Szczegóły

Tytuł artykułu

Pyramidal ceramic armor ability to defeat projectile threat by changing its trajectory

Tytuł czasopisma

Bulletin of the Polish Academy of Sciences Technical Sciences

Rocznik

2015

Wolumin

63

Numer

No 4

Autorzy

Wydział PAN

Nauki Techniczne

Zakres

843-849

Data

2015[2015.01.01 AD - 2015.12.31 AD]

Identyfikator

DOI: 10.1515/bpasts-2015-0096 ; ISSN 2300-1917

Źródło

Bulletin of the Polish Academy of Sciences: Technical Sciences; 2015; 63; No 4; 843-849

Referencje

Kędzierski (2015), Optimization of two - component armour, Bull Tech, 173. ; McIntosh (1998), The Johnson - Holmquist Ceramic Model as Used in LS Defence Research Establishment Quebec, Dyna. ; Chabera (2015), Comparison of numerical and experimental study of armour system based on alumina and silicon carbide ceramics, Bull Tech, 363. ; Hunn (2011), Development of a novel ceramic armor system : analysis and test th Ballistic, Int Symp, 26, 1. ; Holmquist (2005), Modeling the mm projectile for ballistic impact computations Computational Ballistics II WIT on Modelling and Simulation, Trans, 14, 61. ; Medvedovski (2010), Ballistic performance of armour ceramics : Influence of design and structure Part Ceramics, Int, 36. ; Jovicic (2000), Modeling of the ballistic behavior of gradient design composite armors Part, Composites, 31. ; Johnson (1983), A constitutive model and data for metals subjected to large strains high strain rates and high temperatures th Ballistics, Proc Int Symp, 7, 541. ; Yungwirth (2008), Experiment assessment of the ballistic response of composite pyramidal lattice truss structures composite pyramidal lattice truss structures Part, Composites, 39. ; Holmquist (2012), Modeling the ballistic response of the mm projectile Special Topics, Eur Phys, 14, 206. ; Wilkins (1978), Mechanics of penetration and perforation, Int J Eng Sci, 16. ; Nia (2013), Ballistic resistance of hybrid - cored sandwich plates : numerical and experimental assessment Part, Composites, 46.
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