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P.O. Box 829 Quakertown, PA 18951 Phone and Fax: 888.NADRA4U (888.623.7248) |
ACQ Wood Preservative and Fasteners—Are They Compatible?
Roofing systems contain treated wood in several applications, such as
wood blocking. For many years, wood treated with chromated copper
arsenate (CCA) preservative was the industry standard. Exterior wood is
subjected to all kinds of hazards: weather conditions, decay, fungi and
insect infestation. Over 80 years ago Dr. Karl Wolman invented a process
to treat and protect the wood from the environment. Using a pressurized
holding tank filled with wood and preservative, Wolman discovered a way
to force the preservative into the wood. This process, which has been
coined “Wolmanized,” increased the service life of wood used in outdoor
construction, such as roofing. Unfortunately, the process hasn’t been
without its share of challenges and changes.
In the beginning, CCA became the most commonly used preservative and was
employed for decades. However, the EPA raised environmental concerns
about the arsenic and chromium in CCA. Chromium is a heavy metal that
can leach into the soil, and depending on the dosage, arsenic can be a
lethal poison and is a carcinogen. The arsenic in CCA wood can become
airborne during sawing or burning. Raising other concerns is the
exposure to children using playground equipment constructed with
CCA-treated wood.
To address these environmental issues, researchers began experimenting
with other types of wood preservatives until they developed alkaline
copper quaternary (ACQ), which is the preferred preservative used today.
The main active ingredients in ACQ are copper oxide and a quaternary
ammonium compound, also referred to as quat, a fungicide that destroys
decay organisms such as fungi and termites.
Though this preservative mix has proven to be the most effective so far,
ACQ poses its own concerns. Similar to its predecessor, ACQ also leaches
into water tables and leach tests using ACQ wood in wetlands have shown
elevated levels of copper in rainwater run-off, soil and sediment. ACQ
doesn’t have the arsenic or chromium issues of CCA, but it does have
triple the amount of copper—a substantial increase.
Despite the problems and setbacks, wood and how it is fastened is a
critical part of the roofing process. Even today, researchers continue
to ensure that fasteners can stand up to the rigors of ACQ-treated wood.
The factors impacted by the preservation of wood are numerous and are
exacerbated by non-standardized testing, the types of metals used, and
the lack of long-term data collection.
Corrosion Impact
There are many years of field life experience with fasteners installed
into CCA-treated wood that show fasteners do have a long service life.
An added benefit of CCA is that it contains chromium, which is a
corrosion inhibitor. Exposing certain types of roofing fasteners to the
high amounts of copper in ACQ and additional amounts during leach-out of
the copper during rainfall causes a galvanic corrosion concern. The
potential of galvanic corrosion depends on the types of metals that are
in contact with each other. Another potential concern is the durability
of the typical coating on a fastener. When a coated fastener is
installed into a substrate such as wood there is a potential for the
abrasion to remove some of the protective coating. Small areas that are
missing coating can experience more galvanic corrosion than if there
were no coating on the fastener. The smaller the unprotected exposed
“anode” area is in relation to the larger “cathode” copper surface area
in ACQ wood can accelerate galvanic corrosion in the unprotected area.
This area can be located within the fastener threads.
Lack of Standard Testing
Testing conclusions can be stated as pass-fail criteria or they can show
hours of exposure during the test, creating doubt as to the answer to
the critical question of field service: How many years will the fastener
resist corrosion when installed in ACQ-treated wood? Another factor is
moisture. Galvanic corrosion can fluctuate widely depending on the
amount of moisture the fastener and ACQ wood are exposed to during their
service life. Predicting the amount of that moisture over the years of
service life is also problematic. Therefore, when reviewing the results,
all these aspects should be considered.
Types of Available Fasteners
Each product, presumably, has passed corrosion testing of some sort.
Testing has shown that some carbon steel and stainless steel fasteners
coated with proprietary coatings are effective in ACQ applications. This
harks back to the ACQ testing issue, because when it comes to
condensation, moisture or roof leaks, standardized testing is not able
to determine if the additional copper in ACQ will cause the screw hole
in the steel deck to corrode faster than when CCA is used and if it will
have an impact on wind uplift resistance. Ample field life history is
available for CCA wood used with steel decking.
Fasteners treated with a durable ACQ corrosion-resistant proprietary
coating have more of a safety factor than standard coated carbon steel
fasteners. However, all these factors make the fasteners more costly
than the fasteners used in CCA-treated wood. Wood preservative
manufacturers are working on formulaic changes to reduce the corrosive
reaction. Once these formulas are proven successful and receive EPA
approvals, cost reductions can be reviewed to bring down the cost of the
ACQ corrosion-resistant fastener. Many questions arise in regards to the
use of stainless steel fasteners perhaps because there are so many types
of stainless steel alloys.
Stainless Steel
The four basic types of stainless steel are martensitic, ferritic,
austenitic, and precipitation hardening. Martensitic is in the 400
series and contains more carbon and less chromium than the 400 series
ferritic type. When nickel is added and chromium is increased, the
stainless steel becomes austenitic and is then part of the 200 and 300
series. Ferritic 400 series stainless steel is magnetic, has low carbon
content, and contains 13 percent to 17 percent chromium. Precipitation
hardening is a heat-treating process that relieves stress, thus
increasing strength, ductility, and corrosion resistance by
precipitating certain compounds. Precipitation-hardened stainless steel
is similar to martenistic stainless steel and exhibits high strength and
hardness from heat-treating.
Passivation is an important factor in the corrosion resistance of
stainless steel. Passivation removes iron compounds from the surface of
stainless steel through a chemical surface-cleaning process. According
to testing and galvanic reaction charts, passivated stainless steel
surfaces are less corrosive then non-passivated.
Hot-dipped Galvanized
Testing Method
The ACQ extract test was used in these experiments because several
variables needed to be taken into account. First, one must drive the
fastener into wood to achieve the potential of removing any coating. The
fastener was removed from the wood to allow for maximum ACQ chemical
exposure. The ACQ chemistry was directly extracted from the ACQ-treated
wood by preparing a solution from ACQ wood chip leach-out achieving a
conductivity reading of ACQ 0.420 uS (+/-10 percent).
The fasteners were submerged into the ACQ extract solution to ensure
full exposure. The ACQ extract solution was aerated to keep the solution
churning and ensure oxygen was present in the system to facilitate
oxidation. Testing was conducted to evaluate fastener and steel deck
resistance to corrosion and the impact on pullout after the deck and
fastener were exposed to ACQ extract. A total of 54 fasteners were
submerged into the test tank. Eighteen designs of different coatings and
fastener materials were tested. Baseline pullouts were measured on
fasteners that were not exposed to ACQ extract. Corrosion and pullout
were evaluated after fasteners were exposed to 30 days in the ACQ
extract corrosion test.
Results
Fastener surfaces displayed a wide spectrum of results from no
corrosion, small amounts of corrosion and massive corrosion. Even
certain coated stainless steel alloys had a variety amount of corrosion.
In general, stainless steel of the 300 and 400 series performed well.
The 410 series stainless steel with specific proprietary coatings also
did well. In some cases particular coatings seemed to allow more
corrosion than others. Some types of uncoated stainless steel did
extremely well, however, one must consider the other detriments such as
salt spray and Kesternich acid resistance test, which means coating
stainless steel may not be needed for ACQ but is needed for protection
against the other elements. Some types of carbon steel with proprietary
coatings had very low amounts of corrosion. Hot-dipped galvanized was
covered with corrosion and so were the bi-metal samples.
Conclusions
Fastener manufactures such as ITW Buildex are offering solutions. 410
stainless steel ACQ-resistant proprietary coating and durable
proprietary coated carbon steel proved to be the most
corrosion-resistant according to the ACQ extract test. Although in many
cases the corrosion observed in this testing was only surface corrosion,
many contractors are uncomfortable using fasteners that accumulate large
areas of surface corrosion. Corrosion testing needs to be standardized
for ACQ corrosion potential. The ACQ extract testing is an accelerated
corrosion test performed in extreme conditions.
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