The Electrochemical Behavior of As-Prepared Aluminum Alloy A360 Produced by Selective Laser Melting Fabrication with and without a Trivalent Chromium Process Conversion Coating

We report herein on the electrochemical behavior and corrosion resistance of as-prepared aluminum alloy, A360 (AlSi10Mg), fabricated by additive manufacturing, with and without a trivalent chromium process conversion coating. Selective laser melting was the 3D printing process used for the alloy build. The corrosion suppression provided by the coating system was assessed through electrochemical measurements and accelerated degradation testing during a 14-day continuous neutral salt-spray exposure. The results indicate that the conversion coating can be formed by solution pretreating (degreasing and deoxidation) the alloy (X-Z plane perpendicular to the build plane) with its native surface roughness (as-prepared) followed by immersion for 10, 15 or 20 min in the coating bath. All three immersion times provide an equivalent level of corrosion protection to the alloy. The conversion coating suppresses both anodic and cathodic currents, increases the polarization resistance, and provides both anodic and cathodic corrosion protection to the as-prepared alloy. The conversion-coated specimens exhibit good stand-alone corrosion resistance during a 14-day neutral salt-spray exposure with corrosion intensity values (g/m(2)-year) similar to 10x lower than values for the uncoated, as-prepared alloy specimens.

Automated summary

This study reports on the electrochemical behavior and corrosion resistance of as-prepared aluminum alloy A360 (AlSi10Mg) fabricated by additive manufacturing, with and without a trivalent chromium process conversion coating. The corrosion suppression provided by the coating system was evaluated through electrochemical measurements and accelerated degradation testing. The results indicate that the conversion coating can provide equivalent corrosion protection to the alloy and protect the as-prepared alloy by suppressing both anodic and cathodic currents and increasing polarization resistance.