bec,in. Cathodic protection allows an element such as
(see Figure 3) zinc to act as the anodic area on the steel. As the anode, zinc preferentially corrodes, keeping the cathode (base steel) intact. This sacrificial action is also known as "galvanic protection;" only galvanizing delivers an economical combined cathodic and barrier coating protection to steel. Galvanized coatings' excellent field performance
results from zinc's intrinsic corrosion resistance and
its ability to form a dense, protective layer on the surface. While fresh zinc Surfaces are quite reactive,
a thin layer of protective reaction products forms upon exposure to the atmosphere. This stable, protective layer is essential to reducing zinc's corrosion rate, a rate that is approximately 10 to 100
times less than that of steel, depending upon the
environment . It is important to note that hot-dip galvanized
zinc coatings have a much higher density than
zinc-rich paint coatings.

Specifically, three to six
mils (76-152 microns) of zinc-ricli paint, depending
upon the paint formulation, would need to be applied
to equal the zinc content of just 1.7 miils (43) microns) of hot-dip galvanized coating. The lower zinc content detracts from the cathodic protection of a zinc-ricli paiiit system.

Metallurgical Bond
During the galvanizing process. steel is
immersed in iiiolten zinc. Through diffusion, the zinc
metallurgically bonds to the steel, creating a series of
three zinc-iron alloy layers . The zinc coating's adhesion strength is measured on the order of several thousand pounds per sq. in. (dynes per sq.cm.). In addition, the zinc coating resists abrasion

See Hot Dip Galvanized Steel Data Sheet (Click Here) To print the Hot-Dip Galvanizing Click Here