不同弹形撞击下泡沫铝夹芯结构动力学性能研究

doi:10.3969/j.issn.1000-1093.2019.10.008

兵工学报 ›› 2019, Vol. 40 ›› Issue (10): 2032-2041.doi: 10.3969/j.issn.1000-1093.2019.10.008

不同弹形撞击下泡沫铝夹芯结构动力学性能研究

郭亚周¹，刘小川¹，何思渊²，王计真¹，杨海¹

(1.中国飞机强度研究所结构冲击动力学航空科技重点试验室，陕西西安 710065；2.东南大学生物科学与医学工程学院，江苏南京 211189）

收稿日期:2018-12-19 修回日期:2018-12-19 上线日期:2019-12-18
通讯作者: 刘小川（1983—），男，研究员，博士 E-mail:asri02@163.com
作者简介:郭亚周（1994—），男，助理工程师，硕士。E-mail: guoyazhoul23@163.com
基金资助:
国家自然科学基金项目（11572087）；陕西省青年科技新星项目（2018KJXX-052）

Research on Dynamic Properties of Aluminum Foam Sandwich Structure Impacted by Projectiles with Different Shapes

GUO Yazhou¹, LIU Xiaochuan¹, HE Siyuan², WANG Jizhen¹, YANG Hai¹

(1.Aviation Key Laboratory of Science and Technology on Structures Impact Dynamics, Aircraft Strength Research Institute of China, Xi'an 710065, Shaanxi, China；2.School of Biological Science & Medical Engineering, Southeast University, Nanjing 211189, Jiangsu, China）

Received:2018-12-19 Revised:2018-12-19 Online:2019-12-18

摘要/Abstract

摘要： 为研究不同弹形撞击下泡沫铝夹芯结构的动力学性能，通过空气炮发射方式分别开展了球形弹、锥头弹和平头弹撞击泡沫铝夹芯板试验。基于非线性动力有限元软件LS-DYNA进行了不同弹形撞击泡沫铝夹芯板的数值仿真，分析了不同弹形、不同速度对夹芯板吸能特性的影响。试验结果与仿真结果一致性较好，结果表明：锥头弹撞击变形模式与球头弹撞击变形模式基本相同，平头弹侵彻过程中产生较严重的冲塞破坏，前面板和后面板呈现撕裂破坏模式，侵彻后夹芯被压实部分泡沫铝粘接在后面板上；锥形弹头部尖锐，弹头与靶的接触区域小、侵彻力大，平头弹的弹头和靶的接触区域大、侵彻力小，但靶面破坏区域大且撞击后效更大，球头弹则居于二者之间；当速度较低时，改善前面板和夹芯板的厚度以及材料性能可以较好地提升泡沫铝夹芯板的性能；当速度较高时，后面板吸能比例逐渐增大，重点改善后面板的厚度和材料性能可以较好地改善夹芯板抗侵彻性能。

关键词: 泡沫铝夹芯板, 弹形, 撞击, 变形模式, 抗侵彻试验

Abstract: The experiments of impacting the aluminum foam sandwich panels by spherical, pointed and flat nose projectiles launched from gas gun were carried to study the dynamic properties of aluminum foam sandwich structure. Based on LS-DYNA software, the impacts of different projectiles on aluminum foam sandwich panels are simulated, and the influences of different projectile shapes and speed on the energy absorption characteristics of sandwich panels are analyzed. The experimental results are well in agreement withe the simulated results. The results show that the deformation mode of pointed projectile is basically the same as that of spherical projectile, the flat nose projectile damages the sandwich panels more seriously during penetrating, the front and rear panels exhibit a tear failure mode, and the compacted aluminum foam is bonded to the rear panel after penetration. The head of pointed projectile is sharp, the contact area between the warhead and the target is small, and the penetration force is large. The contact area between the warhead of flat noise projectile and the target is large, and the penetration force is small, but the target damage area is large and the impact is more effective. The impact effect of spherical projectile is between those of pointed and flat nose projectiles: the improvement in the thicknesses and material properties of front and sandwich panels can better improve the penetration resistance of aluminum foam sandwich panel at low impact speed; the proportion of energy absorption of rear panel increases gradually, the improvement in the thickness and material properties of rear panel can improve the penetration resistance of sandwich panel at high impact speed. Key

Key words: aluminumfoamsandwichpanel, shapeofprojectile, impact, deformationmode, anti-penetrationtest

中图分类号:

V214.1⁺1

郭亚周，刘小川，何思渊，王计真，杨海. 不同弹形撞击下泡沫铝夹芯结构动力学性能研究[J]. 兵工学报, 2019, 40(10): 2032-2041.

GUO Yazhou, LIU Xiaochuan, HE Siyuan, WANG Jizhen, YANG Hai. Research on Dynamic Properties of Aluminum Foam Sandwich Structure Impacted by Projectiles with Different Shapes[J]. Acta Armamentarii, 2019, 40(10): 2032-2041.

参考文献

［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)

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不同弹形撞击下泡沫铝夹芯结构动力学性能研究

Research on Dynamic Properties of Aluminum Foam Sandwich Structure Impacted by Projectiles with Different Shapes

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