Print

2018 №08 (06) DOI of Article
10.15407/tpwj2018.08.07
2018 №08 (08)


The Paton Welding Journal, 2018, #8, 39-43 pages
 

Materials for individual armour protection (Review)

A.A. Babinets1, I.A. Ryabtsev1 and A.I. Panfilov2


1E.O. Paton Electric Welding Institute of the NAS of Ukraine 11 Kazimir Malevich Str., 03150, Kyiv, Ukraine. E-mail: office@paton.kiev.ua
2LLC «Steel Wrok», Kryvyi Rih, Ukraine. E-mail: a.panfilov@steel-work.net
In the paper the available literature data on the properties of different materials, currently used in the means of individual armour protection, were analyzed and the methods for improving their bulletproof and other operational properties were evaluated. It is shown that at the present time to create the means of individual armour protection, a variety of materials are used: fabric aramid or polyethylene fibers, metal plates based on steels, titanium, aluminum and their alloys, as well as ceramics based on boron and silicon carbides, etc. The main advantages and disadvantages of these armoured materials are shown. On the basis of literary data, it was established that for the 3rd–5th class of protection, the armoured plates of structural alloyed steels were widely used. To minimize the disadvantages inherent in steel armoured plates, it is necessary to apply bimetallic compositions with alternating hard and soft layers, produced, among others, by welding or surfacing methods. 20 Ref., 4 Tables, 3 Figures.
Keywords: individual armour protection, classes of protection, armoured plates, properties of armoured materials, bulletproof, armour steels, composites, multilayer materials
 
Received:                19.06.18
Published:               01.10.18
 
 
References
1. Kobylkin, I.F., Selivanov, I.F. (2014) Materials and structure of light armour protection. Moscow, N.E. Bauman NSTU [in Russian].
2. Gladyshev, S.A., Grigoryan, V.A. (2010) Armoured steels. Moscow, Interment Engineering [in Russian].
3. Grigoryan, V.A., Kobylkin, I.F., Marinin, V.M., Chistyakov, E.N. (2008) Materials and protective structures for local and individual armouring. Moscow, RadioSoft [in Russian].
4. Anastasiadi, G.P., Silnikov, M.V. (2004) Operating capability of armour materials. St.-Petersburg, Asterion [in Russian].
5. Bajdak, V.I., Blinov, O.F., Znakhurko, V.A. et al. (2003) Concept basics for development of means of individual armour protection. Moscow, Armouring. Politics. Conversion [in Russian].
6. Manzhura, S.A. (2017) Selection of armoured plate materials for individual means of armour protection of law enforcement forces. Systemy Ozbroennya i Vijskova Tekhnika, 2, 89–93 [in Ukrainian].
7. Bolotov, M.G., Ganeev, T.R., Novomlynets, O.O., Prybytko, I.O. (2015) New trends of application of titanium aluminides. Tekhnichni Nauky ta Tekhnologii, 2, 51–55 [in Ukrainian].
8. Novikov, V.A. (2015) Flak jacket: Modern materials and their properties. In: Proc. of Int. Sci.-Techn. Conf. of Young Scientists of V.G. Shukhov BSTU (1–30 May, Belgorod), 1443–1446.
9. Gorbunov, I.M., Kharchenko, E.F., Aniskovich, V.A. (2006) Analysis on scientific and technical level of development of modern armour protection means in Russia and abroad. Oboronny Compleks — Nauchno-Tekhnicheskomu Progressu Rossii, 4, 32–35 [in Russian].
10. (2002) DSTU 4103–2002: Means of individual protection, bulletproof vests. General specifications [in Ukrainian].
11. Zagoryansky, V.G. (2015) Substantiation for application of steel-aluminium bimetal on calculation criteria of bulletproof armour. Visnyk NTUU KPI. Seriya: Mashynobuduvannya, 3, 37–41 [in Ukrainian].
12. Guskov, A.V., Milevsky, K.A., Pavlova, O.V. (2014) bulletproof vests with ceramic armour elements of honeycomb structure. Evrazijsky Soyuz Uchyonykh, 8–8, 45–46 [in Russian].
13. Mylnikov, V.V., Abrosimov, A.A., Romanov, I.D., Romanov, A.D. (2014) Analysis of materials and their properties, applied for means of individual armour protection. Uspekhy Sovremennogo Estestvoznaniya, 9–2, 143–147 [in Russian].
14. Chernyshov, E.A., Mylnikov, V.V., Mylnikova, M.V., Romanov, A.D. et al. (2014) Development of metal-ceramic elements of ballistic protection using aluminium-based ceramics. Sovremennye Naukoyomkie Tekhnologii, 4, 97–100 [in Russian].
15. Aleksentseva, S.E., Zakharov, I.V. (2011) Effect of shockproof properties of alloys on bulletproofness. Vestnik Samar. STU. Seriya: Tekhnicheskie Nauki, 4, 88–95 [in Russian].
16. Radonjic, V.M., Jovanovic, D.M., Zivanovic, G.Z., Resimic, B.V. (2014) Ballistic characteristics improving and maintenance of protective ballistic vests. Vojnotehnicki glasnik, 62 (Is. 4), 89-103. DOI: 10.5937/vojtehg62-4992. https://doi.org/10.5937/vojtehg62-4992
17. Kryukov, D.B., Kozlov, D.B. (2016) Perspectives of application of metal composite materials for development of armouring of new generation. Vestnik Penzenskogo Gos. Unta, 2, 103–108 [in Russian].
18. Dragobetsky, V.V., Shapoval, A.A., Zagoryansky, V.G. (2015) Development of elements of individual protection means of new generation based on laminated metallic compositions. Vuzov, Chyorn. Metallurgiya, 58, 1, 44–48 [in Russian].
19. Morka, A., Jackowska, B. (2010) Ballistic resistance of the carbon nanotube fibres reinforced composites — numerical study. Mater. Sci., 50(4), 1244–1249. DOI:10.1016/j. commatsci.2010.03.046.
20. Kurkov, S.N., Kukanov, S.A., Zajtsev, Yu.M. (2016) Application of nanostructured materials in protective compositions of individual armour means. Tulskogo Gos. Un-ta. Tekhnicheskie Nauki, 3, 53–59 [in Russian].