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On the Issue of Laser Selective Removal of Paint Coating from a Sample of Metal Plating of Aircraft Gliders

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Abstract:

In this paper the temperature fields in the zone of processing of paint coatings by laser radiation of a sample of the metal skin of aircraft gliders with selective (layer-by-layer) removal are researched. The performed theoretical studies and numerical calculations made it possible to carry out practical tests and develop conditions under which the physical effect of laser energy causes minimal damage to the alloys and composites of the sample, as well as to assess the effect of the laser on the properties of materials used in the aerospace industry. The obtained results are reflected in the technology of laser selective removal of paint coatings from metal and composite skin of aircraft gliders.

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Periodical:

Key Engineering Materials (Volume 887)

Pages:

364-369

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.887.364

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Online since:

May 2021

Authors:

Marina V. Polonik*, Alexandr A. Mantsybora

Keywords:

Composite Materials, Laser Technologies, Metal, Paint Coatings, Surface Cleaning

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References

[1] E.K. Kondrashov, V.A. Kuznetsova, L.V. Semenova, T.A. Lebedeva, Development of aviation paint coatings, All materials, Encyclopedic reference. 5 (2012).

Google Scholar

[2] E.F. Itsko, A.C. Drinberg, Removal of paint coatings, M.: LKM-press, (2010).

Google Scholar

[3] E.F. Itsko, A.C. Drinberg, Washes for removing paint coatings, Industrial painting. 4 (2003) 2.

Google Scholar

[4] L.V. Semenova, T.A. Novikova, N.I. Nefedov, Study of the washing ability of washes for the removal of paint coatings systems, Aviation materials and technologies. 1 (46) (2017).

Google Scholar

[5] Laser cleaning of surfaces, RITM mechanical engineering journal. 7 (2019) 17-19.

Google Scholar

[6] J. Ion, Laser Processing of Engineering Materials: Principles, Procedure and Industrial Application. Elsevier Butterworth-Heinemann, Oxford, (2005).

Google Scholar

[7] B. Morey, Laser welding applications expand, Manufacturing Engineering. 152 (2014) 81-93.

Google Scholar

[8] Y. Kawahito, M. Mizutani, S. Katayama, High quality welding of stainless steel with 10 kW high power fibre laser, Science and Technology of Welding and Joining. 14 (2009) 288-294.

DOI: 10.1179/136217108x372531

Google Scholar

[9] V.P. Veyko, E.A. Shakhno, Collection of Problems in Laser Technologies, Publishing House of St.Petersburg University of Information Technologies, Mechanics and Optics, St.Peterburg, (2007).

Google Scholar

[10] N.N. Rykalin, Calculations of thermal processes during welding. M.: Mechanical engineering, (1951).

Google Scholar

[11] V.P. Veiko, V.N. Smirnov, A.M. Chirkov, E.A. Shakhno, Laser cleaning in mechanical engineering and instrument making. SPb: NRU ITMO, (2013).

Google Scholar

[12] S.I. Anisimov, B.S. Luk'yanchuk, Selected problems of laser ablation theory, Physics-Uspekhi. 45 (2002) 293-324.

DOI: 10.1070/pu2002v045n03abeh000966

Google Scholar

[13] M.V. Polonik, O.V. Dudko, Selection of the Optimal Parameters of the Process for Thermal Laser Treatment of Metals for Creating the Molten Pool with a Required Depth. 1623 (2016) 768-778.

Google Scholar

[14] D.S. Yatsko, M.V. Polonik, O.V. Dudko, Optimization of the fiber laser parameters for local high-temperature impact on metal, Asia-Pacific Conference on Fundamental Problems of Opto- and Microelectronics. 1017624 (2016).

DOI: 10.1117/12.2268241

Google Scholar

[15] Y.N. Kulchin, S.B. Zmeu, E.P. Subbotin, A.I. Nikitin, Fiber lasers, Bulletin of the Far East branch of the Russian academy of sciences. 3 (2015) 67-78.

Google Scholar

[16] A.A. Malashchenko, A.V. Mezentsev, Laser welding in metals. M.: Mechanical engineering, (1984).

Google Scholar

[17] N.N. Rykalin, A.A. Uglov, Temperature field of dissimilar materials in butt welding with a surface source, Physics and Chemistry of Material Processing. 5 (1969) 12-22.

Google Scholar

[18] N.N. Rykalin, A.A. Uglov and other, Laser and electron-beam processing of materials: Handbook. M.: Mechanical engineering, (1985).

Google Scholar

[19] ANSYS Theory Reference, Structures. SAS IP, Inc.

Google Scholar

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