Your search keyword '"Bai, Hongwei"' showing total 4 results

1. Matrix crystallization induced simultaneous enhancement of electrical conductivity and mechanical performance in poly(l-lactide)/multiwalled carbon nanotubes (PLLA/MWCNTs) nanocomposites.

Author

Huang, Chunmei, Bai, Hongwei, Xiu, Hao, Zhang, Qin, and Fu, Qiang

Subjects

*CRYSTALLIZATION, *ELECTRIC conductivity, *LACTIDES, *MULTIWALLED carbon nanotubes, *MECHANICAL behavior of materials, *POLYMERIC composites

Abstract

In this work, influence of matrix crystallization on the electrical conductivity and mechanical properties of poly( l -lactide)/multiwalled carbon nanotubes (PLLA/MWCNTs) nanocomposites has been investigated. By introducing trace amount of nucleating agent (0.15 wt%) and controlling isothermal crystallization time (0.1–8 min) of PLLA matrix in a hot mould (130 °C), the injection molded bars of the nanocomposites with different matrix crystallinities (5–45%) were prepared. Interestingly, the electrical conductivity is found to be linearly increased with increasing matrix crystallinity for nanocomposites with low concentrations of MWCNTs (below the percolation threshold). This could be attributed to the volume exclusion effect and the straightening effect of MWCNTs provided by PLLA crystallization, as evidenced from SEM observations. However, matrix crystallization induced reconstruction of MWCNTs network cannot effectively enhance the electrical conductivity when the concentration of MWCNTs is high enough (above the percolation threshold). More interestingly, the reconstructed MWCNTs network shows a better reinforcement effect in the nanocomposites as compared with that initially formed in the amorphous matrix. [ABSTRACT FROM AUTHOR]

Published

2014

2. Impact toughness of polypropylene/glass fiber composites: Interplay between intrinsic toughening and extrinsic toughening.

Author

Yu, Bowen, Geng, Chengzhen, Zhou, Mi, Bai, Hongwei, Fu, Qiang, and He, Bobing

Subjects

*IMPACT loads, *FRACTURE toughness, *POLYPROPYLENE, *GLASS fibers, *COMPOSITE materials

Abstract

There are principally two mechanisms to improve the impact resistance of polymer-based composites, intrinsic toughening and extrinsic toughening. But the interplay between them is far from being well understood. Here, glass fiber was incorporated into polypropylene to promote extrinsic toughening mechanism, while addition of elastomer and annealing were adopted for intrinsic toughening. In this way, the interaction among glass fiber, elastomer and annealing could be discussed based on various characterizations, and their combined effect on mechanical properties of the composites could be determined. The results show that the intrinsic toughening mechanism of elastomer will be suppressed by glass fiber irrespective of the support of annealing, though annealing could work synergistically with glass fiber to toughen polypropylene. The possible structure-property relations are discussed. This work will provide deeper insight into the toughening behavior of polymer composites and practical guidance for the design of composites with excellent stiffness-toughness balance. [ABSTRACT FROM AUTHOR]

Published

2016

3. Combined effect of interfacial strength and fiber orientation on mechanical performance of short Kevlar fiber reinforced olefin block copolymer.

Author

Fu, Sirui, Yu, Bowen, Duan, Lingyan, Bai, Hongwei, Chen, Feng, Wang, Ke, Deng, Hua, Zhang, Qin, and Fu, Qiang

Subjects

*THERMOPLASTIC elastomers, *FIBER orientation, *TENSILE strength, *POLYPHENYLENETEREPHTHALAMIDE, *ALKENES, *BLOCK copolymers, *MECHANICAL behavior of materials

Abstract

As a novel thermoplastic elastomer, olefin block copolymers (OBCs) show a tremendous application potential in many areas. However, the practical use of OBCs is mainly restricted to the low load-bearing environments because of its poor low-strain mechanical strength and stiffness. In this work, short Kevlar fiber was introduced into OBC matrix to improve its mechanical properties. The results show that introduction of pristine Kevlar fiber only gives rise to a slight increase in tensile strength of OBC owing to the poor interfacial strength, regardless of the presence of compatibilizer maleic anhydride-grafted polypropylene (MA-g-PP). However, a largely enhanced tensile strength can be easily obtained when hydrolyzed or polydopamine-coated Kevlar fiber was incorporated into the OBC matrix using the MA-g-PP as the reactive compatibilizer. More importantly, the tensile strength can be further enhanced with the orientation of Kevlar fiber in the composites. As compared with compression molded composites with randomly orientated fibers, injection molded composites with highly oriented fibers exhibit a significantly higher tensile strength at the same composition. Moreover, it is interesting to observe that Kevlar fiber can be easily exfoliated into several microfibers during melt-mixing with OBC, but the exfoliation has no evident effect on the reinforcement effect possibly because of the poor interfacial strength between the newly-formed microfibers and the OBC matrix. Our work demonstrates that mechanical performance of short fiber reinforced elastomer composites could be significantly improved by enhancing interfacial strength and fiber orientation using a facile surface modification strategy and conventional melt-processing technology. [ABSTRACT FROM AUTHOR]

Published

2015

4. Largely improved toughness of polypropylene/long glass fiber composites by β-modification and annealing.

Author

Geng, Chengzhen, Su, Juanjuan, Zhou, Caiyi, Bai, Hongwei, Yang, Guanghui, and Fu, Qiang

Subjects

*POLYPROPYLENE fibers, *GLASS fibers, *COMPOSITE materials, *STRENGTH of materials, *ANNEALING of metals, *REINFORCED plastics

Abstract

Abstract: β-Modification and annealing were adopted to improve the impact strength of long glass fiber reinforced (LFPP) composites. It was found that either β-modification or annealing is an efficient way to toughen LFPP composites, and largely enhanced impact toughness can be achieved via simultaneously using β-modification and annealing, particularly for the toughness at low temperatures (−40°C to −20°C). Meanwhile, the tensile strength and Young’s modulus of the composites could be maintained. Various characterizations were used to understand the microstructure changes and toughening mechanism after β-modification and annealing. The results show that the higher extent of the matrix plastic deformation could be the main reason for the enhanced toughness as induced by β-modification and annealing. The possible structural origins for the higher extent of matrix plastic deformation are also discussed. [Copyright &y& Elsevier]

Published

2014