practice for repair of damaged and uncoated area of hot dip galvanize coating a 780
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8/6/2019 Practice for Repair of Damaged and Uncoated Area of Hot Dip Galvanize Coating a 780
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Practice for Repair of Damaged and Uncoated Area of Hot Dip Galvanize
Coating (According to A 780)
If the galvanized product does not meet all of the requirements of the specification, it must be
repaired or rejected along with the lot it represents. When repair of the product is allowed bythe specification or bare spots are present, the galvanizer is responsible for the repair unless
directed otherwise by the purchaser. The specifications allow for some retesting of products
that represent lots or retesting after the lot has been sorted for non-conformance. The coating
thickness of the repaired area must match the coating thickness of the surrounding area. The
maximum sizes for allowable areas that can be repaired during in-plant production are
defined in ASTM A 123/A 123 M. The method for repair of damaged and uncoated area of
hot dip galvanizes coating according to A 780 as below:
1.0 Zinc-Based Solder
Any repairs made to galvanized products must follow the requirements of ASTM A 780,
which defines the acceptable materials and the required procedures. Repairs are normally
completed by the galvanizer before the products are delivered, but under certain
circumstances, the purchaser may perform the repairs on their own. The touch-up and repair
materials are formulated to deliver an excellent color that matches either brightly coated,
newly galvanized products or matte gray, aged galvanized products. Materials used to repair
hot-dip galvanized products include zinc-based solder, zinc-rich paint, and zinc spray
metalizing, and are explained in the following sections.
Soldering with zinc-based alloys is achieved by applying zinc alloy in either a stick orpowder form. The area being repaired needs to be preheated to approximately 600 F (315 C).
The most commonly used solders for repair; include zinc-tin-lead, zinc-cadmium, and zinc-
tin-copper alloys.
1.1 Surface Preparation
According to ASTM A 780, the surface to be reconditioned shall be wire brushed, lightly
ground, or mildly blast cleaned. In addition, if wire brushing or light blasting is inadequate,
all weld flux and spatter must be removed by mechanical methods. The cleaned area also
needs be preheated to 600 F (315 C) and wire brushed while heated. Pre-flux may also be
necessary to provide chemical cleaning of the bare spot. Finally, special care should be given
to insure that the surrounding galvanized coating is not overheated and burned by thepreheating.
1.2 Application
The soldering method is the most difficult of the three repair methods to complete. A high
level of caution must be taken while heating the bare spot to prevent oxidizing the exposed
steel or damaging the surrounding galvanized coating. Solders are typically not economically
suited for touch-up of large areas because of the time involved in the process and because
heating of a large surface area to the same temperature is very difficult. When the repair has
been completed, the flux residue needs to be removed by rinsing the surface with water or
wiping with a damp cloth.
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1.3 Final Repaired Product
The final coating thickness for this repair shall be agreed upon between the galvanizer and
the purchaser, and is generally in the 1 to 2 mil range. The thickness shall be measured by
any of the methods in ASTM A 123/A 123M that are non-destructive. Zinc-based solder
products closely match the surrounding zinc and blend in well with the existing coating
appearance.
2.0Zinc Rich Paint
Zinc-rich paint is applied to a clean, dry steel surface by either a brush or spray and usually
contains an organic binder pre-mix. Zinc-rich paints must contain either between 65% to 69%
metallic zinc by weight or greater than 92% metallic zinc by weight in dry film. Paints
containing zinc dust are classified as organic or inorganic, depending on the binder they
contain. Inorganic binders are particularly suitable for paints applied in touch-up applications
around and over undamaged hot-dip galvanized areas.
2.1 Surface Preparation
According to ASTM A 780, the surface to be repaired shall be blast cleaned to SSPC-
SP10/NACE No.2 near white metal for immersion applications and SSPC-SP11 near bare
metal for less aggressive field conditions. When blasting or power tool cleaning is not
practical, hand tools may be used to clean areas to be reconditioned. The blast cleaning must
extend into the surrounding, undamaged, galvanized coating.
2.2 Application
This method of repairing galvanized surfaces must take place as soon as possible after
preparation is completed and prior to the development of any visible oxides. The spraying or brushing should be in an application of multiple passes and must follow the paint
manufacturers specific written instructions. In addition, proper curing of the repaired area
must occur before the product is put through the final inspection process. This repair can be
done either in the galvanizing plant or on the job site and is the easiest repair method to apply
because limited equipment is required. Zinc-rich painting should be avoided if high humidity
and/or low temperature conditions exist because adhesion may be adversely affected.
2.3 Final Repaired Product
The coating thickness for the paint must be 50% higher than the surrounding coating
thickness, but not greater than 4.0 mils, and measurements should be taken with either a
magnetic, electromagnetic or eddy current gauge. Finally, the surface of the painted coating
on the repaired area should be free of lumps, coarse areas, and loose particles.
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3.0 Zinc Spray Metalizing
Zinc spray, which is also referred to as metalizing, is done by melting zinc powder or zinc
wire in a flame or electric arc and projecting the liquid zinc droplets by air or gas onto the
surface to be coated. The zinc used is nominally 99.5% pure or better and the corrosion
resistance of the wire or powder is approximately equal.
3.1 Surface Preparation
According to ASTM A 780, the surface to be reconditioned shall be blast cleaned to SSPC-
SP5/NACE No.1 near white metal and must be free of oil, grease, weld flux residue, weld
spatter and corrosion products. The blast cleaning must extend into the surrounding,
undamaged, galvanized coating.
3.2 Application
Zinc spraying of the clean, dry surface must be completed by skilled workers and should take
place within four hours after preparation or prior to development of visible oxides. Sprayingshould also be done in horizontal overlapping lines, which yield a uniform thickness more
consistent than the crosshatch technique. The zinc coating can be sealed with a thin coating of
low viscosity polyurethane, epoxy-phenolic, epoxy, or vinyl resin. The details of the
application sequence and procedures can be found in ANSI/AWS C2.18-93. The application
of zinc spray can be done either in the galvanizers plant or at the job site. In addition, if high
humidity conditions exist during spraying, adhesion may be degraded.
3.3 Final Repaired Product
The renovated area shall have a zinc coating thickness at least as thick as that specified
in ASTM A 123/A 123M for the thickness grade required for the appropriate materialcategory. These thickness measurements should be taken with either a magnetic or an
electromagnetic gauge for best results. The plain zinc sprays or the sprays with aluminum
additives both provide a good match for newly galvanized, bright surfaces. Finally, the
surface of the sprayed zinc coating should be free of any lumps, coarse areas, and loose
particles.
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