Fiber–Metal Laminate Panels Subjected to Blast Loading
作者: G. S. Langdon , G. N. Nurick , D. Karagiozova , W. J. Cantwell
DOI: 10.1007/978-1-4419-0446-1_9
关键词: Aluminium 、 Aluminium alloy 、 Materials science 、 Impact resistance 、 Fiber metal laminate 、 Composite number 、 Structural material 、 Composite material
摘要: Fiber–metal laminates (FML) are hybrid metal and composite structural materials that have been attracting interest due to the improved fatigue impact resistance reported in literature (J Mater Proc Tech 103:1–15, 2000; Int J Impact Eng 18(3):291–307, 1996; Compos Struct 61:73–88, 2003; Appl Comput 11:295–315, 2004). Much less is known about their performance under blast loading conditions, as until recently there was very little written on this subject. This chapter reviews experimental numerical studies focus response of FMLs manufactured from aluminium alloy glass fiber-reinforced polymer layers. Herein, difference localized uniformly distributed reviewed, application nondimensional analysis techniques used for steel described, any potential advantages over equivalent areal density panels highlighted.
springer.com
sci-hub.se 参考文章(33)
P. Compston, W. J. Cantwell, C. Jones, N. Jones, Impact perforation resistance and fracture mechanisms of a thermoplastic based fiber-metal laminate Journal of Materials Science Letters. ,vol. 20, pp. 597- 599 ,(2001) , 10.1023/A:1010904930497
Advances in fatigue science and technology Kluwer Academic Publishers. ,(1989) , 10.1007/978-94-009-2277-8
A. Vlot, Impact loading on fibre metal laminates International Journal of Impact Engineering. ,vol. 18, pp. 291- 307 ,(1996) , 10.1016/0734-743X(96)89050-6
G.S. Langdon, W.J. Cantwell, G.N. Nurick, The blast response of novel thermoplastic-based fibre-metal laminates – some preliminary results and observations Composites Science and Technology. ,vol. 65, pp. 861- 872 ,(2005) , 10.1016/J.COMPSCITECH.2004.09.025
P. Cortés, W.J. Cantwell, The prediction of tensile failure in titanium-based thermoplastic fibre–metal laminates Composites Science and Technology. ,vol. 66, pp. 2306- 2316 ,(2006) , 10.1016/J.COMPSCITECH.2005.11.031
Glyn Lawcock, Lin Ye, Yiu-Wing Mai, Chin-Teh Sun, The effect of adhesive bonding between aluminum and composite prepreg on the mechanical properties of carbon-fiber-reinforced metal laminates Composites Science and Technology. ,vol. 57, pp. 35- 45 ,(1997) , 10.1016/S0266-3538(96)00107-8
G. Reyes Villanueva, W.J. Cantwell, The high velocity impact response of composite and FML-reinforced sandwich structures Composites Science and Technology. ,vol. 64, pp. 35- 54 ,(2004) , 10.1016/S0266-3538(03)00197-0
G LANGDON, G NURICK, S LEMANSKI, M SIMMONS, W CANTWELL, G SCHLEYER, Failure characterisation of blast-loaded fibre–metal laminate panels based on aluminium and glass–fibre reinforced polypropylene Composites Science and Technology. ,vol. 67, pp. 1385- 1405 ,(2007) , 10.1016/J.COMPSCITECH.2006.09.010
M. A. McCarthy, J. R. Xiao, N. Petrinic, A. Kamoulakos, V. Melito, Modelling of Bird Strike on an Aircraft Wing Leading Edge Made from Fibre Metal Laminates – Part 1: Material Modelling Applied Composite Materials. ,vol. 11, pp. 295- 315 ,(2004) , 10.1023/B:ACMA.0000037133.64496.13
L.B Vogelesang, A Vlot, Development of fibre metal laminates for advanced aerospace structures Journal of Materials Processing Technology. ,vol. 103, pp. 1- 5 ,(2000) , 10.1016/S0924-0136(00)00411-8