Abstract
Hybrid fiber reinforced thermoplastic composites are receiving important attention in lightweight applications. The fabrication process of hybrid thermoplastic composites is that discontinuous fiber reinforced thermoplastics are injected onto the continuous fiber reinforced thermoplastics by over-molding techniques. The key issue during this process is to get a reliable interfacial bonding strength. To understand the bonding mechanism at the heterogeneous interface of hybrid thermoplastic composites which is difficult to obtain through experimental investigations, a series of molecular dynamic (MD) simulations were conducted in this paper. The influence of processing parameters on the interfacial characteristics, i.e., the distribution of interfacial high-density enrichment areas, radius of gyration, diffusion coefficient and interfacial energy, were investigated during the forming process of a heterogeneous interface. Simulation results reveal that some of molecule chains get across the interface and tangle with the molecules from the other layer, resulting in the penetration phenomenon near the interface zone. In addition, the melting temperature and injection pressure exhibit positive effects on the interfacial properties of hybrid composites. To further investigate the interfacial bonding strength and fracture mechanism of the heterogeneous interface, the uniaxial tensile and sliding simulations were performed. Results show that the non-bonded interaction energy plays a crucial role during the fracture process of heterogeneous interface. Meanwhile, the failure mode of the heterogeneous interface was demonstrated to evolve with the processing parameters.
Highlights
A thermoplastic composite over-molding (TCO) process involves the combination of stamping and injection molding techniques and enables the production of hybrid fiber reinforced thermoplastic composites structures in a single economic process stage of molding [1,2].The continuous fiber reinforced thermoplastic composites (CFRT) in the form of laminate is generally chosen as a base of hybrid composite structures [3,4]
The results show that the melting temperature has an obvious effect on the bonding strength
The intermolecular and nonnon-bonded interactions between atoms were described by the consistent valence force field (CVFF), bonded interactions between atoms to were described by the consistent valence field (CVFF), which has been gradually applied a variety of polypeptides, proteins and force a large number of which has been gradually applied to a variety of polypeptides, proteins and a large number of organic organic molecular systems and broadly applied to investigate the interfacial properties of polymer molecular systems and broadly investigate interfacial properties of polymer systems systems [11,12,28]
Summary
The continuous fiber reinforced thermoplastic composites (CFRT) in the form of laminate (so called organosheet) is generally chosen as a base of hybrid composite structures [3,4]. For the TCO process of hybrid composites, organosheet is firstly thermoformed and subsequently over-molded with pure thermoplastic or short fiber reinforced thermoplastic (SFRT) in an injection mold. As a load-carrying region, the interface bonding strength is assumed as a key property for hybrid composite parts because. The results show that the melting temperature has an obvious effect on the bonding strength. Tanaka et al [6] studied the effect of mold temperature on the bonding strength between the over-molded part and CFRT via
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