Steel Composition
While all common steels can be galvanized, the chemical composition of a particular steel can affect the formation, thickness and appearance of its galvanized coating, as well as the ability of that coating to withstand mechanical damage. Additionally, the prior history of the steel (e.g. whether it is hot rolled, cold rolled, blasted, welded or thermally cut) can also effect the galvanized coating. This is important, as the corrosion resistance of galvanized steel is directly related to the thickness of its coating.
The elements silicon (Si) and phosphorus (P) have a critical impact on galvanizing. These elements can prolong the reaction between iron and zinc, which consumes the pure outer zinc layer of a coating, and results in the zinc-iron alloy layer being exposed. Pure zinc coating provides steel with a shiny metallic finish, whilst zinc-iron alloys result in duller grey colours. This phenomenon is described by the curve on the right.
Whenever the appearance, smoothness or coating thickness of steel is important, specialist advice should be sought out prior to the fabrication or galvanizing of that article of steel. The table below (which was developed from AZ/NZS 2312.2) provides further information on how the chemical composition of steel can affect coating. Steel which belongs to categories A and B of this table usually offer the best aesthetic results and corrosion protection. Australian and New Zealand steel generally comply with minimum coating thickness requirements of AS/NZS 4680.
