Reprinted for Quaker Houghton with permission, ©2020 Light Metal Age
Anodizing Conditions and Their Myriad Effects on Finish Quality By Dr. George N. Oh, Nathan Sheffield, and Yechan Kang, Quaker Houghton, Metal Finishing Group Abstract
Experiment
uality of anodized aluminum, both mechanical and aesthetic, is affected by a number of parameters. Two parameters that have larger effects on finish and quality are anodize temperature and current density. This study shows that these parameters affect coating weight density, mechanical robustness (Michael-Clarke abrasion), electrolytic color tone, and even corrosion resistance. Using a well-established understanding of microstructural development of the anodic aluminum oxide film, this paper explains how and why these variations affect the resulting quality of the part. Control of just these two parameters goes a long way towards ensuring consistent results to meet specifications and customer requirements.
Aluminum 6063-T6 panels were taken through a standard anodization process. The parts were cleaned, acid etched, caustic etched, deoxidized, anodized, and midtemperature-sealed. Some parts were also electrolytically colored to a dark bronze. The finished panels were airdried for at least 16 hours before analysis. Control panels were anodized at 18 ASF (A/ft2) and at 70°F for 28 minutes, targeting 0.7 mil thick coating. Additional panels were run at higher temperatures and at higher or lower current densities, adjusting the time according to the 720 Rule to target the same thickness. Colors were measured in the L*a*b* color space using a Konica Minolta CM–700d Spectrophotometer in SCE mode.3 Color swatches were generated from the nix color sensor tool.4 ΔE values were measured using the Cie76 algorithm.5 The parts were subject to quality tests as per AAMA 611-14,6 with coating thicknesses measured using a Fischer MP0R Isoscope. The panels were also subject to acid dissolution tests (ADT) and Michael-Clarke abrasion tests. Coating weights and densities were also obtained. References contain the detailed experimental parameters and statistical treatment of data.7-9
Q
Introduction Anodization of aluminum provides mechanical and chemical protection to aluminum metal and alloys by building a porous aluminum oxide layer, which is then sealed by chemical and/or physical methods.1-2 This layer is integral to the metal substrate and provides superior mechanical and chemical protection compared to paint, powder coating, or other coatings. Anodizing is fairly environmentally friendly, as it does not rely on hexavalent chromium, and it does not rely heavily on organic materials that must be waste-treated, as is typical for paint. One disadvantage of anodization compared to paint is that control of the final color of the finish is much more difficult. The depth of color is dependent on the amount of colorant taken up by the pores: adsorbed chromophore in the case of dyes, electrodeposited tin in the case of electrolytic color. Furthermore, interference phenomena can modulate the limited color tones of electrolytic color. As a result, moderate variations in the pore structure lead to small changes in color, which can nevertheless be detected by people with average to good color discrimination. Like other finishing techniques, anodization requires understanding of a variety of factors that can cause problems with the final finish. Some, such as the role of effective cleaning, are common to all finishing techniques. Conversely, understanding of the underlying aluminum substrate is much more important for anodization than for other finishing techniques. And like all finishing techniques, some are particular to the technique. In this case, these include applied current in the anodize tank and temperature of the seal tank. Anodization particularly requires some breadth of knowledge, as it has more steps and process tanks than any other finishing process. Expert anodizers can control all of the operational parameters that affect anodize quality and appearance while being able to troubleshoot various problems. Maintaining control of basic anodizing factors goes a long way towards ensuring smooth operation and meeting standard specifications. In this article, two parameters for the anodize tank will be focused on, namely current density and tank temperature. Their effects on a number of architectural specification requirements will be examined, connecting these effects to what is known about the microstructural development of the anodic aluminum oxide layer. 46
Results The results of the experiment determined the effects of temperature and current density on the specifications and color of the aluminum parts. Effect on Specifications: It is generally recommended that a tank temperature of 70°F and a current density of 18 ASF be implemented during anodization. Some specification tests are fairly insensitive to variations in these parameters. Figure 1a shows the results of the ADT at 70, 80, and 85°F, and at 8, 13, 16, 18, and 24 ASF. The parts failed this test only at 8 ASF, and even then only at elevated temperatures. The ADT is designed to test the corrosion resistance of parts, which is primarily dependent on how well the pores generated during anodization are plugged, i.e. the efficacy of the sealing step. Conversely, the ADT depends relatively little on anodizing parameters, and only fails with gross deviations. The experiment showed that the optimum parameters for current density in this study are 70°F and 18 ASF.
Figure 1. Current density and temperature versus ADT (a) and coating weight density (b).
LIGHT METAL AGE, AUGUST 2020