Development and Performing of a Method of Comparative Flammability Tests of Magnesium Alloys

Sergey Barbot’ko; Oleg Volniy; Nikolai Trofimov; Aleksandr Leonov; Andrei Sivenkov; Marina Gravit

doi:10.1051/e3sconf/202132002003

All issues

Volume 320 (2021)

E3S Web Conf., 320 (2021) 02003

References

Open Access

Issue		E3S Web Conf. Volume 320, 2021 Energy Systems Environmental Impacts (ESEI 2021)


Article Number		02003
Number of page(s)		7
Section		Energy Use in Industrial Sector
DOI		https://doi.org/10.1051/e3sconf/202132002003
Published online		09 November 2021

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A.Ya. Korolchenko, Korolchenko D.A., Fire and explosion hazard of substances and materials and means of their extinguishing, Pt.1 – 713 p., Pt.2 – 774 p. [Google Scholar]
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E.F. Volkova, Barbot’ko S.L., Obrezkov O.I., Vershok B.A., A new solution to the problem of protection of magnesium alloys from ignition, Technology of light alloys, 2010. №1. P.151-156 [Google Scholar]
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[1] V.V. Antipov, Development strategy of titanium, magnesium, beryllium and aluminum alloys, Aviation materials and technologies, 2012. №S. P. 157-167 [Google Scholar]

[2] I.S. Kornysheva, Volkova E.F., Goncharenko E.S., Mukhina I.Yu., Prospects for the use of magnesium and casting aluminum alloys, Aviation materials and technologies, 2012. №S. P. 212-222 [Google Scholar]

[3] V.V. Antipov, Prospects for the development of aluminum, magnesium and titanium alloys for products of aerospace technology, Aviation materials and technologies, 2017. S. P. 186–194. DOI 10.18577/2071-9140-2017-0-S-186-194 [Google Scholar]

[4] V.A. Duyunova, Volkova E.F., Uridiya ZP, Trapeznikov A.V., Dynamics of development of magnesium and casting aluminum alloys, Aviation materials and technologies, 2017. №S. С. 225–241. DOI 10.18577/2071-9140-2017-0-S-225-241 [Google Scholar]

[5] A.Ya. Korolchenko, Korolchenko D.A., Fire and explosion hazard of substances and materials and means of their extinguishing, Pt.1 – 713 p., Pt.2 – 774 p. [Google Scholar]

[6] V.I. Perelman, A reference book of a chemist, Moscow, 1951, 675 p. [Google Scholar]

[7] E.F. Volkova, Barbot’ko S.L., Obrezkov O.I., Vershok B.A., A new solution to the problem of protection of magnesium alloys from ignition, Technology of light alloys, 2010. №1. P.151-156 [Google Scholar]

[8] S.V. Gnedenkov, Sidorova M.V., Sinebryukhov S.L., Antipov V.V., Buznik V.M., Volkova E.F., Sergienko V.I., Structure and properties of coatings obtained by plasma electrolytic oxidation on aviation magnesium alloys, Aviation materials and technologies, 2013. №S-2. P. 36–45 [Google Scholar]

[9] E.N. Kablov, Volkova E.F., Filonova E.V., Influence of REE on the phase composition and properties of a new high-temperature magnesium alloy of the Mg-Zn-Zr-REE system, Metallurgy and heat treatment of metals, 2017. №7(745). P. 19-26. [Google Scholar]

[10] R. Tandon, Advances in Additive Manufacturing Using Magnesium Alloy Powders, The Eight Triennial International Aircraft Fire and Cabin Safety Research Conference, October 24-27, Atlantic City NJ https://www.fire.tc.faa.gov/2016Conference/files/Materials_VI_Magnesium/TandonAdditiveMagAlloy/TandonAdditiveMagAlloyPres.pptx [Google Scholar]

[11] B. Gwynne, Lyon P., Magnesium Alloys in Aerospace Applications, Past Concerns, Current Solutions, Triennial International Aircraft Fire & Cabin Safety Research Conference, October 29 November 1, 2007 https://www.fire.tc.faa.gov/2007Conference/files/Materials_Fire_Safety/WedAM/GwynneMagnesium/GwynneMagnesiumPres.pdf [Google Scholar]

[12] Y. Kawamura, Flame-resistant Magnesium Alloys with High Strength, The Seventh Triennial International Fire & Cabin Safety Research Conference / Philadelphia Marriott Downtown, December 2-5, 2013. https://www.fire.tc.faa.gov/2013Conference/files/Magnesium_Use_In_Aircraft_I/KawamuraFireResistantMag/KawamuraFireResistantMagPres.pdf [Google Scholar]

[13] D. Henry, Kemp M., Development of a Lightweight Forged Magnesium Aircraft Seat Component, Eighth Triennial International Aircraft Fire and Cabin Safety Research Conference / 27th October 2016 https://www.fire.tc.faa.gov/2016Conference/files/Crash_Dynamics_IV/HenryForgedMagnesium/HenryForgedMagnesiumPres.pdf [Google Scholar]

[14] P. Boris, A study of the flammability of magnesium, Technical Report ADS-14 / Federal Aviation Agency, 1964, 43 p. https://www.fire.tc.faa.gov/pdf/ads-14.pdf [Google Scholar]

[15] T.R. Marker, Evaluating the Flammability of Various Magnesium Alloys During Laboratoryand Full-Scale Aircraft Fire Tests, Technical Report DOT/FAA/AR-11/3 / Federal Aviation Administration, US Department of Transportation, 2013. 146 p. https://www.fire.tc.faa.gov/pdf/AR11-13.pdf [Google Scholar]

[16] T.R. Marker, Development of a Laboratory-Scale Flammability Test for Magnesium Alloys Used in Aircraft Seat Construction, Technical Report DOT/FAA/TC-13/52 / Federal Aviation Administration, US Department of Transportation. 2014. 228 p. https://www.fire.tc.faa.gov/pdf/TC-13-52.pdf [Google Scholar]

[17] T. Marker, Development of New Flammability Test for Magnesium-Alloy Cabin Components, International Aircraft Materials Fire Test Forum / Virtual Meeting, June 8, 2020 https://www.fire.tc.faa.gov/pdf/materials/June20Meeting/Marker-0620-magtask.pdf [Google Scholar]

[18] Aircraft Materials Fire Test Handbook https://www.fire.tc.faa.gov/Handbook [Google Scholar]

[19] S.L. Barbot’ko, Volniy O.S., Kirienko O.A., Shurkova E.N., Assessment of fire safety of polymer materials for aviation purposes: analysis of the state, test methods, development prospects, methodological features, VIAM, 2018. 424 p. [Google Scholar]

[20] E. Canary, Revised EASA SC on Use of Magnesium Alloys for Passenger Seat Components, International Aircraft Materials Fire Testing Working Group Meeting Cologne, 7-8 June 2017 https://www.fire.tc.faa.gov/pdf/materials/June17Meeting/EASA-0616-UseofMagnesium.pdf [Google Scholar]

[21] H.-P. Busch, Magnesium small scale test, FAA Seventh Triennial International Fire & Cabin Safety Research Conference, 2-5 December, 2013 https://www.fire.tc.faa.gov/2013Conference/files/Magnesium_Use_in_Aircraft_II/BuschMagBurning/BuschMagBurningPres.pptx [Google Scholar]

[22] E.N. Kablov, Innovative developments of FSUE “VIAM” SSC RF for the implementation of “Strategic directions for the development of materials and technologies for their processing for the period up to 2030”, Aviation materials and technologies. 2015. №1 (34). P. 3–33. DOI: 10.18577/2071-9140-2015-0-1-3-33. [Google Scholar]

[23] E.N. Kablov, New generation materials and technologies for their digital processing, Herald of the Russian Academy of Sciences. 2020. Vol. 90. No. 2. P. 225-228. [Google Scholar]