The nature of «black spots» formation on the surface of large parts made of aluminum alloys in the process of anodic oxidising


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Abstract

The causes of black spot defects detected on the surface of large parts made of aluminum alloys (D16chT, 1973T2, V95pchT2, V95pchT3) following anodic oxidation   are investigated in the paper. A hypothesis of such defects appearing during the dissolution of intermetallics on the surface of a part in the process of etching during anodizing was put forward and tested. A technique was developed for this purpose the essence of which was that an intermetallic was detected on a polished sample and using a microhardness tester the area including the intermetallic was marked to facilitate its subsequent detection at the end of the specimen etching. After the etching of the specimen during periods of different duration in an alkaline bath of the anodizing line the area containing an intermetallic previously labeled using the microhardness tester was detected by microscopic observations and photographed. The duration of the etching process was 120 seconds and consisted of 8 cycles. Metallographic tests of the specimens. revealed the fact that in the process of etching of an aluminum alloy dissolution (etching) of intermetallic particles opening out on the surface of the part takes place. Subsequent anodic oxidation leads to the visualization of defects which have the form of black spots.

About the authors

V. V. Semenychev

Ulyanovsk Science and Technology Center of the All-Russian Institute of Aviation Materials

Author for correspondence.
Email: untcviam@viam.ru

Candidate of Science (Engineering)

Chief Researcher

Russian Federation

R. K. Salakhova

Ulyanovsk Science and Technology Center of the All-Russian Institute of Aviation Materials

Email: salahovark@viam.ru

Candidate of Science (Engineering)

Chief of laboratory

Russian Federation

References

  1. Kablov E.N. Strategic directions of development of materials and technologies to process them for the period up to 2030 // Aircraft Materials and Technologies. 2012. No S. P. 7-17. (In Russ.)
  2. Antipov V.V., Senatorova O.G., Tkachenko E.A., Vahromov R.O. Aluminum wrought alloys // Aircraft Materials and Technologies. 2012. No. S. P. 167-182. (In Russ.)
  3. Antipov V.V. The development strategy of titanium, magnesium, beryllium and aluminum alloys // Aircraft Materials and Technologies. 2012. No. S. P. 157-167. (In Russ.)
  4. Istoriya aviatsionnogo materialovedeniya. VIAM-75 let poiska, tvorchestva, otkrytiy [History of aviation materials science. VIAM-75 years of research, creative work, discoveries]. Edited by Academician E.N. Kablov. Moscow: Nauka Publ., 2007. 343 p.
  5. Sinjavskij V.S., Komissarova V.S., Val'kov V.D., Batrakov V.P. Promyshlennye alyuminievye splavy. Spravochnik. [Industrial aluminum alloys. Reference guide]. Moscow: Metallurgy Publ., 1984. P. 507-508.
  6. Ivonin V.N., Chin' Kuok Khan', Din' Van Dam, Olejnik S.V., Kuznenkov Ju.A., Kuznecov Ju.I., Karpov V.A. On the effectiveness of anticorrosion protection of aluminum alloys conversion coatings in a humid tropical climate // Corrosion: Materials, protection. 2012. No. 10. P. 44-48. (In Russ.)
  7. Semenychev V.V. Corrosion resistance of high-strength aluminum alloys in marine subtropical climate // Technology of light alloys. 2007. No. 4. P. 138-142. (In Russ.)
  8. Kononov S.A., Gorohov V.P., Perevozov A.S., Ivanishheva M.G., Lancova L.P., Tkachenko E.A. Development and implementation of production technology skin sheets of duralumin of regulated grain size // Abstracts of the International Scientific and Technical Conference «Topical issues of avi-ation materials». Moscow: VIAM. 2007. P. 37. (In Russ.)
  9. Zhirnov A.D., Karimova S.A. Corrosion and Protection of metallic materials / The collection of 75 years. Aircraft materials. Selected Works «VIAM». Anniversary scientific and technical collection. Moscow: VIAM. 2007. P. 202-208. (In Russ.)
  10. Zhilikov V.P., Karimova S.A., Leshko S.S., Chesnokov D.V. Study of the dynamics of corrosion of aluminum alloys when tested in a salt spray (KST) // Aircraft Materials and Technologies. 2012. No. 4. P.18-22. (In Russ.)
  11. Elinek T.V., Shtajnhajm an der Murr. Success of electroplating. Review of the world literature in 2010-2011 // Electroplating and Surface Treatment. 2012. No. 4. P.13-28. (In Russ.)
  12. Hohlov V.V., Zharinov P.M., Rakoch A.G. Corrosion resistance of the alloy D16 with oxide ceramic coatings produced by micro-arc oxidation in silicate electrolyte // Corrosion: Materials, protection. 2007. No. 4. P. 23-27. (In Russ.)
  13. Shatrov A.S. Protective oxideceramic coatings formed on aluminum alloys using the method of plasma electrolytic oxidation // Corrosion: Materials, protection. 2012. No. 4. P.28-37. (In Russ.)

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