ArticleName |
Optimization of low-temperature crystalline phosphatization of steel surfaces |
ArticleAuthorData |
D. Mendeleev University of Chemical Technology of Russia (Moscow, Russia):
D. V. Mazurova, Cand. Eng., Associate Prof., Dept. of Innovative Materials and Corrosion Protection, E-mail: diana-mazurova@yandex.ru N. S. Grigoryan, Cand. Chem., Associate Prof., Dept. of Innovative Materials and Corrosion Protection, E-mail: ngrig108@mail.ru Yu. I. Kapustin, Dr. Eng., Prof., Dept. of Innovative Materials and Corrosion Protection, E-mail: kap@muctr.ru T. A. Vagramyan, Dr. Eng., Prof., Head of the Dept. of Innovative Materials and Corrosion Protection, E-mail: vagramyan@muctr.ru |
Abstract |
Unique properties of phosphate coatings, a relatively low cost and a simple production process explain why phosphatization became widespread in many industries. Phosphatization involves multiple stages and a lot of energy, the temperature of conventional industrial phosphatization solutions can reach 85 °С. One of the processes involves surface activation of steel in phosphatization activator suspension. This paper looks at the process of steel surface activation combined with phosphate coating. A conventional phosphatization process involves activation, i.e. a pre-treatment of the target surface in the suspension containing fine dispersed poorly soluble compounds. Due to surface adsorption, such compounds hinder the growth of phosphate grains thus increasing the coating consolidation. The authors also looked at the effect of fine dispersed SiO2 and TiO2 oxides introduced directly in the low-temperature phosphatization agent. The authors developed a low-temperature steel surface phosphatization process that combines phosphatization with activation which take place in the suspension containing ZnO — 10 g/l, Н3PO4 — 19 g/l, НNO3 — 8 g/l, FeCl3·6H2О — 0.3 g/l, Ce(SO4)2·4H2O — 0.2 g/l, NH2OH — 2.0 g/l, SiO2 or TiO2 — 1 g/l at pH = 2±0.5. The paper shows that a 10-minute deposition at 30 °С produces phosphate coatings the corrosion resistance and protective properties of which would be comparable to those of the phosphate coatings produced with the help of pre-activation. Introduction of fine SiO2 or TiO2 particles would make it a simpler process because in this case no pre-activation bath is used. And the low-temperature regime helps reduce the energy cost.
This research was funded by the Mendeleev University of Chemical Technology of Russia. Project No. 015-2018. |
References |
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