Preserve ACQ – (Alkaline copper quaternary)
Alkaline copper quaternary (ACQ) is a wood preservative formulation made of soluble copper and a quaternary compound. Copper has been used for centuries to control fungi, and is highly effective against most forms of fungi that feed on wood.
Preserve CA – (Copper azole)
Copper azole (CA type C) is a wood preservative formulation made of soluble copper and uses organic triazoles (tebuconazole and propiconazole) as the co-biocide to control copper-tolerant fungi.
Preserve is Building Code Compliant
- Preserve ACQ and Preserve CA have been standardized by The American Wood Protection Association (AWPA) for ground-contact and above-ground applications.
- Each Preserve formulation is building code compliant (2012 IBC/IRC) under AWPA Use Categories U1, UC3B, UC4A, and UC4B and meets all applicable major model building code requirements. Click here for AWPA information on how to specify treated wood.
- In Canada, Preserve ACQ is building code compliant (CSA-O80) and meets all applicable major model building code requirements in Canada
- Download the Residential Wood Deck Construction Guide
Portions of this content sourced from http://treatedwood.com/products/preserve/
Borates are essential to all higher plants. They are routinely applied in agriculture when soils are deficient to improve crop yields and quality. There are scientific studies indicating biological importance to animals and humans.
Biostatic: Sufficient concentrations of borates can inhibit the growth of bacteria and fungi and protect against damage by wood destroying insects. For this reason, borates are widely used to improve the durability of wood and wood based construction products. They are also used in the formulation of some insecticidal products.
Buffering: Borates can serve to balance acidity and alkalinity. This property is made use of in both industrial processes and consumer products.
Glass-Forming: Borates modify the structure of glass to make it resistant to heat or chemical attack. They can also lower the melting temperature of glasses to facilitate the production of durable fiberglass, specialty glasses, and ceramic glazes. Borate glasses are important components in modern TV, computer, and mobile device display panels.
Cross-linking: Borates react with suitable alcohols and carbohydrates to link them together. This effect is used to produce starch adhesives and fluids used in oil recovery. Related chemistry also provides the basis for the essential biological roles of boron.
Anticorrosion: Borates passivate ferrous and other metal surfaces to reduce their susceptibility to corrosion. This property is utilized in anticorrosive coatings, lubricants, industrial water systems, and automotive coolants.
Fire Retarding: Borates are used as fire retardants for polymers and cellulosic materials, such as cotton batting, wood, and cellulose insulation. Specialized borate compounds, such as zinc borates, are used as fire retardants and smoke suppressant additives in polymers.
Metallurgical: Borates are excellent fluxes used to remove oxide impurities from metals. Boron is also added to steel and aluminum to produce especially hard and corrosion resistant alloys. Borates find many specialized metallurgical uses, including the production of super strong magnets. Borates are also used to stabilize metallurgical slags to divert them from landfills into useful applications.
Detergency and Cleaning: Borates improve the performance of cleaning products by buffering and conditioning wash water. They inhibit the corrosion of washing machine parts. In addition, perborates can provide a convenient source of active oxygen for non-chlorine bleaching and stain removal.
Nuclear Shielding: Boron is unique among the light elements in its ability to capture neutrons, due to the natural presence of the 10B isotope of boron (~20% natural abundance). This radiation absorbing effect is utilized in the shielding, control, and safety of nuclear reactors and in medical therapeutics. Boron neutron capture therapy (BNCT) is an experimental treatment for cancers and other diseases in which neutron capture is harnessed to perform effective microsurgery.
Spectroscopic: Borates absorb infrared light. Incorporated into building products, such as insulation fiberglass, borates improve energy efficiency by preventing heat loss through infrared transmission. This effect can also be utilized in plastics, coatings, and other materials.
Synthesis: In addition to the above mentioned physical and chemical effects, borates are used as starting materials in the manufacture of a wide range of advanced materials and specialty chemicals. These include super hard ceramics, boron halides, hydrides, and esters, to name only a few.
For more on Borates, visit www.borax.com.
Portions of this content sourced from http://www.borax.com/about-borates/borates-by-function
Chemonite® Wood: Product Applications
Chemonite® wood is especially appropriate for industrial, utility, marine, and heavy construction applications, particularly those where coastal Douglas fir or other refractory species are used or where longevity is a concern. Typical applications include:
- Utility poles – distribution & transmission
- Building poles
- Foundation piling
- Marine piling – fresh or saltwater
- Sawn timbers or supporting columns used for bridges, barns, decks or other uses
- Agricultural posts
- Post frame construction
- Highway construction
- Railroad ties
Download a Chemonite® Wood Specification Guide
Portions of this content sourced from: http://www.wolmanizedwood.com/Products/Preservative/Chemonite/applications.htm