Evaluating the Electrochemical Properties in the Protection Potential of Material for Use in Al Vessels in Seawater

Seong Jong Kim

doi:10.4028/www.scientific.net/MSF.510-511.158

Paper Titles

Simulation of Electric Upsetting and Forging Process for Large Marine Diesel Engine Exhaust Valves
p.142

Appearance of Indium Oxide Nanorods in MOCVD Growth
p.146

Compressive Deformation Behaviour of a Closed-Cell Aluminum
p.150

A Simple Reliable Method of Selecting Epoxy Molding Compounds for High Power Short Wavelength Light Emitting Diode Packages
p.154

Evaluating the Electrochemical Properties in the Protection Potential of Material for Use in Al Vessels in Seawater
p.158

A Slow Strain Rate Test Experiment to Evaluate the Characteristics of High-Strength Al-Mg Alloy for Application in Ships
p.162

Effects of Current Density on the Formation of Anodic Oxide Films on AZ91
p.166

CdSe/ZnS Quantum Dots Loaded Solid Lipid Nanoparticles: Novel Luminescent Nanocomposite Particles
p.170

Corrosion Behavior of Chromium Cast Iron and Steel in Hot Concentrated Alkaline
p.174

HomeMaterials Science ForumMaterials Science Forum Vols. 510-511Evaluating the Electrochemical Properties in the...

Evaluating the Electrochemical Properties in the Protection Potential of Material for Use in Al Vessels in Seawater

Abstract:

FRP (fiber-reinforced polymer) ships used with small boats for fishing pose numerous problems related to both the environment and recycling. From this perspective, aluminum offers an environmentally friendly substitute for FRP that is easy to recycle and imparts a high added value to fishing boats, with a reduction in fuel demands. The current density of 7075 Al alloy increases linearly with an increase in potential during anodic polarization, which implies that no passivation of this alloy occurs. With 1050 and 5456 alloys, passive films form during anodic polarization but are destroyed by the Cl in seawater, only to regrow as a result of the self-healing capacity of aluminum. A shift to more anodic or cathodic conditions in the potential range of –1.5 ~ –0.68 V resulted in a sudden increase in current density. Current densities in the high-strength 7075 Al alloy showed the greatest values. In contrast, the current densities of 5456 alloy, known to have excellent corrosion resistance in seawater, were the lowest in the range of –0.70 ~ –1.3 V, and we conclude that this potential range offers optimal protection.