Interface Strengthening Mechanism of Short Fiber Bridging for Metal⁃Matrix Polymeric Composites

doi:10.19491/j.issn.1001-9278.2021.03.009

Abstract

Abstract:

Aiming at the common problem that the metal-matrix polymeric composites are easy to induce interface peeling damage and failure， this paper focused on the composite interface strengthening through a short fiber bridge formed at the interface between the polymeric composite layer and adhesive layer by means of the multi-layer composite assembly injection molding. On the basis of a cohesive peeling damage model， a simulation technology was constructed for the failure process of interfacial peeling crack propagation and the fracture failure of the composites with short fiber bridging. A synergetic relevance theory based on the failure critical load-bridging fiber properties-interface peeling fracture toughness （damage crack initiation stress T₀ and critical strain energy release rate G_c） was constructed for the interfacial peeling unstable crack rapid propagation fracture damage failure. The interface strengthening mechanism of short fiber bridging was explored， with the design criterion proposed for preventing the peeling unstable crack rapid propagation fracture damage failure induced by the short fiber bridge strengthening interface. The results indicated that the critical load was increased by 55.9 % with a density of bridging fiber at 20/mm². The critical load was controlled by the density of bridging fiber， initial pre-crack area， damage crack initiation stress and critical strain energy release rate. The critical load was positively correlated with the density of bridging fiber， damage crack initiation stress and critical strain energy release rate， but negatively correlated with the initial pre-crack area.

Key words: metal matrix, polymer, composite, fiber bridging, interface strengthening, delamination failure, preventive design criteria

CLC Number:

TQ320

JI Cao, ZHOU Guofa. Interface Strengthening Mechanism of Short Fiber Bridging for Metal⁃Matrix Polymeric Composites[J]. China Plastics, 2021, 35(3): 59-66.

Figures/Tables 18

Fig.1. Model of bilinear cohesion

Fig.2. Solid model

材料	弹性模量/GPa	泊松比
聚丙烯	4.2	0.4
环氧树脂胶	3.185	0.33
碳钢	210	0.3
碳纤维	294	0.18

Tab.1. Material parameters

损伤启裂应力/MPa			临界应变能释放率/J·m^-2
T_I0	T_II0	T_III0	G_IC	G_IIC	G_I_IIC
31.9	31.9	31.9	800	800	800

Tab.2. Fracture toughness parameters of polypropylene?epoxy structural adhesive interface

损伤启裂应力/MPa			临界应变能释放率/J·m^-2
T_I0	T_II0	T_III0	G_IC	G_IIC	G_IIIC
56	56	56	1050	1050	1050

Tab.3. Fracture toughness parameters of polypropylene ?carbon fiber interface

Fig.3. Displacement load vs. time

Fig.4. Evolution cloud diagram of the damage coefficient of the interface with or without short fiber bridge strengthening

Fig.5. Extending area ratio of crack vs. time

Fig.6. Crack growing load vs. time

Fig.7. Mises stress evolution at the crack tip

Fig.8. Critical load vs bridging fiber density

Fig.9. Critical failure load vs interface pre?crack area ratio

Fig.10. Critical load vs damage initiation stress

Fig.11. Critical failure load vs critical strain energy release rate

Fig.12. Collaborative coupling correlation curve of critical strain energy release rate and damage initiation stress

Fig.13. CSDMG cloud diagram of interface damage coefficient at point A

Fig.14. CSDMG cloud diagram of interface damage coefficient at point B

Fig.15. Crack area ratio vs time

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