1. Mechanical properties and thermal characteristics of three nano-filler/silk fiber reinforced hybrid composites: A comparative study using a ductile epoxy resin matrix.
- Author
-
Zheng, Jian, Liu, Yulong, Wang, Qingzhu, Cheng, Lan, Zhang, Chunhua, Zhang, Tonghua, Shao, Jiaxing, and Dai, Fangyin
- Subjects
- *
FIBROUS composites , *EPOXY resins , *THERMAL properties , *HYBRID materials , *YOUNG'S modulus , *SILICA nanoparticles - Abstract
In contemporary developments across automotive, aerospace, and military industries, there is an ever-growing demand for lightweight and robust polymer composites. In this study, a ductile epoxy resin, carbon nanotubes (CNTs), cellulose nanofibers (CNFs), and silica nanoparticles were used to fabricate nano-fillers/epoxy composites and nano-fillers/silk fibers/epoxy hybrid composites through solution casting and hot pressing. Their mechanical properties and thermal characteristics were analyzed and compared, which show that: these nano-fillers can dramatically enhance the strength and stiffness of the ductile epoxy resin; however, this is achieved at the expense of its toughness and extensibility. CNT/silk fiber/epoxy hybrid composite has the highest tensile strength (81.10 MPa), Young's modulus (3.76 GPa) and impact strength (103.7 kJ/m2), while the CNFs-reinforced one exhibits the highest breaking energy (9.96 MJ/m3). These nano-fillers almost do not affect the thermal stability of the epoxy resin and silk fiber composites. In addition, the fracture modes of their reinforced composites were revealed by macroscopic and microscopic observations. • Reveal how different nano-fillers affect the mechanical behaviors of ductile polymer matrix. • Explore the optimal content of these nano-fillers in the polymer matrix. • Indicate nano-fillers do not affect the thermal stability of their reinforced composites. • Elucidate the composites' fracture modes introduced by silk fibers and different nano-fillers. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF