Data-driven R&D, Startup and Corrosion Science and Engineering
Masahiro Takemura
pp. 1-2
DOI:
10.3323/jcorr.73.1Backnumber
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07 Oct. (Last 30 Days)
Masahiro Takemura
pp. 1-2
DOI:
10.3323/jcorr.73.1Takashi Miwa, Azusa Ishii, Akira Sugiyama
pp. 5-11
DOI:
10.3323/jcorr.73.5Abstract
Accelerated corrosion tests need to ensure compatibility between acceleration of corrosion and reproduction of atmospheric corrosion in actual coastal environments. However, gordaite, a highly protective zinc-corrosion product, is not produced in cyclic corrosion tests using general NaCl aqueous solutions. Moreover, the ratio of the corrosion rates of steel/zinc after those tests is too small compared to that after outdoor exposure. Conversely, when artificial seawater is used, the corrosion products contain too much gordaite, and the ratio of corrosion rate of steel/zinc is too large compared with that for outdoor exposure. With these solutions, the corrosion resistance of zinc is underestimated or overestimated. Therefore, we developed a new test solution for reproducing the atmospheric corrosion behavior of zinc in coastal area. The solution enables us to evaluate corrosion resistance of zinc-rich paint and galvanized steel in coastal areas more accurately than other solutions do.
Mizuki Miyauchi, Azusa Ooi, Eiji Tada
pp. 12-20
DOI:
10.3323/jcorr.73.12Abstract
In this study, the corrosion behavior of zinc in a simulated soil environment was investigated at various degrees of saturation, Sr by using surface observation, corrosion depth analysis, electrochemical impedance spectroscopy, and potentiodynamic polarization tests to evaluate the effect of soil moisture on corrosion morphology and corrosion rate and of zinc. At high soil moisture content (Sr>80%), the average corrosion rate of zinc remained low and did not change much with Sr. On the other hand, at low moisture content (Sr<80%), the average corrosion rate increased significantly and showed a peak at around Sr=50%. In addition, the corrosion morphology of zinc became more heterogeneous with decreasing Sr, indicating that the corrosion depth became deeper. The effects of soil moisture on the corrosion morphology and corrosion rate of zinc were discussed based on the changes in cathodic reduction of oxygen and anodic reaction of zinc in a simulated soil environment.
07 Oct. (Last 30 Days)
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