Influence of rigid and flexible matrices on ultimate strength and fracture mechanisms of polymer composite materials upon impact and static loading conditions

I. Krylov, N. Korneeva, V. Kudinov
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Abstract

An universal method “Break upon Impact and Static” (RUS) has been developed for the experimental determination of the ultimate strength properties of polymer composite materials based on multifilament nanocrystalline ultra-high molecular weight polyethylene (UHMWPE) fibers, which differs in the method of fixing the sample in a testing machine.The method is carried out using a uniform BIS-sample with an intermediate matrix at the ends and equipment for its attachment to the platforms of testing machines. The sample is a round composite rod composed of the fibers and matrices under investigation, which is held in the tooling by an additional matrix that fixtures it under various loading rates. The RUS method was used to study the properties and mechanisms of destruction upon impact and in a static situation of anisotropic polymer and hybrid composite materials (PCM and HCM) based on flexible and rigid matrices reinforced with hybrid fibers of carbon, aramid, and UHMWPE-fibers activated by non-equilibrium low-temperature plasma. The breaking loads under low-velocity impact and static bending conditions, relative deformation, specific absorbed-in-fracture energy, work of adhesion, shear strength, and other properties are determined. It was found out that the plasticity of the matrix and the hybrid fiber composition affect the properties and fracture mode of PCM and HCM. For the destruction of HCM with a flexible matrix upon impact, a load twice as large as for composites with a rigid matrix is required. HCMs have the highest strength, in which at all stages of loading up to failure, joint deformation of the matrix and the reinforcing fiber occurs. The mechanism of deformation and destruction of anisotropic HCM upon impact is stepwise, while the nature of the deformation curve is zigzag. In statics, the deformation proceeds smoothly. By changing the ratio of carbon and UHMWPE-fibers during hybridization, it is possible to control the properties of HCM and improve its specific properties. The combination of carbon and UHMWPE-fibers in a hybrid fiber for reinforcing a flexible matrix makes it possible to create a material with a delayed fracture. It has been established that for HCM based on a flexible matrix reinforced with a hybrid fiber combining 20 % carbon and 80 % UHMWPE fiber, the fracture load increases by factor 2, the specific fracture work by 42 %, relative deformation by 68 %.
刚性和柔性基体在冲击和静载荷条件下对高分子复合材料极限强度和断裂机制的影响
针对基于多丝纳米晶超高分子量聚乙烯(UHMWPE)纤维的高分子复合材料的极限强度性能,提出了一种通用的“冲击与静态断裂”(RUS)方法,该方法不同于将样品固定在测试机上的方法。该方法是使用均匀的bis样品进行的,两端有中间矩阵和设备,用于连接到测试机器的平台。样品是由纤维和基体组成的圆形复合棒,通过附加的基体在不同的加载速率下固定在工具中。采用RUS方法研究了非平衡低温等离子体活化碳、芳纶和超高分子量聚乙烯纤维混杂纤维增强柔性和刚性基体的各向异性聚合物和混杂复合材料(PCM和HCM)的性能和静态冲击破坏机理。测定了低速冲击和静态弯曲条件下的断裂载荷、相对变形、断裂吸收能、粘着功、抗剪强度等性能。研究发现,基体的塑性和混杂纤维的组成对PCM和HCM的性能和断裂方式都有影响。对于具有柔性基体的HCM在冲击时的破坏,所需的载荷是具有刚性基体的复合材料的两倍。hcm具有最高的强度,在加载直至破坏的各个阶段,基体和增强纤维都会发生联合变形。各向异性HCM在冲击作用下的变形和破坏机制是阶梯的,而变形曲线的性质是锯齿形的。在静力学中,变形是平稳进行的。在杂化过程中,通过改变碳和超高分子量聚乙烯纤维的比例,可以控制超高分子量聚乙烯的性能,提高其性能。碳和超高分子量聚乙烯纤维在混合纤维中的结合,用于增强柔性基体,使制造具有延迟断裂的材料成为可能。结果表明,以20% %碳和80% % UHMWPE纤维混合纤维增强柔性基体的HCM,其断裂载荷增加了2倍,断裂功增加了42 %,相对变形增加了68 %。
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