Volume 4 Issue 2
Jan.  2024
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Meiyu LIU, Yueqing ZHAO, Yuncong FENG, Xiaobing LI, Weizhao ZHANG. Characterizing thermal conductivity of high-toughness resin and its carbon fiber reinforced composite under curing condition[J]. Journal of Advanced Manufacturing Science and Technology , 2024, 4(2): 2024006. doi: 10.51393/j.jamst.2024006
Citation: Meiyu LIU, Yueqing ZHAO, Yuncong FENG, Xiaobing LI, Weizhao ZHANG. Characterizing thermal conductivity of high-toughness resin and its carbon fiber reinforced composite under curing condition[J]. Journal of Advanced Manufacturing Science and Technology , 2024, 4(2): 2024006. doi: 10.51393/j.jamst.2024006

Characterizing thermal conductivity of high-toughness resin and its carbon fiber reinforced composite under curing condition

doi: 10.51393/j.jamst.2024006
Funds:

The work described in this paper was supported by grant from the Innovation Fund of the National Commercial Aircraft Manufacturing Engineering Technology Research Center, China (No. COMACSFGS-2022-2387).

  • Received Date: 2023-12-05
  • Accepted Date: 2023-12-20
  • Rev Recd Date: 2023-12-15
  • Available Online: 2023-12-25
  • Publish Date: 2024-01-02
  • In the present study, heat conductivity of an aircraft-grade BA9916 resin with high-toughness was characterized under the curing condition, so as to support curing modeling for this resin and its carbon fiber composites and avoid timeand labor-consuming experiments for manufacturing process design. Thermal-related properties, including density, curing kinetics, glass transition temperature, specific capacity and thermal diffusivity were measured to obtain thermal conductivity of the material. However, the BA9916 resin was toughened via addition of thermoplastic particles, resulting in much higher viscosity before completely cured than that of common epoxy resins. As a result, it was challenging to directly measure certain thermal properties of the neat resin. To settle this problem, the BA3202 unidirectional carbon fiber composite prepreg with the BA9916 resin was employed as a media to obtain corresponding properties of the resin through experiments and analytical calculation. Derived material properties of the resin were then input to the user-defined material subroutine UMAT to predict thermal response of the composite under various curing conditions, with the maximum error of 6.82% validated via experiments. Hence, the acquired characteristics can be utilized for numerical analysis of various composites composed of BA9916 resin, obviating the need for repeated physical experiments that are time- and resource-consuming.

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  • [1]
    . Zou JC, Xiong YF, Tang CR, et al., Blank geometry design for preforming of woven composites based on numerical modeling. Journal of Advanced Manufacturing Science and Technology 2023; 4(1): 2023020.
    [2]
    . Xu PJ, Zhu Z, Wang YD, et al. Phase structure characterization and compatibilization mechanism of epoxy asphalt modified by thermoplastic elastomer (SBS). Construction and Building Materials 2022; 320: 126262.
    [3]
    . Fadlurrahman Z, Alandro D, Santos GNC. Mechanical and chemical properties of matrix composite: curing agent ratio, degassing process, and filler effect perspectives. Journal of Engineering Research 2023:100120(in press).
    [4]
    . Feng YC, Zheng WK, Zhao ZZ, et al. Characterization and finite element modeling for thermoset resin of carbon fiber prepregs during curing. Journal of Manufacturing Science and Engineering 2022; 144(8): 081007.
    [5]
    . Wang WZ, Zhao WQ, Zhang JJ, et al. Epoxy-based grouting materials with super-low viscosities and improved toughness. Construction and Building Materials 2021; 267: 121104.
    [6]
    . Ferrer G, Barreneche C, Sole A, et al. New proposed methodology for specific heat capacity determination of materials for thermal energy storage (TES) by DSC. Journal of Energy Storage 2017; 11: 1-6.
    [7]
    . McHugh J, Fideu P, Herrmann A, et al. Determination and review of specific heat capacity measurements during isothermal cure of an epoxy using TM-DSC and standard DSC techniques. Polymer Testing 2010; 29(6): 759-765.
    [8]
    . Kerschbaumer RC, Stieger S, Gschwandl M, et al. Comparison of steady-state and transient thermal conductivity testing methods using different industrial rubber compounds. Polymer Testing 2019; 80: 106121.
    [9]
    . Yu ZP, Feng DL, Feng YH, et al. Thermal conductivity and energy storage capacity enhancement and bottleneck of shape-stabilized phase change composites with graphene foam and carbon nanotubes. Composites Part A: Applied Science and Manufacturing 2022; 152: 106703.
    [10]
    . ASTM D792-20. Standard test methods for density and specific gravity (relative density) of plastics by displacement. West Conshohocken, PA: ASTM International. 2020.
    [11]
    . Yuksel O, Sandberg M, Baran I, et al. Material characterization of a pultrusion specific and highly reactive polyurethane resin system: Elastic modulus, rheology, and reaction kinetics. Composites Part B: Engineering 2021; 207: 108543.
    [12]
    . ASTM E1269-11. Standard test method for determining specific heat capacity by differential scanning calorimetry. West Conshohocken, PA: ASTM International. 2018.
    [13]
    . ASTM E1461-13. Standard test method for thermal diffusivity by the flash method. West Conshohocken, PA: ASTM International. 2013.
    [14]
    . Fan M, Naughton A, Bregulla J. Fire performance of natural fibre composites in construction. Advanced high strength natural fibre composites in construction. 2017. p. 375-404.
    [15]
    . Melro AR, Camanho PP, Pinho ST. Generation of random distribution of fibres in long-fibre reinforced composites. Composites Science and Technology 2008; 68(9): 2092-2102.
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