[1] BLOKPOEL H. Bird hazards to aircraft[M].Toronto, Canada: Clarke, Irwin & Co.,1976. [2] 张永康,李玉龙,汤忠斌,等.冰雹撞击下泡沫铝夹芯板的动态响应[J].爆炸与冲击,2018,38(2):373-380. ZHANG Y K, LI Y L,TANG Z B, et al. Dynamic response of aluminum-foam-based sandwich panels under hailstone impact[J]. Explosion and Shock Waves, 2018,38(2):373-380. (in Chinese) [3] DIRK S, HANS W. Aluminium foam sandwich structure for space application[J]. Acta Astronautica, 2007,61(1):326-330. [4] JAE U C, SON J H, SANG K L, et al. Impact facture behavior at material of aluminum foam[J]. Material Science and Engineering A, 2012,539 : 250-258. [5] ZHU F, LU G X, RUAN D, et al. Plastic deformation, failure and energy absorption of sandwich structures with metallic cellular cores[J]. International Journal of Protective Structure, 2010, 1(4): 537-541. [6] MOHAN K, YIP T H, SRIDHAR I, et al. Impact response of aluminum foam core sandwich structure[J]. Material Science and Engineering A, 2011,529:94-101. [7] GOLDSMITH W, WANG G T, LI K. Perforation of cellular sandwich plates[J]. International Journal of Impact Engineering, 1997,19(5/6):361-379. [8] DEAN J, S-FALLAH A, BROWN L A. Energy absorption during projectile perforation of light weight sandwich panels with metallic fibre cores[J].Composite Structures, 2011,93:1089-1095. [9] LIU X R, TIAN X G, LU T J, et al. Blast resistance of sandwich-walled hollow cylinders with graded metallic foam cores[J]. Composite Structrres,2012,94:2485-2493.
[10] RADFORD D D, FLECK N A, DESHPANDE V S. The response of clamped sandwich beams subjected to shock loading[J]. International Journal of Impact Engineering,2006,32(6):968-987. [11] 赵桂平,卢天健. 多孔金属夹层板在撞击载荷作用下的动态响应[J].力学学报,2008,40(2):194-206. ZHAO G P, LU T J. Dynamic response of cellular metallic sandwich plates under impact loading[J]. Chinese Journal of Theoretical and Applied Mechanics, 2008,40(2):194-206.(in Chinese) [12] 李志斌,卢芳云. 泡沫铝夹芯板压入和侵彻性能的实验研究[J]. 振动与冲击,2015,34(4):1-5. LI Z B, LU F Y. Test for indentation and perforation of sandwich panels with aluminum foam core[J]. Journal of Vibration and Shock, 2015,34(4):1-5. (in Chinese) [13] 宋延泽,王志华,赵隆茂,等. 撞击载荷下泡沫铝夹层板的动力响应[J]. 爆炸与冲击,2010,30(3):301-307. SONG Y Z, WANG Z H, ZHAO L M, et al. Dynamic response of foam sandwich plates subjected to impact loading[J]. Explosion and Shock Waves, 2010,30(3):301-307. (in Chinese) [14] TIWARI G, IQBAL M A, GUPTA P K, et al. The ballistic resistance of thin aluminum plates with varying degrees of fixity along the circumference [J].International Journal of Impacting Engineering, 2014,74:46-56. [15] 惠旭龙,刘小川,王计真,等. TC4钛合金平板高速撞击损伤及弹道极限特性[J].科学技术与工程,2017,17(11):1-8. XI X L, LIU X C, WANG J Z, et al. High velocity impact failure and ballistic performance of TC4 plate[J]. Science Technology and Engineering,2017,17(11):1-8. (in Chinese) [16] 刘富,张嘉振,童明波,等. 2024-T3铝合金动力学试验及其平板鸟撞动态响应分析[J].振动与冲击,2014,33(4):113-118. LIU F, ZHANG J Z, TONG M B, et al. Dynamic tests and bird impact dynamic response analysis for a 2024-T3 aluminum alloy plate[J]. Journal of Vibration and Shock, 2014,33(4):113-118. (in Chinese) [17] 毛亮,王华,姜春兰,等. 钨合金球形破片侵彻陶瓷/DFRP复合靶的弹道极限速度[J].振动与冲击,2015,34(13):1-5. MAO L, WANG H, JIANG C L, et al. Ballistic limit velocity of tungsten alloy spherical fragment penetrating ceramic/DFRP composite target plates[J]. Journal of Vibration and Shock, 2015,34(13): 1-5. (in Chinese) [18] 杨飞,王志华,赵隆茂. 泡沫铝夹芯板抗侵彻性能的数值研究[J]. 科学技术与工程,2011,11(15):3377-3383. YANG F, WANG Z H, ZHAO L M. Numerical simulation on anti-penetration performance of aluminum foam-based sandwich panels[J]. Science Technology and Engineering,2011,11(15):3377-3383.(in Chinese)
第40卷 第10期2019 年10月兵工学报ACTA ARMAMENTARIIVol.40No.10Oct.2019
|