This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 3.0 License.
David N.V., Gao X.-L., Zheng J.K. Ballistic Resistant Body Armor: Contemporary and Prospective Materials and Related Protection Mechanisms. Applied Mechanics Reviews; Volume 62: 050802-1Search in Google Scholar
Abtew M.A., Boussu F., Bruniaux P., Loghin C., Cristian I. Ballistic impact mechanisms – A review on textiles and fiber-reinforced composites impact responses, Composite Structures, 2019, 223 110966, https://doi.org/10.1016/j.compstruct.2019.110966Search in Google Scholar
Chen X., Zhou Y., Wells G. Numerical and experimental investigations into ballistic performance of hybrid fabric panels. Composites: Part B 58 (2014) 35–42Search in Google Scholar
Chen Introduction, in Advanced Fibrous Composite Materials for Ballistic Protection, pp 2016 Elsevier LtdSearch in Google Scholar
Lewis E., Carr D.J. Personal armor, in Lightweight Ballistic Composites. Military and Law-Enforcement Applications, pp 217-230, Second Edition, editor by Ashok Bhatnagar, Woodhead Publishing, Elsevier, Amsterdam, Netherland, 2016Search in Google Scholar
Lewis E., Carr D.J. Pushing the limits of possibility, (accessed 13.05.2023), https://www.dupont.com/brands/kevlar.htmlSearch in Google Scholar
Finckernor M.M. Comparison of high-performance fiber materials properties in
simulated and actual space environments. NASA Tech. Rep.; 2017,
https://ntrs.nasa.gov/citations/20170006996Search in Google Scholar
Abtew M.A., Boussu F., Bruniaux P., Loghin C., Cristian I., Yan Chen, L. Wang. Ballistic impact performance and surface failure mechanisms of two-dimensional and three-dimensional woven p-aramid multi-layer fabrics for lightweight women ballistic vest applications Journal of Industrial Textiles, 2021, Vol. 50(9) 1351–1383, DOI: 10.1177/1528083719862883Search in Google Scholar
Bhatnagar A. (Editor) (2016). Lightweight ballistic composites (2nd ed.), Woodhead Publishing, Elsevier.Search in Google Scholar
Bhatnagar A. (Editor) (2016) Ballistic Resistance of Body Armor NIJ Standard-0101.06, https://www.ojp.gov/pdffiles1/nij/223054.pdfSearch in Google Scholar
Gotts P. International ballistic and blast specifications and standards, pp 115-156, in Lightweight Ballistic Composites. Military and Law-Enforcement Applications, 2nd Edition, A. Bhatnagar (editor) Woodhead Publishing, Elsevier, 2016Search in Google Scholar
Grujicic M. Multiscale modeling of polymeric composite materials for ballistic protection, in Advanced Fibrous Composite Materials for Ballistic Protection, pp 323-361, 2016 Elsevier LtdSearch in Google Scholar
Sockalingam S., Gillespie Jr. J.W.,& Keefe M. Role of Inelastic Transverse Compressive Behavior and Multiaxial Loading on the Transverse Impact of Kevlar KM2 Single Fiber, Fibers. 2017; Volume 5(9); doi:10.3390/fib5010009Search in Google Scholar
Nilakantan G. Filament-level modeling of Kevlar KM2yarns for ballistic impact studies, Composite Structures 104 (2013) 1–13,http://dx.doi. org/ 10.1016/j. compstruct.2013.04.001Search in Google Scholar
Endruweit A., Zeng X., Matveev M., Long A.C. Effect of yarn cross-sectional shape on
resin flow through inter-yarn gaps in textile reinforcements, Composites Part A: Applied Science and Manufacturing, Volume 104, 2018, 139-150,
https://doi.org/10.1016/j.compositesa.2017.10.020.Search in Google Scholar
Wong C.C., Long A.C., Sherburn M., Robitaille F., Harrison P., Rudd C.D. Comparisons of novel and efficient approaches for permeability prediction based on the fabric architecture, Composites Part A: Applied Science and Manufacturing, Volume 37(6), 2006, pp. 847-857, https://doi.org/10.1016/j.compositesa.2005.01.020.Search in Google Scholar
Grujicic M, Bell W, Arakere G, He T, Xie X, Cheeseman B. Development of a meso-scale material model for ballistic fabric and its use in flexible-armor protection systems. J Mater Eng Perform 2010;19(1):22-39Search in Google Scholar
Ojoc G.G.; Chiper Titire L.; Munteniță C.; Pîrvu C.; Sandu S.; Deleanu L. Ballistic Response of a Glass Fiber Composite for Two Levels of Threat. Polymers 2023, 15, 1039. https://doi.org/10.3390/polym15041039Search in Google Scholar
Tan P., Lee B., Tsangalis C. 2010, Finite element analysis of sandwich panels subjected to shock tube blast loadings, Journal of Sandwich Structures and Materials, 13(3), pp. 263-278Search in Google Scholar
Børvik S. Dey & Clausen A.H.. Perforation resistance of five different high-strength steel plates subjectedto small-arms projectiles, International Journal of Impact Engineering, 36, 948-964, doi:10.1016/j.ijimpeng.2008.12.003, 2009Search in Google Scholar
Giglio M., Gilioli A., Manes A., Peroni L. & Scapin M., Investigation about the influence of the mechanical properties of lead, EPJ Web of Conferences, 26, 04010, doi: 10.1051/epjconf/20122604010, 2012Search in Google Scholar
Peroni L., Scapin M.; Fichera C.; Manes A., Giglio M. Mechanical properties at high strain-rate of lead core and brass jacket of aNATO 7.62 mm ball bullet in numerical simulations of ballistic impacts. Proc. DYMAT 2012, 26, 01060.Search in Google Scholar
Grujicic M., Snipes J., Avuthu S.R.V., Yen C.-F., Cheeseman B. 2016, Derivation of the material models for ultra-high molecular-weight polyethylene fiber-reinforced armor-grade composites with different architectures, Engineering Computations, 33(3), pp. 926-956Search in Google Scholar
Ojoc G.G, Totolici Rus V., Popescu C., Pirvu C. & Deleanu L. (2020). Influence of friction in a case of impact simulation. INCAS BULLETIN. 12. 145-154. 10.13111/2066-8201.2020.12.4.13.Search in Google Scholar
Pirvu C., Deleanu L. Ballistic Testing of Armor Panels Based on Aramid, 2018, DOI: 10.5772/intechopen.78315, in Ballistics, C. Osheku (editor), IntechOpen Tan P., 2014, Ballistic protection performance of curved armor systems with or without debondings/delaminations, Materials and Design, 64, pp. 25–34.Search in Google Scholar
