in the code. This video provides an overview of a Wood WORKS! BC workshop at the City of Surrey Fire Department Training Facility which demonstrates fire performance with a live burn of three large demonstration boxes, including one of mass timber, and summarizes the learning outcomes essential for understanding taller and larger wood building fire requirements. CLICK HERE TO VIEW THE VIDEO.

Article

en anglais seulement

Forest Industry Applauds Government for Facilitating Tall Wood Construction                                           

Edmonton, January 24, 2020 – The Alberta Forest Products Association (AFPA) and Wood WORKS! Alberta congratulate the Government of Alberta for becoming the first jurisdiction in Canada to permit 12 storey wood buildings province-wide.

This change raises the permissible limit for wood buildings in Alberta from 6 to 12 storeys.

“The Government of Alberta is to be commended for taking action to promote Alberta jobs and support local business,” said Paul Whittaker, President and CEO of the AFPA. “By becoming a leader in wood construction, we are adding value to our resources right here. We are also creating public spaces and homes that Albertans will cherish for generations.”

“This is a tremendous step forward for Alberta,” said Rory Koska, Program Director for Wood WORKS! Alberta. “We have seen tall wood buildings sprouting up around the world. With the innovations in wood construction, building taller with mass wood will provide an economic and environmentally responsible option for builders and developers. This announcement will bring an exciting change to the architectural landscape across Alberta.”

Facts About Tall Wood Construction

  • Tall wood construction in Alberta has the potential to consume $40 million of locally produced lumber each year.
  • The market for wood buildings of 7 to 12 storey buildings, in Canada, is approximately 27 million square feet.
  • Since many components of tall wood buildings are prefabricated offsite, wood buildings can be assembled more quickly, with less noise and disruption to neighbours.
  • The world’s tallest wood building is the 18 storey, 85.4 metre Mjøstårnet Tower in Norway.
  • Wood products store carbon absorbed by the trees while growing. As a low-carbon material, wood has significant potential to reduce the overall greenhouse gas emissions of the building sector.
  • Tall wood construction is safe. Wood buildings must meet or exceed the safety requirements for buildings constructed of materials like concrete and steel.

Contact:

Brock Mulligan
Director of Communications
Alberta Forest Products Association
p) 780.239.6890
e) [email protected]

Barbara Murray
Communications Co-ordinator
Wood WORKS! Alberta
p) 780.392.0761
e) [email protected]

Article

Edmonton, January 24, 2020 – The Alberta Forest Products Association (AFPA) and Wood WORKS! Alberta congratulate the Government of Alberta for becoming the first jurisdiction in Canada to permit 12 storey wood buildings province-wide.

This change raises the permissible limit for wood buildings in Alberta from 6 to 12 storeys.

“The Government of Alberta is to be commended for taking action to promote Alberta jobs and support local business,” said Paul Whittaker, President and CEO of the AFPA. “By becoming a leader in wood construction, we are adding value to our resources right here. We are also creating public spaces and homes that Albertans will cherish for generations.”

“This is a tremendous step forward for Alberta,” said Rory Koska, Program Director for Wood WORKS! Alberta. “We have seen tall wood buildings sprouting up around the world. With the innovations in wood construction, building taller with mass wood will provide an economic and environmentally responsible option for builders and developers. This announcement will bring an exciting change to the architectural landscape across Alberta.”

Facts About Tall Wood Construction

  • Tall wood construction in Alberta has the potential to consume $40 million of locally produced lumber each year.
  • The market for wood buildings of 7 to 12 storey buildings, in Canada, is approximately 27 million square feet.
  • Since many components of tall wood buildings are prefabricated offsite, wood buildings can be assembled more quickly, with less noise and disruption to neighbours.
  • The world’s tallest wood building is the 18 storey, 85.4 metre Mjøstårnet Tower in Norway.
  • Wood products store carbon absorbed by the trees while growing. As a low-carbon material, wood has significant potential to reduce the overall greenhouse gas emissions of the building sector.
  • Tall wood construction is safe. Wood buildings must meet or exceed the safety requirements for buildings constructed of materials like concrete and steel.

Contact:

Brock Mulligan
Director of Communications
Alberta Forest Products Association
p) 780.239.6890
e) [email protected]

Barbara Murray
Communications Co-ordinator
Wood WORKS! Alberta
p) 780.392.0761
e) [email protected]

Article

The Canadian Wood Council (CWC) applauds Premier John Horgan’s announcement today at the BC Council of Forest Industries (COFI) annual convention to choose wood construction wherever possible for public sector buildings.  Read the press release.

Article

The Canadian Wood Council (CWC) applauds the Government of British Columbia’s announcement today in support of opportunities in the province for forest communities and innovative low-carbon solutions such as tall wood construction. Read the press release.

Article

Article by Len Garis and Karin Mark.

When assistant deputy fire chief Ray Bryant heard about construction of the tallest wood building in the world in Vancouver, his reaction was predictable. “I thought it was an insane idea,” Bryant said. But once Bryant learned about the compartment-style construction of the student residence at the University of British Columbia, his opinion changed. “I couldn’t believe how safe it is,” he said. Read the article.

Article

Canadian Wood Council Applauds Announcement of the Origine Project.

Click here to read Press Release

Article

The American Wood Council (AWC) and the Canadian Wood Council (CWC) have announced the release of two new environmental product declarations (EPDs) for cellulosic fiberboard and laminated strand lumber (LSL), bringing the available EPDs for North American wood products to 11. Read the press release and check out the EPDs.

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