高速冲击加载下碳纤维复合材料层合结构抗侵彻特性及响应机理

蔡宣明1, 潘成龙2, 郭安肖1, 张迅1, 高玉波1, 范志强1

振动与冲击 ›› 2024, Vol. 43 ›› Issue (12) : 88-96.

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振动与冲击 ›› 2024, Vol. 43 ›› Issue (12) : 88-96.
论文

高速冲击加载下碳纤维复合材料层合结构抗侵彻特性及响应机理

  • 蔡宣明1,潘成龙2,郭安肖1,张迅1,高玉波1,范志强1
作者信息 +

Anti-penetration characteristics and response mechanism of carbon fiber reinforced plastic laminated structures under high-impact loading

  • CAI Xuanming1,PAN Chenglong2,GUO Anxiao1,ZHANG Xun1,GAO Yubo1,FAN Zhiqiang1
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文章历史 +

摘要

碳纤维复合材料(Carbon Fiber Reinforced Plastic,CFRP)层合结构在高冲击服役环境中常遭受外来物体冲击作用,使之出现一些不可预测的各种损伤形式,甚至会出现不可控的损伤模式。为确保这些结构的安全性和可靠性,对碳纤维复合材料层合结构抗冲击响应及防护机理展开了研究。以碳纤维复合材料层合结构作为研究对象,基于一级轻气炮构建高速冲击加载试验装置,探明了碳纤维复合材料层合结构能量吸收特性与冲击能量之间的联系规律,结合弹道极限方程,确定了其弹道极限,并明确了不同冲击速度作用下的损伤模式。同时引入内聚力单元进行数值模拟仿真研究,探明了碳纤维复合材料层合结构层与层之间内聚力单元的损伤模式,揭示了其在高速冲击加载环境下的损伤机制。研究结果为反向设计适用于高速冲击加载环境复合材料层合结构提供理论依据。

Abstract

Carbon Fiber Reinforced Plastic (CFRP) laminated structures are often subjected to the impact of foreign objects in high-impact service environments, which results in a number of unpredictable forms of damage and even uncontrollable damage patterns. In order to ensure the safety and reliability of these structures, the impact response and protection mechanism of carbon fiber composite laminated structures have been studied. Taking the carbon fiber composite laminated structure as the research object, a high-speed impact loading test device is constructed based on a first-stage light air gun, the linkage law between the energy absorption characteristics of the carbon fiber composite laminated structure and the impact energy is explored, the ballistic limit is determined by combining with the ballistic limit equations, and the damage modes under the effect of different impact velocities are clarified. At the same time, the cohesion unit is introduced to carry out numerical simulation research, which proves the damage mode of the cohesion unit between layers of the carbon fiber composite laminated structure, and reveals its damage mechanism under the high-speed impact loading environment. The results provide theoretical basis for the reverse design of composite laminated structures suitable for high-speed impact loading environment.

关键词

冲击 / 复合材料层合结构 / 能量吸收 / 抗侵彻性能

Key words

Impact / Composite laminated structure / Energy absorption / Anti-penetrating performance

引用本文

导出引用
蔡宣明1, 潘成龙2, 郭安肖1, 张迅1, 高玉波1, 范志强1. 高速冲击加载下碳纤维复合材料层合结构抗侵彻特性及响应机理[J]. 振动与冲击, 2024, 43(12): 88-96
CAI Xuanming1, PAN Chenglong2, GUO Anxiao1, ZHANG Xun1, GAO Yubo1, FAN Zhiqiang1. Anti-penetration characteristics and response mechanism of carbon fiber reinforced plastic laminated structures under high-impact loading[J]. Journal of Vibration and Shock, 2024, 43(12): 88-96

参考文献

[1] Li X M, Liu P, Cheng H, et al. Impact damage prediction of CFRP laminates with rubber protective layer using back-propagation neural networks [J]. International Journal of Advanced Manufacturing Technology, 2023, 127:3281-3296. [2] Patel M, Patel S, Ahmad S. Blast analysis of efficient honeycomb sandwich structures with CFRP/Steel FML skins [J]. International Journal of Impact Engineering, 2023, 178: 104609. [3] Dong F, Ma Q H , Qin X Y, et al. Failure analysis of Al/CFRP hybrid tube with initial damage during axial compression [J]. Thin-Walled Structures, 2022, 181: 110108. [4] Liu Y, Li Q N, Qi Z C, et al. Rapid prediction of thrust force coupling scale-span model and revised ANN in drilling CFRPs [J]. International Journal of Advanced Manufacturing Technology, 2021, 116:2255-2268. [5] Lozano C, Langsto M, Kashefizadeh M H, et al. Analytical and experimental investigation into pre-stressed carbon fiber reinforced polymer (CFRP) fatigue retrofits for steel waterway lock-gate structures [J]. Metals, 2022, 12: 88. [6] Guo C, He J. Multi-scale concurrent analysis for bio-inspired helicoidal CFRP laminates and experimental investigation [J]. Composite Structures, 2022, 296: 115886. [7] Mohamed H S, Shao Y B, Chen C, et al. Static strength of CFRP-strengthened tubular TT-joints containing initial local corrosion defect [J]. Ieee Journal of Oceanic Engineering, 2021, 236: 109484. [8] 张建国,张春. 基于CFD数值计算的大跨悬索桥碳纤维矩形截面吊杆风致振动研究 [J]. 振动与冲击,2023,42(18):199-205. ZHANG Jianguo,ZHANG Chun. Wind-induced vibration of carbon fiber rectangular hangers of large-span suspension bridges based on CFD analysis [J]. Journal of Vibration and Shock, 2023,42(18):199-205. [9] 马钢,高松涛,王卓然,等. 低速冲击下纤维混凝土梁的动力学特征与断裂耗能研究 [J]. 振动与冲击,2022,41(8):208-216. MA Gang,GAO Songtao,WANG Zhuoran,et al. Dynamic characteristics and fracture energy dissipation of fiber reinforced concrete beams under low - velocity impact [J]. Journal of Vibration and Shock, 2022,41(8):208-216. [10] 郭亚周,刘小川,白春玉,等. 短纤维对泡沫铝压缩力学性能与吸能特性的影响研究 [J]. 振动与冲击,2021,40(2):57-62. GUO Yazhou,LIU Xiaochuan,BAI Chunyu,et al. Effect of short fibers on compressive mechanical properties and energy absorption properties of aluminum foam [J]. Journal of Vibration and Shock, 2021,40(2):57-62. [11] Yang Z, Jiang R S, Zuo Y J, et al. Riveting damage behavior and mechanical performance assessments of CFRP/CFRP single-lap gasket-riveted joints [J]. Engineering Failure Analysis, 2023, 149: 107253. [12] Wang H T, Bian Z N , Chen M S, et al. Flexural strengthening of damaged steel beams with prestressed CFRP plates using a novel prestressing system [J]. Glass Structures & Engineering, 2023, 284: 115953. [13] Liu J L, Su X C. A modified model for ultimate bearing capacity of CFRP-shear-strengthened pre-cracked beams with geopolymer [J]. Multidiscipline Modeling in Materials and Structures, 2022, 18:919-939. [14] Ramadhan A A, Abu Talib A R, Mohd Rafie A S, et al. High Velocity Impact Response of Kevlar-29/Epoxy and 6061-T6 Aluminum Laminated Panels [J]. Materials and Design, 2013, 43: 307-321. [15] Zhang N, Gu X T, Hou W Y. Analysis of interfacial mechanical properties of steel beams strengthened with CFRP Sheets under temperature and creep [J]. Polymers, 2022, 14: 2384. [16] Chen Z P, Qin W H, Liang Y H, et al. Axial compressive performance of seawater sea sand concrete-filled CFRP-stainless steel tube short columns [J]. Construction and Building Materials, 2023, 369: 130501. [17] Liu J A, Dong Z Q, Zhu X Y, et al. Flexural properties of lightweight carbon fiber/epoxy resin composite sandwiches with different fiber directions [J]. Materials Research Express, 2022, 9: 026506. [18] Xu M M, Huang G Y, Dong Y X, et al. An Experimental Investigation into the High Velocity Penetration Resistance of CFRP and CFRP/Aluminium Laminates [J]. Composite Structures, 2018, 188: 450-460. [19] Wang P G, Han X F, Wang Y T, et al. Effect of chloride penetration on CFRP sheet, CFRP-concrete interface, and CFRP-strengthened concrete beams [J]. Structural Concrete, 2023, 24: 4869-4888. [20] Tirillò J, Ferrante L, Sarasini F, et al. High Velocity Impact Behaviour of Hybrid Basalt-Carbon/Epoxy Composites [J]. Composite Structures, 2017, 168: 305-312. [21] Liu L, Zhao Z, Chen W, et al. An Experimental Investigation on High Velocity Impact Behavior of Hygrothermal Aged CFRP Composites [J]. Composite Structures, 2018, 204: 645-657. [22] Zhou J, Liu J, Zhang X, et al. Experimental and Numerical Investigation of High Velocity Soft Impact Loading on Aircraft Materials [J]. Aerospace Science and Technology, 2019, 90: 44-58. [23] Xie, W B, Zhang W, Yang H B, et al. Experimental investigation of high velocity impact response of CFRP laminates subjected to flyer plate impact [J]. Thin-Walled Structures, 2022, 178: 109521. [24] Hashin Z. Fatigue failure criteria for unidirectional fiber composites [J]. Journal of Applied Mechanics, 1981, 48(4): 846-852. [25] 王忠宇. 碳纤维复合材料螺栓连接结构的损伤失效行为及影响因素分析 [D]. 哈尔滨:哈尔滨工业大学,2022.

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