Research progress on ballistic response of advanced composite for ballistic protection
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摘要: 本文对弹道防护用先进复合材料的弹道响应研究及其在工程领域的应用现状进行了综述。首先,基于工程应用研究的试验结果,对超高分子量聚乙烯(UHMWPE)纤维、对位芳香族聚酰胺(PPTA)纤维、芳Ⅲ纤维、聚对苯撑苯并双噁唑(PBO)纤维和聚酰亚胺(PI)纤维等高性能纤维的防弹性能及其复合材料在弹道防护工程领域的应用现状进行了概述,近年来先进复合材料的防弹性能随着纤维力学性能的突破而逐渐提高;其次,讨论了先进复合材料弹道响应的影响因素及其作用机制,发现先进复合材料的塑性拉伸变形是其抵挡弹丸侵彻的主要防弹机制;最后,对弹道防护用先进复合材料的研究方向进行了展望。Abstract: The ballistic response of advanced composite for ballistic protection and its application status in engineering field are reviewed in this paper. Firstly, the bulletproof performance of high-performance fiber is outlined based on the experimental results of engineering application research. Those high-performance fibers include ultra-high molecular weight polyethylene (UHMWPE) fiber, aramid Ⅲ fiber, poly para phenylene terepthalamide (PPTA) fiber, poly-p-phenylene-2,6-benzobisoxazole (PBO), and polyimide (PI) fiber. In addition, the application status of its composite is introduced in the field of ballistic protection engineering. The ballistic performance of advanced composite is gradually improved with the breakthrough of fiber mechanical properties in recent years. Secondly, the influence factors and its working-mechanism of ballistic behavior of advanced composites are discussed. It is found that the plastic tensile deformation of advanced composites is the main ballistic mechanism to resist projectile penetration. Finally, the research outlooks of advanced composite for ballistic application are proposed.
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表 1 弹道防护用高性能纤维的物理性能及其Cunniff速度
${{{{{c}}}^{{{*}}}}}$ Table 1. Physical properties and Cunniff velocity
${{{{{c}}}^{{{*}}}}}$ of bulletproof high-performance fiberTypes of fiber Volume density/(g·cm−3) Tensile strength/(cN·dtex−1) Tensile modulus/(cN·dtex−1) Elongation/% ${{{c}^{*}}} $/(m·s−1) UHMWPE 0.97 34–45 1000–1600 2.60–3.00 514–939 PPTA 1.44 18–21 600–800 2.30–2.50 538–611 PBO 1.56 30.04 961 2.56 715 Aramid Ⅲ 1.43–1.45 25.93 881 2.46 662 PI 1.43 25.74 865 2.59 670 PIPD[12] 1.70 31.81 2100 1.4 679 Notes: UHMWPE—Ultra-high molecular weight polyethylene; PPTA—Poly para phenylene terepthalamide; PBO—Poly-p-phenylene-2,6-benzobisoxazole; PI—Polyimide; PIPD—Poly[2,6-diimidazo(4,5-b:4′,5′-e)pyridinylene-1,4(2,5-dihydroxy) phenylen]. 表 2 先进复合材料弹道响应的影响因素
Table 2. Influence factors of ballistic behavior of advanced composite
Type of influence factor Specification Component material properties and structure Fiber property; Matrix property; Interface property; Macro- and micro- structure; Material content; Thickness or areal-density; Hybrid Molding process parameter Consolidation pressure; Consolidation temperature; Consolidation time Ballistic test parameter Projectile core material; Projectile geometry; Impacting velocity; Shooting angle; Shooting state; Shooting distance Service environment Temperature; Preload -
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