Research on the thermal conductivity and mechanical properties of carbon fiber reinforced thermoplastic composites doped with different sizes carbon nanotubes: A combination of experiments, numerical simulations and multi‐objective optimization

While improving the thermal conductivity of composites, single‐size carbon nanotubes (CNT) often degrade their mechanical properties due to the agglomerates. To overcome this limitation, this study reported thermoplastic resin matrix composites synergistically reinforced with small, medium, and larg...

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Bibliographic Details
Published in:Polymer composites 2024-08, Vol.45 (12), p.11252-11265
Main Authors: Wang, Bing, Li, Nan, Liu, Zehao, Bao, Qingguang, Cheng, Shan, Feng, Jingyao, Wang, Ning, Li, Mengting, Wang, Zaiyu, Jiang, Binlin, Chen, Lei, Hong, Houquan, Jian, Xigao
Format: Article
Language:English
Subjects:
Carbon
Carbon fiber reinforced plastics
Carbon nanotubes
composites
Compressive strength
Design optimization
Fiber composites
Fiber reinforced polymers
fibers
Flexural strength
Heat conductivity
Heat transfer
Mechanical properties
Polynomials
Resin matrix composites
Tensile strength
Thermal conductivity
thermal properties
Thermoplastic resins
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Summary:While improving the thermal conductivity of composites, single‐size carbon nanotubes (CNT) often degrade their mechanical properties due to the agglomerates. To overcome this limitation, this study reported thermoplastic resin matrix composites synergistically reinforced with small, medium, and large‐size carbon nanotubes (S‐CNT, M‐CNT, and L‐CNT). Using the thermal conductivity (λ) and mechanical properties (flexural strength [F], compressive strength [C] and tensile strength [T]) as the response values, we conducted 21 sets of mixing design experiments and developed the associated quadratic term models. Further multi‐objective optimization was carried out for the above response values. Optimized multiscale CNT synergistically modified composites (S‐CNT, M‐CNT, and L‐CNT contents of 1.25, 7.02, and 2.56 wt%) exhibited a λ value of 1.168 W/mK, which was 121% higher than that of pure composite and also superior to the same content of S‐CNT‐ (1.031 W/mK), M‐CNT‐ (1.016 W/mK), and L‐CNT‐modified composites (0.983 W/mK). Additionally, the optimized composite demonstrated excellent mechanical properties (F = 1482 MPa, C = 848 MPa, and T = 1759 MPa), which were 13%, 11%, and 13% higher than those of the pure composites, respectively, and also surpassed those of the S‐CNT‐, M‐CNT‐and L‐CNT‐modified composites. Highlights Using three different scales of carbon nanotubes modified CF/PPBESK composites. Polynomial modeling of composite's thermal conductivity and mechanical properties. Synergistic interactions between carbon nanotubes to improve the composite's thermal conductivity and mechanical properties. A method to enhance the thermal conductivity‐mechanical properties of CF/PPBESK composites.
ISSN:0272-8397
1548-0569
DOI:10.1002/pc.28563