Crack Propagation for Glass Fiber Reinforced Laminates Containing Flame Retardant: Based on Single-Edge Tensile Loading

IF 0.6 4区 材料科学 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY
Zhao Changfang, Ren Rui, Wei Yi, Yang Guang, He Bin, Zhang Kebin, Zhong Jianlin
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引用次数: 2

Abstract

Research on crack propagation for fiber reinforced composites containing flame retardant is rare. The micro-cracks propagation is a reason for delamination and debonding failure of fiber reinforced composites. To study the crack propagation of continuous glass fiber reinforced epoxy resin laminates that contained ammonium polyphosphate flame retardant (GFRP-APP), the quasi-static single-edge tensile loading (SETL) experiments for the end-notched GFRP-APP specimens were carried out by MTS universal electronic testing machine. The crack propagation of the end-notched 90� GFRP-APP specimen includes two types, both of which belong to opening type (mode I). Namely, one type is mode I multi-cracks propagation without preexisting crack, and the other is mode I fiber bridge propagation with preexisting crack. The intralaminar fracture toughness along fiber direction of GFRP-APP is approximately 8.4 N/mm, which is calculated by area method. The opening displacement-tensile force curves can be divided into three stages for 90� GFRP-APP specimen without crack, i.e., crack gestation, crack birth and crack propagation. However, the 90� GFRP-APP specimen with crack not contains the crack birth stage. Additionally, the microscopic morphology for the fracture face of pure epoxy resin and GFRP-APP, and the phase analysis for GFRP-APP were performed by scanning electron microscope (SEM), X-ray diffraction (XRD) and energy dispersive spectrometer (EDS). As a conclusion, the pores and interfaces in materials were the guiding factors of micro-crack propagation, and the ammonium polyphosphate flame retardant particle contributed extra interfaces.
含阻燃剂玻璃纤维增强层压板的裂纹扩展:基于单边拉伸载荷
含阻燃剂的纤维增强复合材料的裂纹扩展研究很少。微裂纹的扩展是纤维增强复合材料分层和脱粘失效的原因之一。为了研究含有聚磷酸铵阻燃剂(GFRP-APP)的连续玻璃纤维增强环氧树脂层压板的裂纹扩展,在MTS通用电子试验机上对端部缺口GFRP-APP试件进行了准静态单边拉伸载荷(SETL)试验。端部缺口90的裂纹扩展� GFRP-APP试件包括两种类型,均属于开口型(I型)。也就是说,一种类型是没有预先存在的裂纹的I型多裂纹传播,另一种是有预先存在的裂缝的I型纤维桥传播。用面积法计算出GFRP-APP沿纤维方向的层内断裂韧性约为8.4N/mm。对于90°,开启位移-拉力曲线可分为三个阶段� 无裂纹的GFRP-APP试样,即裂纹孕育、裂纹萌生和裂纹扩展。然而,90� 有裂纹的GFRP-APP试件不包含裂纹萌生阶段。此外,通过扫描电子显微镜(SEM)、X射线衍射仪(XRD)和能谱仪(EDS)对纯环氧树脂和GFRP-APP的断口进行了微观形貌分析,并对GFRP-APP进行了相分析。因此,材料中的孔隙和界面是微裂纹扩展的主导因素,聚磷酸铵阻燃剂颗粒贡献了额外的界面。
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来源期刊
Materiale Plastice
Materiale Plastice MATERIALS SCIENCE, MULTIDISCIPLINARY-
CiteScore
1.40
自引率
25.00%
发文量
99
审稿时长
6-12 weeks
期刊介绍: Materiale Plastice, abbreviated as Mater. Plast., publishes original scientific papers or guest reviews on topics of great interest. The Journal does not publish memos, technical reports or non-original papers (that are a compiling of literature data) or papers that have been already published in other national or foreign Journal.
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