骨料粒径对混凝土靶抗高速破片侵彻影响的实验研究

doi:10.3969/j.issn.1000-1093.2012.08.019

摘要/Abstract

摘要： 为考察骨料粒径对混凝土材料抗高速破片侵彻的影响，利用轻气炮加速装置和激光测试系统进行素混凝土(PC)和钢纤维增强混凝土(SFPC)侵彻实验研究，通过高速摄像机记录弹体着靶姿态和靶体动态损伤过程。实验中混凝土靶选用5～10 mm、10～15 mm、15～20 mm 3种不同级别骨料粒径，通过对侵彻深度、成坑体积以及靶体碎片剥落过程的比较发现：针对素混凝土靶体，3种级别粒径范围内，级别最大的骨料粒径靶体其抗侵彻能力达到最强；而对于钢纤维含量为1%的钢纤维增强混凝土，粒径级别为10～15 mm的靶体抗侵彻能力最佳，结合骨料粒径对混凝土断裂能的双重作用，表明钢纤维的含量与骨料粒径之间存在一个优化值，在这个优化值配比下，钢纤维增强混凝土抗高速破片的侵彻能力能够达到比较理想的效果。实验结果的讨论分析对混凝土防护工程的设计具有借鉴作用。

关键词: 爆炸力学, 抗侵彻, 骨料粒径, 高速破片, 成坑体积

Abstract: In order to investigate the effect of aggregate size on the anti-penetration ability of concrete targets subjected to high-velocity fragments, a two-stage light-gas gun as the accelerate facility and laser light barrier measurement system were employed to conduct the penetration experiments for plain concrete targets and steel fiber-reinforced concrete targets, and the projectile pose and the dynamic damage process of targets were recorded by a high-speed camera. In the experiments, three different aggregate sizes on 5～10 mm, 10～15 mm and 15～20 mm were involved. The results of penetration depth, crate volume and debris spall processes indicate that the large aggregate size corresponds to the increase of anti-penetration ability for plain concrete targets, but the target with 10～15 mm of aggregate size has the optimum efficiency in terms of anti-penetration ability when comparing to the other two kinds of concrete targets for steel fiber-reinforced concrete targets with 1% steel fiber in volume. Considered the effect of aggregate size on the fracture energy of concrete materials, it indicates that there exists an optimum ratio between the content of steel fiber and aggregate size, and under the optimum ratio, the ability of anti-penetration of concrete targets can reach the maximum value. The results in this paper is very beneficial to the design of protection engineering.

Key words: mechanics of explosion, anti-penetration ability, aggregate size, high-velocity fragment, crate volume

中图分类号:

O383

张伟，慕忠成，肖新科. 骨料粒径对混凝土靶抗高速破片侵彻影响的实验研究[J]. 兵工学报, 2012, 33(8): 1009-1015.

ZHANG Wei， MU Zhong-cheng, XIAO Xin-ke. Experimental Study on Effect of Aggregate Size to Anti-penetration Ability of Concrete Targets Subjected toHigh-velocity Fragments[J]. Acta Armamentarii, 2012, 33(8): 1009-1015.

参考文献

［1］ Anderson W F, Watson A J, Armstrong P J. Fiber reinforced concretes for the protection of structures against high velocity impact[C]∥Proceedings of the International Conference on Structural Impact and Crashworthiness. London: Imperial College, 1984: 687-695.
[2］ Luo X, Sun W, Chan S Y N. Characteristics of high-performance steel fiber-reinforced concrete subject to high velocity impact[J]. Cement Concrete Research, 2000, 30(6): 907-914.
[3］纪冲，龙源，万文乾，等. 钢纤维混凝土抗侵彻与贯穿特性的实验研究[J]. 爆炸与冲击, 2008, 28(2): 178-185.
JI Chong, LONG Yuan, WAN Wen-qian, et al. On anti-penetration and anti-perforation characteristics of high-strength steel fiber-reinforced concrete［J］. Explosion and Shock Waves, 2008, 28(2): 178-185. (in Chinese)
[4］ Mu Z C, Zhang W, Pang B J, et al. Resistance of plain and steel fiber-reinforced concrete slabs against short ogival projectiles impact [C]∥Proceeding of the Fourth International Conference on Experimental Mechanics. Singapore: 2010, 7522(752204): 1-8.
[5］ Langberg H, Markeset G. High performance concrete-penetration resistance and material development [C]∥Proceedings of the Ninth International Symposium on Interaction of the Effects of Munitions with Structures. Strausberg, Berlin: Norwegian Defense Construction Service, 1999: 933-941.
[6］ Wang Y H, Wang Z D, Liang X Y, et al. Experimental and numerical studies on dynamic compressive behavior of reactive powder concretes[J]. Acta Mechanica Solida Sinica, 2008, 21(5): 420-430.
[7］ Hanchak S J, Forrestal M J, Young E R, et al. Perforation of concrete slabs with 48 MPa (7 ksi) and 140 MPa (20 ksi) unconfined compressive strengths[J]. International Journal of Impact Engineering, 1992, 12(1): 1-7.
[8］ Dancygier A N, Yankelevsky D Z. High strength concrete response to hard projectile impact[J]. International Journal of Impact Engineering, 1996, 18(6): 583-599.
[9］ Bludau C, Keuser M, Kustermann A. Perforation resistance of high-strength concrete panels[J]. Structural Journal, 2006, 103(2): 188-195.
[10］ Zhang M H, Shim V P W, Lu G, et al. Resistance of high-strength concrete to projectile impact[J]. International Journal of Impact Engineering, 2005, 31(7): 825-841.
[11］ Chen B, Liu J Y. Effect of aggregate on the fracture behavior of high strength concrete[J]. Construction and Building Materials, 2004, 18(8): 585-590.
[12］王成启. 集料粒径对不同几何尺寸纤维混凝土力学性能的影响[J]. 混凝土, 2009, (6): 247-251.
WANG Cheng-qi. Effects of maximum aggregates size on mechnical properties of different geometry size fiber concrete[J]. Concrete, 2009, (6): 247-251. (in Chinese)
[13］陈小伟. 穿甲/侵彻问题的若干工程研究进展[J]. 力学进展, 2009, 39(3): 316-351.
CHEN Xiao-wei. Advances in the penetration/perforation of rigid projectiles[J]. Advances in Mechanics, 2009, 39(3): 316-351. (in Chinese)
[14］ Chen X W, Fan S C, Li Q M. Oblique and normal penetration/perforation of concrete target by rigid projectiles[J]. International Journal of Impact Engineering, 2004, 30(6): 617-637.
[15］ Li Q M, Reid S R, Wen H M, et al. Local impact effects of hard missiles on concrete targets[J]. International Journal of Impact Engineering, 2005, 32(1-4): 224-284.
[16］ Tate A. Further results in the theory of long rod penetration[J]. Journal of the Mechanics and Physics of Solids, 1969, 17(3): 140-150.
[17］ Christman D R, Gehring J W. Analysis of high-velocity projectile penetration mechanics[J]. Journal of Applied Physics, 1966, 37(4): 1579-1587.
[18］周劲松，杨德庄. 高速碰撞下弹坑的成坑规律研究[J]. 哈尔滨工业大学学报, 1999, 31(3): 132-136.
ZHOU Jin-song, YANG De-zhuang. Formation of craters by hypervelocity impact[J]. Journal of Harbin Institute of Technology, 1999, 31(3): 132-136. (in Chinese)

[1]	余雯君, 陈胜云, 邓树新, 于冰冰, 晋冬艳. 爆炸冲击波在变向通道中传播规律数值模拟[J]. 兵工学报, 2023, 44(S1): 180-188.
[2]	王晓东, 徐永杰, 董方栋, 王昊, 郑娜娜. 凯夫拉与陶瓷复合结构抗侵彻性能数值仿真[J]. 兵工学报, 2022, 43(9): 2360-2366.
[3]	田超，李志鹏，董永香. 表面驻留对陶瓷复合结构抗侵彻特性影响[J]. 兵工学报, 2022, 43(5): 1144-1154.
[4]	徐海斌，杨军，仵可，陈博，随亚光，王等旺. 光辐射起爆乙炔银-硝酸银光敏炸药同步性能[J]. 兵工学报, 2022, 43(11): 2791-2797.
[5]	李茂，侯海量，李典，陈鹏宇，李永清，朱锡. 动态爆炸战斗部对舰船舱壁的破片载荷特性研究[J]. 兵工学报, 2019, 40(9): 1804-1818.
[6]	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.
[7]	胡年明，陈长海，朱锡，侯海量. 陶瓷与芳纶层合板叠层结构抗侵彻性能试验研究[J]. 兵工学报, 2018, 39(5): 976-982.
[8]	孔祥韶，王旭阳，徐敬博，郑成，徐双喜，袁天, 吴卫国. 复合防护液舱抗爆效能对比试验研究[J]. 兵工学报, 2018, 39(12): 2438-2449.
[9]	冉春，陈鹏万，李玲，张旺峰. 中高应变率条件下TC18钛合金动态力学行为的实验研究[J]. 兵工学报, 2017, 38(9): 1723-1728.
[10]	陈浩玉，洪仁楷，陈永涛，张世文，任国武，莫俊杰. 用于微层裂物质诊断的小型动量探针技术[J]. 兵工学报, 2017, 38(9): 1729-1735.
[11]	唐廷，周健南. 地震后地下受损拱结构的抗爆炸能力研究[J]. 兵工学报, 2017, 38(9): 1736-1744.
[12]	杨军，李焰，张德志，史国凯，张敏，刘文祥，王昭，熊琛. 光子多普勒测速仪与压杆相结合的冲击波反射压力测试技术[J]. 兵工学报, 2017, 38(7): 1368-1374.
[13]	刘俊，田宙，钟巍，谢淑红. 冲击波作用下单层钢化玻璃抗爆性能的数值模拟研究[J]. 兵工学报, 2017, 38(7): 1402-1408.
[14]	冯君，孙巍巍，刘志林，王晓鸣. 带装甲钢背板的钢纤维混凝土靶抗侵彻试验及数值模拟研究[J]. 兵工学报, 2017, 38(6): 1041-1051.
[15]	李勇，程远胜，张攀，刘均. 空中爆炸载荷下梯度波纹夹层板抗爆性能仿真研究[J]. 兵工学报, 2017, 38(6): 1131-1139.