[Anon., PN-EN 13261: 2020. Railway applications – Wheelsets and bogies - Axles - Product requirements.]Search in Google Scholar
[Anon., PN-EN 45545-1: 2013. Railway applications – Fire protection on railway vehicles – Part 1: General.]Search in Google Scholar
[Anon., PN-EN 45545-2: 2021. Railway applications – Fire protection on railway vehicles – Part 2: Requirements for fire behaviour of materials and components.]Search in Google Scholar
[Anon., PN-EN ISO 2808: 2019. Paints and varnishes – determination of film thickness.]Search in Google Scholar
[Anon., PN-EN ISO 4624: 2016. Paints and varnishes – Pull – off test for adhesion.]Search in Google Scholar
[Anon., PN-EN ISO 5658-2. Reaction to fire tests - Spread of flame. Part 2: Lateral spread on building and transport products in vertical configuration.]Search in Google Scholar
[Anon., PN-EN ISO 5659-2:2012. Plastics - Smoke generation - Part 2: Determination of optical density by a single-chamber test.]Search in Google Scholar
[Anon., PN-EN ISO 5660-1. Plastics – Reaction-to-fire tests-Heat release, smoke production and mass loss rate – Part 1: Heat re-lease rate (cone calorimeter method) and smoke production rate (dynamic measurement).]Search in Google Scholar
[Anon., PN-EN ISO 6272: 2011. Paints and varnishes – Rapid – deformation (impact resistance) tests – Part 2: Falling – weight test, large-area indenter.]Search in Google Scholar
[Burakowski, T., 2013. Areologia – podstawy teoretyczne. Wydawnictwo Naukowe Instytutu Technologii Eksploatacji – PIB, Radom.]Search in Google Scholar
[Dudek, A., Włodarczyk, R., 2010. Structure and Properties of Bioceramics Layers used for Implant Coatings. Solid State Phenomena, 165, 31-36.10.4028/www.scientific.net/SSP.165.31]Search in Google Scholar
[He, Y., Wu, Y., Qu, W., Zhang, J., 2022. Crack-Resistant Amino Resin Flame-Retardant Coatings Using Waterborne Polyurethane as a Co-Binder Resin. Materials, 15, art. 4122.10.3390/ma15124122923114235744180]Search in Google Scholar
[Hong, L., Hu, X., Rao, W., Zhang, X., 2015. Flame retardancy and crack resistance of transparent intumescent fire-resistive coatings. Journal of Applied Polymer Science, 132 (35), art. 42423.10.1002/app.42423]Search in Google Scholar
[Hornsby, P. R., 2001. Fire Retardant Fillers for Polymers. International Materials Reviews, 46(4), 199-210.10.1179/095066001771048763]Search in Google Scholar
[Hyrynkiewicz, T., 1999. Technologia powierzchni i powłok. Wydawnictwo Uczelniane Politechniki Koszalińskiej, Koszalin.]Search in Google Scholar
[Jańczewski, D., Różycki, C., Synoradzki, L., 2010. Projektowanie procesów technologicznych. Matematyczne metody planownia eksperymentów. Oficyna Wydawnicza Politechniki Warszawskiej, Warszawa.]Search in Google Scholar
[Kozłowska, A., 1987. Węzłowe zagadnienia naukowe i techniczne warunkujące rozwój technologii powłok ochronnych w XX wieku. Instytut Mechaniki Precyzyjnej, Warszawa.]Search in Google Scholar
[Liu, X., Guo, J., Sun, J., Gu, X., Feng, W., Liu, W., Li, H., Zhang, S., 2019. The preparation of a bisphenol A epoxy resin based ammonium polyphosphate ester and its effect on the char formation of fire resistant transparent coating. Progress in Organic Coatings, 129, 349-356.10.1016/j.porgcoat.2019.01.003]Search in Google Scholar
[Pasieczyński, Ł., Radek, N., Radziszewska-Wolińska, J., 2018. Operational properties of anti-graffiti coating systems for rolling stock. Advances in Science and Technology Reasearch Journal, 12(1), 127-134.10.12913/22998624/85705]Search in Google Scholar
[Pietraszek, J., Radek, N., Goroshko, A., 2020. Challenges for the DOE methodology related to the introduction of Industry 4.0. Production Engineering Archives, 26(4), 190-194.10.30657/pea.2020.26.33]Search in Google Scholar
[Radek, N., 2009. Determining the operational properties of steel beaters after electrospark deposition. Eksploatacja i Niezawodność - Maintenance and Reliability, 4 (44), 10-16.]Search in Google Scholar
[Radek, N. et al., 2014. Electrospark alloying of carbon steel with WC-Co-Al2O3: deposition technique and coating properties. Advanced Materials Research, 874, 101-106.10.4028/www.scientific.net/AMR.874.101]Search in Google Scholar
[Radek, N. et al., 2018. The impact of laser processing parameters on the properties of electro-spark deposited coatings. Archives of Metallurgy and Materials, 63(2), 809-816.]Search in Google Scholar
[Radziszewska-Wolińska, J., Milczarek, D., 2018. Fire Tests of Non-Metallic Materials for Walls and Ceilings in Rolling Stock. Materials Research Proceedings, 5, 90-95.]Search in Google Scholar
[Radziszewska-Wolińska, J., Radek, N., Pasieczyński, Ł., 2018. Fire properties of “anti-graffiti” coating systems for rolling stock. 11th International Scientific and Technical Conference on Automotive Safety, Casta Papiernicka, Slovakia, 1-5.10.1109/AUTOSAFE.2018.8373329]Search in Google Scholar
[Radziszewska-Wolińska, J., Tarka, I., 2018. The Influence of Reinforcing Layers and Varnish Coatings on the Smoke Properties of Laminates Based on Selected Vinyl Ester and Polyester Resins. Materials Research Proceedings, 5, 210-215.]Search in Google Scholar
[Ulewicz, R., Sztaniak, P., Novy, F., 2014. Fatigue Properties of Wear Resistant Martensitic Steel. 23th International Conference on Metallurgy and Materials, Ostrava, Tanger, 784-789.]Search in Google Scholar
[Weil, E. D., 2011. Fire-protective and flame-retardant coatings-A state-of-the-art review. Journal of Fire Sciences, 29, 259-296.10.1177/0734904110395469]Search in Google Scholar
[Yang, F., 2017. Fire-retardant carbon-fiber-reinforced thermoset composites. Chapter in book: Novel Fire Retardant Polymers and Composite Materials, Elsevier Ltd., Amsterdam, 271-293.10.1016/B978-0-08-100136-3.00010-8]Search in Google Scholar
[Żurawski, W., Chatys, R., Radek, N., Borowiecka-Janrozek, J., 2008. Plasma sprayed composite coatings with reduced friction coefficient. Surface & Coatings Technology, 202, 4578-4582.10.1016/j.surfcoat.2008.04.026]Search in Google Scholar