泡沫铝夹层结构复合材料低速冲击性能  被引量：9

作　　者：赵金华 曹海琳 晏义伍[1] 丁莉 ZHAO Jin-hua;CAO Hai-lin;YAN Yi-wu;DING Li(Shenzhen Key Laboratory of Composite Materials, Shenzhen Academy of Aerospace Technology, Shenzhen 518057 ,Guangdong,China;School of Chemical Engineering and Technology, Harbin Institute of Technology, Harbin 150001, China)

机构地区：[1]深圳航天科技创新研究院深圳市复合材料重点实验室,广东深圳518057 [2]哈尔滨工业大学化工学院,哈尔滨150001

出　　处：《材料工程》2018年第1期92-98,共7页Journal of Materials Engineering

基　　金：深圳市重点实验室提升项目(ZDSYS20140509152209835);深圳市基础研究(学科布局)项目(JCYJ20160428164113144)

摘　　要：以泡沫铝为夹芯材料,玄武岩纤维(BF)和超高分子量聚乙烯纤维(UHMWPE)复合材料为面板,制备夹层结构复合材料。研究纤维类型、铺层结构和芯材厚度对泡沫铝夹层结构复合材料冲击性能和损伤模式的影响规律,并与铝蜂窝夹层结构复合材料性能进行对比分析。结果表明:BF/泡沫铝夹层结构比UHMWPE/泡沫铝夹层结构具有更大的冲击破坏载荷,但冲击位移和吸收能量较小。BF和UHMWPE两种纤维的分层混杂设计比叠加混杂具有更高的冲击破坏载荷和吸收能量。随着泡沫铝厚度的增加,夹层结构复合材料的冲击破坏载荷降低,破坏吸收能量增大。泡沫铝夹层结构比铝蜂窝夹层结构具有更高的冲击破坏载荷,但冲击破坏吸收能量较小;泡沫铝芯材以冲击部位的碎裂为主要失效形式,铝蜂窝芯材整体压缩破坏明显。Sandwich structural composites were prepared by aluminum foam as core materials with ba-salt fiber（BF） and ultra-high molecular weight polyethylene（UHMWPE） fiber composite as faceplate.The effect of factors of different fiber type faceplates, fabric layer design and the thickness of the core-materials on the impact properties and damage mode of aluminum foam sandwich structure was stud-ied. The impact properties were also analyzed to compare with aluminum honeycomb sandwich struc-ture. The results show that BF/aluminum foam sandwich structural composites has bigger impact damage load than UHMWPE/aluminum foam sandwich structure, but less impact displacement and energy absorption. The inter-layer hybrid fabric design of BF and UHMWPE has higher impact load and energy absorption than the overlay hybrid fabric design faceplate sandwich structure. With the in-crease of the thickness of aluminum foam,the impact load of the sandwich structure decreases, but the energy absorption increases. Aluminum foam sandwich structure has higher impact load than the alu-minum honeycomb sandwich structure, but smaller damage energy absorption; the damage mode of a-luminum foam core material is mainly the fracture at the impact area, while aluminum honeycomb core has obvious overall compression failure.

关 键 词：泡沫铝 夹层结构 玄武岩纤维 超高分子量聚乙烯 冲击性能 

分 类 号：TB332[一般工业技术—材料科学与工程]