Development of a Composite Material for Impact Load

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Abstract

The goal of this work was to invent a high energy absorbing composite material. This composite needs to be able to attach on the building's surfaces and increase blast-resistance. In this innovation, the test samples were reinforced with aramidfiber, glass fiber and carbon fiber and tested by Charpy pendulum impact testing machine. During the tests, the aramid and glass fiber reinforced composites showed good resistance and high energy absorption against impact load.

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  • [1] Ashby M. F. Jones D. R. H.: Engineering Materials 1. An Introduction to PropertiesApplications and Design. Third Edition Elsevier Butter-worth-Heineman Cambridge UK P.K. 2005.

  • [2] Szakali M. Szűcs E.: The defence planning model formation and development / Védelmi tervezésimodellek kialakulása és fejlődése. Hadmérnök 12/1. (2017) 24–40. ISSN 1788-1919

  • [3] Malick P. K.: Fiber-reinforces composites. Third edition. Taylor and Francis Boca Raton USA 2008.

  • [4] Ráthy I. Pinke P. Huszák Cs.: PP mátrixú fröccsöntött kompozitok mechanikai vizsgálatai. Acta Materialia Transylvanica 1. (2018) 105–109. https://doi.org/10.2478/amt-2018-0039

  • [5] Lange D.: A review of blast loading and explosions in the context of multifunctional buildings. Fire technology SP Technical Research Institut of Sweden 2013. ISSN 0284-5172

  • [6] Gay E. Berthe L. Boustie M. Arrigoni M. Buzaud E.: Effects of the shock duration on the response of CFRP composite laminates. Journal of Physics D: Applied Physics 2014 https://doi.org/10.1088/0022-3727/47/45/455303

  • [7] Zvaková Z. Figuli L. Guttenová D.: Analysis of blast load steel beam. Juniorstav 2014 VUT Brno ISBN 978-80-214-4851-3.

  • [8] Figuli L. Jangl Š. Papán D.: Modelling and Testing of Blast Effect On the Structures. IOP Conference Series: Earth and Environmental Science 44. (5) 052051 https://doi.org/10.1088/1755-1315/44/5/052051

  • [9] Lu G. Yu T.: Energy absorption of structures and materials. Woodhead Publishing Limited Cambridge England 2000.

  • [10] Qiao P. Yang M. Bobaru F.: Impact Mechanics and High-Energy Absorbing Materials: Review. Journal of Aerospace Engineering 21/4. (2008) 235–248. https://doi.org/10.1061/(ASCE)0893-1321 (2008) 21:4(235)

  • [11] Zhou H. Wang X. Ma G.. Liu Z.: On the effectiveness of blast mitigation with lightweight claddings. Procedia Engineering 210. (2017) 148–153. https://doi.org/10.1016/j.proeng.2017.11.060

  • [12] Figuli L. Štaffenová D.: Practical Aspect of Methods Used for Blast Protection. Key Engineering Materials 755. (2017) 139–146. https://doi.org/10.4028/www.scientific.net/KeM.755.139

  • [13] Daruka N. Kugyela L.: Ipari robbanóanyagok megjelenésének lehetőségei az improvizált robbanószerkezetek kialakításának tekintetében. Robbantástechnika 35. (2018) 155–174.

  • [14] Galusca D. G. Galusca L. Tóth L.: Analyses of Deformation of Fibre Reinforced Composits. In: microCAD'98 M Section: International Computer Science Conference. Miskolci Egyetem 1998.

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