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References [1] Ashby M. F., Evans A. G., Fleck N. A., Gibson L. J., Hutchinson J. W., Wadley H. N. G.: Metal foams. A design guide . Butterworth-Heinemann, 2000. [2] Mankovits T., Budai I., Balogh G., Gábora A., Kozma I., Varga T., Manó S., Kocsis I.: Structural analysis and its statistical evaluation of a closed-cell metal foam. International Review Applied Science Engineering, 5/2. (2014) 135–143. https://doi.org/10.1556/IRASE.5.2014.2.5 [3] Orbulov I. N.: Compressive properties of aluminium matrix syntactic foams . Materials Science and Engineering A, 555

References 1. Kathuria Y.P., A preliminary study on laser assisted aluminum foaming, Journal of Materials Science 38 (2003) 2875 - 2881. 2. Kathuria Y.P., Nd-YAG laser assisted aluminum foaming, Journal of Materials Processing Technology Volume 142, Issue 2, 25 November 2003, Pages 466-470. 3. Malekjafarian M., Sadrnezhaad S.K., Closed-cell Al alloy composite foams: Production and characterization, Materials and Design 42 (2012) 8-12. 4. PN-EN ISO 9013:2008 Thermal cutting - Classification of thermal cuts - Geometrical product specification and quality tolerances

, C.S., Fraga, T. & Pasa, V.M.D. (2016). Production and characterization of polyurethane foams from a simple mixture of castor oil, crude glycerol and untreated lignin as bio-based polyols. Eur. Polym. J. 85, 53–61. 5. Omrani, I., Farhadian, A., Babanejad, N., Shendi, H.K., Ahmadi, A. & Nabid, M.R. (2016). Synthesis of novel high primary hydroxyl functionality polyol from sunflower oil using thiolyne reaction and their application in polyurethane coating. Eur. Polym. J. 82, 220–231. 6. Piszczyk, Ł., Strankowski, M., Danowska, M., Hejna, A. & Haponiuk, J.T. (2014

Literature Cited 1. Armenta, M. (2003). Mechanism and control of water infiow to wells in gas reservoirs with bottom-water drive. Doctoral dissertation, Louisiana State University, USA. 2. Oyewole, P. & Lea, J. (2008). Artificial lift selection strategy for the life of gas well with some liquid production. Annual Technical Conference and Exhibition, 21–24 September 2008. Denver, Colorado, USA: Society of Petroleum Engineers. 3. Huang, F. & Nguyen, D. (2012). Optimized foamers for natural gas well deliquification: A statistical design approach. Fuel 97 (7), 523

References [1] Silva M.C., Takahashi J.A., Chaussy D., Belgacem M.N., Silva G.G. (2010). Composites of rigid polyurethane foam and cellulose residue. Journal of Applied Polymer Science, 117, 3665-3672. [2] Stirna U., Beverte I., Yakushin V., Cabulis U. (2011). Mechanical properties of rigid polyurethane foams at room and cryogenic temperatures. Journal of Cellular Plastics, 47(4), 337-355. [3] Zatorski W., Brzozowski Z.K., Kolbrecki A. (2008). New developments in chemical modification of fire-safe rigid polyurethane foams. Polymer Degradation and Stability, 93

., Wang, Y., Zhang, H.B., Li, X., Gui, C.X., Yu, Z.Z.: Enhanced electromagnetic interference shielding efficiency of polystyrene/graphene composites with magnetic Fe 3 O 4 nanoparticles. Carbon 82 (2015) 67-76. 12. Min, Z., Yang, H., Chen, F., Kuang, T.: Scale-up production of lightweight high-strength polystyrene/carbonaceous filler composite foams with high-performance electromagnetic interference shielding. Materials Letters 230 (2018) 157-160. 13. Wang, C., Xue, T., Dong, B., Wang, Z., Li, H.L.: Polystyrene–acrylonitrile–CNTs nanocomposites preparations and

References 1. Belytschko, T., Lu, Y. Y., Gu, L., Element-Free Galerkin Methods, International Journal for Numerical Methods in Engineering, Vol. 37, 229-256 (1994). 2. Brian Croop, Hubert Lobo, Selecting Material Models for the Simulation of Foams in LS-DYNA, 7th European LS-DYNA Conference, 2009 3. Crisfield M. A., Non-linear Finite Element Analysis of Solids and Structures, John Wiley & Sons, 1988, 2000, ISBN 0 471 95649 X 4. Hallquist O. John, LS-DYNA Theory Manual, 1991-2006 Livermore Software Technology Corporation, ISBN 0-9778540-0-0 5. Liu, G. R., Meshfree

for preparation of Pt-modifi ed electrocatalysts: Application for alkaline water electrolysis. Int. J. Hydrogen Energy 37, 8917-8922. DOI: 10.1016/j.ijhydene.2012.03.008. 12. Bidault, F., Brett, D.J.L., Middleton, P.H., Abson, N. & Brandon, N.P. (2009). A new application for nickel foam in alkaline fuel cells. Int. J. Hydrogen Energy 34, 6799-6808. DOI: 10.1016/j.ijhydene.2009.06.035. 13. Verlato, E., Cattarin, S., Comisso, N., Gambirasi, A., Musiani, M. & Vazquez-Gomez, L. (2012). Preparation of Pd- -Modifi ed Ni Foam Electrodes and Their Use as Anodes for the

References 1. Abe, S., & Yamaguchi, M. (2001). Study on the foaming of crosslinked polyethylene. J. Appl. Polym. Sci., 79 , 2146–2155. 2. Bo, Wang, Mouhua, Wang, Zhe, Xing, Hongyan, Zeng, & Guozhong, Wu. (2013). Preparation of radiation crosslinked foams from low-density polyethylene/ethylene-vinyl acetate (LDPE/EVA) copolymer blend with a supercritical carbon dioxide approach. J. Appl. Polym. Sci. , 127 , 912–918. 3. Stasiek, A., Raszkowska-Kaczor, A., & Bajer, K. (2013). Wpływ obecności środka wspomagającego sieciowanie oraz zawartości środka porującego na

References DERECKI, Tadeusz (1999). Fre-fighting equipment for the administration of water and fire-fighting foams, The Main School of Fire Service Edition, Warsaw1999. (in polish) DERECKI, Tadeusz, WAWRZYŃSKI, Wiktor (1981). Equipment for the manufacture of fire-fighting foam, Editorial Institute of Trade Unions, Warsaw 1981. (in polish) GAŁAJ, Jerzy, PAWLAK, Elżbieta; ZEGAR, Wojciech (2004) Laboratory of Hydromechanics [in:] Gałaj J., Research liquid ejectors used in fire protection, The Main School of Fire Service Edition, Warsaw 2004. (in polish) GIL