爆炸冲击波和破片联合作用下玻璃纤维夹芯复合结构毁伤特性实验研究

doi:10.3969/j.issn.1000-1093.2017.05.006

摘要/Abstract

摘要： 为研究爆炸冲击波和破片联合作用下复合夹芯结构的防护能力和毁伤机理，采用TNT和预制破片开展了冲击波和破片联合作用下玻璃纤维夹芯结构的联合毁伤实验。研究玻璃纤维复合夹芯结构的毁伤特性，将其防护能力与芳纶、高强聚乙烯复合夹芯结构进行了量化对比，并分析了冲击波和破片联合作用下复合夹芯结构前面板、芯层、后面板的破坏模式及相应破坏机理。结果表明：选用复合夹芯结构抗冲击波和破片联合毁伤时，同等防护能力所需E玻璃纤维芯层重量分别为芳纶芯层、高强聚乙烯芯层的1.37倍、2.50倍；前面板破坏模式主要由冲击波载荷、破片载荷、芯层约束3方面因素共同决定；破片载荷对芯层破坏模式起主要作用，后面板破坏模式与芯层碰撞、破片载荷两方面因素有关，其中冲击波载荷和芯层碰撞为面载荷，使前后面板产生整体弯曲变形，破片载荷为点载荷，使面板和芯层产生局部的穿甲破孔，芯层约束限制了前面板变形空间。

关键词: 兵器科学与技术, 实验研究, 破坏模式, 防护能力, 复合夹芯结构

Abstract: In order to explore the protection ability and damage mechanism of glassfiber sandwich bulkhead under explosion and fragment loadings，the deformation and failure tests of glassfiber sandwich structure were performed using cast TNT and prefabricated fragments. The damage characteristics of glassfiber composite sandwich structure，of which protection ability is quantitatively compared with those of aramid and high-strength polyethylene composite sandwich structures，are studied，and the failure mode of each layer composite sandwich structure and its corresponding failure mechanism are analyzed. The results show that E-glass core is required to be 1.37 times and 2.50 times heavier than aramid core and high-strength polyethylene core，respectively，when sandwich structure is applied to resist explosion and fragment loadings. The failure mode of front panel is co-determined by three factors，including shock wave，fragment load,and core constraint. Fragment load plays a major role on core failure mode，the failure mode of rear panel is related to core impact and fragment load. The shock wave and core impact are surface loads，which lead to the bending deformation of front and rear panels，the fragment load is point load，which leads to the local piercing holes on panel and core，and the core constraint limits the deformation space of the front panel. Key

Key words: ordnancescienceandtechnology, experimentalinvestigation, failuremode, protectionability, compositesandwichstructure

中图分类号:

李典，侯海量，戴文喜, 朱锡，李茂，陈长海. 爆炸冲击波和破片联合作用下玻璃纤维夹芯复合结构毁伤特性实验研究[J]. 兵工学报, 2017, 38(5): 877-885.

LI Dian， HOU Hai-liang， DAI Wen-xi, ZHU Xi， LI Mao， CHEN Chang-hai. Experimental Investigation on Damage of Glassfiber Sandwich Structure under Explosion and Fragment Loadings[J]. Acta Armamentarii, 2017, 38(5): 877-885.

参考文献

［1］史作飞. 模拟弹与水面舰船防护甲板的对抗研究[D]. 南京:南京理工大学, 2013.
SHI Zuo-fei. Reasearch on simulated missile against the ship deck[D]. Nanjing:Nanjing University of Science and Technology, 2013.(in Chinese)

[2] Longère P, Gae··lle A, Leblé B, et al. Ship structure steel plate failure under near-field air-blast loading: numerical simulations vs experiment[J]. International Journal of Impact Engineering, 2013, 62(24):88-98.
[3] Zhang P, Cheng Y S, Liu J, et al. Experimental and numerical investigations on laser-welded corrugated-core sandwich panels subjected to air blast loading[J]. Marine Structures, 2015, 40:225-246.
[4] 任鹏, 张伟, 刘建华, 等. 水下冲击波作用的铝合金蜂窝夹层板动力学响应研究[J]. 振动与冲击, 2016, 35(2):7-12.
REN Peng, ZHANG Wei, LIU Jian-hua, et al. Dynamic analysis of aluminium alloy honeycomb core sandwich panels subjected to underwater shock loading[J]. Journal of Vibration and Shock, 2016, 35(2):7-12. (in Chinese)
[5] Wadley H N G, Dharmasena K, Chen Y. Compressive response of multilayered pyramidal lattices during underwater shocking loadings[J]. International Journal of Impact Engineering, 2008, 35(9): 1102-1114.
[6] 侯海量, 朱锡, 阚于龙. 轻型陶瓷复合装甲结构抗弹性能研究进展[J]. 兵工学报, 2008, 29(2):208-216.
HOU Hai-liang, ZHU Xi, KAN Yu-long.The advance of ballistic performance of light ceramic composite armour under the impact of projectile[J]. Acta Armamentarii, 2008, 29(2):208-216.(in Chinese)
[7] 王晓强, 朱锡, 梅志远. 纤维增强复合材料抗侵彻研究综述[J]. 玻璃钢/复合材料, 2008(5):47-56.
WANG Xiao-qiang, ZHU Xi, MEI Zhi-yuan. Curing reaction kinetics of cyanate ester/epoxy matrices[J]. Fiber Reinforced Plastic/Composites, 2008(5):47-56.(in Chinese)

[8] 徐豫新, 王树山, 严文康, 等. 纤维增强复合材料三明治板的破片穿甲实验[J]. 复合材料学报, 2012, 29(3):72-78.
XU Yu-xin, WANG Shu-shan, YAN Wen-kang, et al. Armor-piercing experiment on fragment against sandwich plate with fiber reinforced composite cores[J]. Acta Materiae Composite Sinica, 2012, 29(3):72-78. (in Chinese)
[9] 陈长海, 朱锡, 侯海量, 等.结构形式对舰船舷侧复合装甲结构抗穿甲性能的影响研究[J]. 振动与冲击, 2013, 32(14):58-63.
CHEN Chang-hai, ZHU Xi, HOU Hai-liang, et al. Influence of structural configuration on perforation-resistance of a warship topside composite armor system[J]. Journal of Vibration and Shock, 2013, 32(14):58-63. (in Chinese)

[10] 李茂, 朱锡, 侯海量, 等. 冲击波和高速破片对固支方板的联合作用数值模拟研究[J]. 中国舰船研究, 2015, 10(6):60- 67.
LI Mao, ZHU Xi, HOU Hai-liang, et al. Numerical simulation of steel plate subjected to the impact of impact wave and fragments[J]. Chinese Journal of Ship Research, 2015, 10(6):60-67.(in Chinese)
[11] Ulrika N, Gylltoft K. Numerical studies of the combined effects of blast and fragment loading[J]. International Journal of Impact Engineering, 2009, 36(8):995-1005.
[12] 侯海量, 张成亮, 李茂, 等. 冲击波和高速破片联合作用下夹芯复合舱壁结构毁伤特性实验研究[J]. 爆炸与冲击, 2015, 35(1):116-123.
HOU Hai-liang, ZHANG Cheng-liang, LI Mao, et al. Damage characteristics of sandwich bulkhead under the impact of shock and high-velocity fragments[J]. Explosion and Shock Waves, 2015, 35(1):116-123.(in Chinese)
[13] 李典, 朱锡, 侯海量, 等. 近距爆炸破片作用下芳纶纤维夹芯复合舱壁结构毁伤特性实验研究[J]. 兵工学报, 2016, 37(8):1436-1442.
LI Dian, ZHU Xi, HOU Hai-liang, et al. Experimental investigation on damage of aramid fiber sandwich bulkhead under near explosion and fragment loadings[J]. Acta Armamentarii, 2016, 37(8):1436-1442.(in Chinese)
[14] 王晓强, 虢忠仁, 宫平, 等. 抗弹复合材料在舰船防护上的应用研究[J]. 工程塑料应用, 2014, 42(11):143-146.
WANG Xiao-qiang, GUO Zhong-ren, GONG Ping, et al. Application research of bulletproof composites in warship protection[J]. Engineering Plastics Application, 2014, 42(11):143-146. (in Chinese)
[15] 张成亮, 朱锡, 侯海量, 等. 爆炸冲击波与高速破片对夹层结构的联合毁伤效应试验研究[J]. 振动与冲击, 2014, 33(15): 184-188.
ZHANG Cheng-liang, ZHU Xi, HOU Hai-liang, et al. Tests for combined damage effect of blast waves and high fragments on composite sandwich plates[J]. Journal of Vibration and Shock, 2014, 33(15):184-188. (in Chinese)

第38卷第5期
2017 年5月兵工学报ACTA
ARMAMENTARIIVol.38No.5May2017

[1]	杨光瑞, 汪维, 杨建超, 汪剑辉, 王幸. POZD涂覆波纹钢加固钢筋混凝土板抗爆性能[J]. 兵工学报, 2023, 44(5): 1374-1383.
[2]	邓希旻, 田泽, 武海军, 王浩, 黄风雷. 上下非对称结构弹体侵彻金属薄板的特性及薄板破坏形式[J]. 兵工学报, 2023, 44(12): 3836-3850.
[3]	亓晓鹏, 张杰, 赵婷婷, 王志勇, 王志华. 考虑骨料级配的混凝土靶板接触爆炸破坏模式[J]. 兵工学报, 2023, 44(12): 3641-3653.
[4]	赵泽虎, 李祥龙, 胡启文, 王建国. 含铜石榴黑云片岩动态力学特性及损伤本构模型[J]. 兵工学报, 2023, 44(12): 3805-3814.
[5]	周伯俊, 于传强，刘志浩，柯冰. 基于高压储能的特种车辆快速起竖技术与验证[J]. 兵工学报, 2022, 43(7): 1488-1497.
[6]	高月光，冯顺山，刘云辉，黄岐. 不同端盖厚度的圆柱形装药壳体破片初速分布[J]. 兵工学报, 2022, 43(7): 1527-1536.
[7]	张震东，王雪琴，任杰，刘峥，高原，王玺. 连续碳纤维增强环氧树脂复合材料圆管多胞结构的准静态压缩响应[J]. 兵工学报, 2022, 43(5): 1185-1193.
[8]	梁浩哲，张庆明，龙仁荣，任思远. 深水爆炸下凸型加筋锥柱壳结构的破坏模式[J]. 兵工学报, 2021, 42(5): 987-996.
[9]	伍鹏，李高春，韩永恒，赵汝岩，谭洁，刘著卿. 固体火箭发动机矩形粘接试件多角度拉伸过程变形测量与破坏模式[J]. 兵工学报, 2020, 41(11): 2234-2242.
[10]	徐伟，侯海量，朱锡，陈长海，李茂. 平头弹低速冲击下薄钢板的穿甲破坏机理研究[J]. 兵工学报, 2018, 39(5): 883-892.
[11]	石超，强洪夫，刘虎. 含碳颗粒的凝胶推进剂雾化特性实验研究[J]. 兵工学报, 2018, 39(1): 71-82.
[12]	武海军，张爽，黄风雷. 钢筋混凝土靶的侵彻与贯穿研究进展[J]. 兵工学报, 2018, 39(1): 182-208.
[13]	娄伟鹏，郑长松，李和言，陈建文，张周立，马源. 高速《Symbol》v湿式换挡离合器排油阀临界开启和关闭压力研究[J]. 兵工学报, 2017, 38(9): 1665-1672.
[14]	王宪成，杨绍卿，马宁，赵文柱. 车辆柴油机缸套动载荷磨损计算模型研究[J]. 兵工学报, 2017, 38(9): 1673-1680.
[15]	孙皓泽，常天庆，王全东，孔德鹏，戴文君. 一种基于分层多尺度卷积特征提取的坦克装甲目标图像检测方法[J]. 兵工学报, 2017, 38(9): 1681-1691.