AI Chat Paper

Note: Please note that the following content is generated by AMiner AI. SciOpen does not take any responsibility related to this content.

Chat more with AI

| Sign up

Browse by Subject

Search for peer-reviewed journals with full access.

Journals A - Z

About Us

Discover the SciOpen Platform and Achieve Your Research Goals with Ease.

About Us

Publish with Us

Support

Journals A - Z

About Us

Publish with Us

Support

Article Link

Cite

EndNote(RIS) BibTeX

Collect

Show Outline

Outline

Show full outline

Hide outline

Outline

Show full outline

Hide outline

Full Length Article | Open Access

Laser ablation mechanism and performance of glass fiber-reinforced phenolic composites: An experimental study and dual-scale modelling

Ran BI^{^a^,^b^,}, Pengfei SHEN^{^c}, Longyu ZHU^{^a^,^b}, Zhengzheng MA^{^c}, Chuyang LUO^{^a^,^b}(

), Yongfeng LI^{^a}, Lijian PAN^{^a}

Shanghai Key Laboratory of Lightweight Composite, Donghua University, Shanghai 201620, China

Shanghai High Performance Fibers and Composites Center (Province-Ministry Joint), Center for Civil Aviation Composites, Donghua University, Shanghai 201620, China

AVIC Composite Corporation Ltd, Beijing 101300, China

Peer review under responsibility of Editorial Committee of CJA.

Show Author Information

Abstract

Both experimental and simulation approaches were employed to investigate the laser ablation mechanism and performances of Glass Fiber Reinforced Phenolic Composites (GFRP). During the ablation process, the difference in thermal conductivities of the glass fibers and the resin matrix as well as their discrepant physical and chemical reactions form a conical ablation morphology. The formation of a residual carbon layer effectively mitigates the ablation rate in the thickness direction. A higher power density results in a faster ablation rate, while a longer irradiation time leads to a larger ablation pit diameter. To account for the variation in thermal conductivity between the fiber and resin, a macro-mesoscale model was developed to differentiate the matrix from the fiber components. Finite element analysis revealed that laser irradiation leads to phenolic decomposition, glass fiber melting vaporization, and residual carbon skeleton evaporation. The dual-scale model exhibits precise prediction capabilities concerning the laser ablation process of GFRP, and its accuracy is confirmed through the comparison of simulation and experimental results for the GFRP laser ablation process. This model provides a feasible method for performance evaluation and lifetime prediction of GFRP subjected to continuous wave laser irradiation.

Keywords

Finite element method Microstructural analysis Polymer-matrix composites Ablation mechanism Continuous-wave laser

References

Zachariah SA, Dayananda Pai K, Satish SB. Multi-level hybridization in mitigating impact damages in advanced composites–A review on recent trends. Mater Today Proc 2021;46:9059–66.

Crossref Google Scholar

Li D, Wu TF, Ji Y, et al. Model analysis and resonance suppression of wide-bandwidth inertial reference system. Nanotechnol Precis Eng 2019;2(4):177–87.

Crossref Google Scholar

Zhang HF, Cheng ZE, Long ML, et al. Applications of satellite laser ranging and laser time transfer in BeiDou navigation satellite system. Optik 2019;188:251–62.

Crossref Google Scholar

Zhang YX, Zhu Z, Joseph R, et al. Damage to aircraft composite structures caused by directed energy system: A literature review. Def Technol 2021;17(4):1269–88.

Crossref Google Scholar

Ferrante L, Tirillò J, Sarasini F, et al. Behaviour of woven hybrid basalt-carbon/epoxy composites subjected to laser shock wave testing: Preliminary results. Compos Part B Eng 2015;78:162–73.

Crossref Google Scholar

Affan Ahmed S, Mohsin M, Zubair Ali SM. Survey and technological analysis of laser and its defense applications. Def Technol 2021;17(2):583–92.

Crossref Google Scholar

Allheily V, Lacroix F, Eichhorn A, et al. An experimental method to assess the thermo-mechanical damage of CFRP subjected to a highly energetic 1.07μm-wavelength laser irradiation. Compos Part B Eng 2016;92:326–31.

Crossref Google Scholar

Lu MY, Zhang M, Zhang KH, et al. Femtosecond UV laser ablation characteristics of polymers used as the matrix of astronautic composite material. Materials 2022;15(19):6771.

Crossref Google Scholar

Xu F, Zhu SZ, Ma Z, et al. Ablation behavior of inorganic particle-filled polybenzoxazine composite coating irradiated by high-intensity continuous laser. Ceram Int 2019;45(12):14968–75.

Crossref Google Scholar

Ma C, Ma Z, Gao LH, et al. Laser ablation behavior of nano-copper particle-filled phenolic matrix nanocomposite coatings. Compos Part B Eng 2018;155:62–8.

Crossref Google Scholar

Kaludjerović BV, Srećković M, Janićijević M, et al. Influence of Nd³⁺:YAG laser irradiation on the properties of composites with carbon fibers. Compos Part B Eng 2017;125:165–74.

Crossref Google Scholar

Zhang YQ, Zhang L, Tan FL, et al. Effect of laser irradiation on morphology and dielectric properties of quartz fiber reinforced epoxy resin composite. E-Polymers 2021;21(1):734–41.

Crossref Google Scholar

Wang AA, Zhu JJ, Ma C, et al. Organic-inorganic composites for novel optical transformation induced by high-energy laser ablation. Ceram Int 2022;48(1):508–13.

Crossref Google Scholar

Ma C, Ma Z, Gao LH, et al. Ablation behavior of glass fiber reinforced polybenzoxazine composites irradiated by high energy continuous-wave laser. Mater Res Express 2019;6(8):085315.

Crossref Google Scholar

Ma C, Ma Z, Gao LH, et al. Zirconium carbide-modified polymer-matrix composites with improved reflectivity under high-energy laser ablation. Ceram Int 2019;45(14):17681–7.

Crossref Google Scholar

Sihn S, Pitz J, Gerzeski RH, et al. Experimentally-validated computational model for temperature evolution within laser heated fiber-reinforced polymer matrix composites. Compos Struct 2019;207:966–73.

Crossref Google Scholar

Liu YC, Wu CW, Huang YH, et al. Interlaminar damage of carbon fiber reinforced polymer composite laminate under continuous wave laser irradiation. Opt Lasers Eng 2017;88:91–101.

Crossref Google Scholar

Liu WL, Chang XL, Zhang XJ, et al. Progressive damage analysis of carbon/epoxy laminates under couple laser and mechanical loading. Results Phys 2017;7:995–1005.

Crossref Google Scholar

Canel T, Bağlan İ, Sınmazçelik T. Mathematical modeling of heat distribution on carbon fiber poly(ether-ether-ketone) (PEEK) composite during laser ablation. Opt Laser Technol 2020;127:106190.

Crossref Google Scholar

Wang ZJ, Kwon DJ, Gu GY, et al. Ablative and mechanical evaluation of CNT/phenolic composites by thermal and microstructural analyses. Compos Part B Eng 2014;60:597–602.

Crossref Google Scholar

Bahramian AR, Kokabi M, Famili MHN, et al. Ablation and thermal degradation behaviour of a composite based on resol type phenolic resin: Process modeling and experimental. Polymer 2006;47(10):3661–73.

Crossref Google Scholar

Bahramian AR, Kokabi M, Famili MHN, et al. High temperature ablation of kaolinite layered silicate/phenolic resin/asbestos cloth nanocomposite. J Hazard Mater 2008;150(1):136–45.

Crossref Google Scholar

Loomis M, Prabhu D, Gorbunov S, et al. Results & analysis of large scale article testing in the AMES 60 MW interaction heating arc jet facility. Proceedings of the 48th AIAA aerospace sciences meeting including the new horizons forum and aerospace exposition. Reston: AIAA; 2010. No. AIAA2010-445.

Crossref

Zhang JD, Bi R, Jiang SD, et al. Laser ablation mechanism and performance of carbon fiber-reinforced poly aryl ether ketone (PAEK) composites. Polymers 2022;14(13):2676.

Crossref Google Scholar

Xu F, Zhu SZ, Ma Z, et al. Effect of TaSi₂/ZrSi₂ on ablation properties of carbon-phenolic composite irradiated by high-intensity continuous laser. Ceram Int 2020;46(18):28443–50.

Crossref Google Scholar

Shi SB, Li LJ, Liang J, et al. Surface and volumetric ablation behaviors of SiFRP composites at high heating rates for thermal protection applications. Int J Heat Mass Transf 2016;102:1190–8.

Crossref Google Scholar

Xu WJ, Song WD, Jia XF, et al. Nano-silica modified lightweight and high-toughness carbon fiber/phenolic ablator with excellent thermal insulation and ablation performance. Def Technol 2024;31:192–9.

Crossref Google Scholar

Wu CY, Liu WN, Li M, et al. Phenolic resin plate precision cutting by ultraviolet nanosecond laser ablation regulation. Optik 2021;243:167481.

Crossref Google Scholar

Xu WY, Gao LH, Ma C, et al. Design and preparation of composite coatings with increased reflectivity under high-energy continuous wave laser ablation. Ceram Int 2020;46(15):23457–62.

Crossref Google Scholar

Zhang JP, Xin YP, Wang RN, et al. Ablation behaviour of C/C-HfC-SiC composites prepared by joint route of precursor infiltration and pyrolysis and gaseous silicon infiltration. Chin J Aeronaut 2023;36(9):426–36.

Crossref Google Scholar

Liu XS, Fu QG, Wang H, et al. Microstructure, thermophysical property and ablation behavior of high thermal conductivity carbon/carbon composites after heat-treatment. Chin J Aeronaut 2020;33(5):1541–8.

Crossref Google Scholar

Shen PF, Zhuang YP, Jiang SD, et al. Experimental and numerical investigation on the ablation mechanism of Al₂O₃/Al₂O₃-CMCs under continuous-wave laser irradiation. J Eur Ceram Soc 2022;42(5):2307–18.

Crossref Google Scholar

Charles JA, Wilson DW. A model of passive thermal nondestructive evaluation of composite laminates. Polym Compos 1981;2(3):105–11.

Crossref Google Scholar

Thai CH, Ferreira AJM, Tran TD, et al. A size-dependent quasi-3D isogeometric model for functionally graded graphene platelet-reinforced composite microplates based on the modified couple stress theory. Compos Struct 2020;234:111695.

Crossref Google Scholar

Yu B, Till V, Thomas K. Modeling of thermo-physical properties for FRP composites under elevated and high temperature. Compos Sci Technol 2007;67(15–16):3098–109.

Crossref Google Scholar

Li WJ, Liang HR, Zhang ZW, et al. Analysis of influence of fabric architecture and radiation characteristics on effective thermal conductivity of carbonized woven thermal protection composites. Acta Astronaut 2021;188:387–99.

Crossref Google Scholar

Galgano A, Di Blasi C, Branca C, et al. Thermal response to fire of a fibre-reinforced sandwich panel: Model formulation, selection of intrinsic properties and experimental validation. Polym Degrad Stab 2009;94(8):1267–80.

Crossref Google Scholar

Grange N, Chetehouna K, Gascoin N, et al. One-dimensional pyrolysis of carbon based composite materials using FireFOAM. Fire Saf J 2018;97:66–75.

Crossref Google Scholar

Zheng FJ, Ren ZY, Xu B, et al. Elucidating multiple-scale reaction behaviors of phenolic resin pyrolysis via TG-FTIR and ReaxFF molecular dynamics simulations. J Anal Appl Pyrolysis 2021;157:105222.

Crossref Google Scholar

Kim M, Choe J, Lee DG. Development of the fire retardant glass fabric/carbonized phenolic composite. Compos Struct 2016;148:191–7.

Crossref Google Scholar

Hasan MZ. Thermal response and surface recession of a carbon-phenolic charring heatshield of spacecraft: Numerical simulation and validation. J Space Saf Eng 2022;9(3):298–318.

Crossref Google Scholar

Helber B, Turchi A, Scoggins JB, et al. Experimental investigation of ablation and pyrolysis processes of carbon-phenolic ablators in atmospheric entry plasmas. Int J Heat Mass Transf 2016;100:810–24.

Crossref Google Scholar

Zou CR, Li B, Meng XJ, et al. Ablation behavior and mechanism of SiO_2f/SiO₂, SiO_2f/BN and Si₃N_4f/BN radar wave transparent composites. Corros Sci 2018;139:243–54.

Crossref Google Scholar

Dong L, Correia JPM, Barth N, et al. Finite element simulations of temperature distribution and of densification of a titanium powder during metal laser sintering. Addit Manuf 2017;13:37–48.

Crossref Google Scholar

Gao JX, Cao YZ, Lu LH, et al. Study on the interaction between nanosecond laser and 6061 aluminum alloy considering temperature dependence. J Alloys Compd 2022;892:162044.

Crossref Google Scholar

Wen Z, Jiang S, Luo C, et al. Assessment of ablation damage on quartz ceramics through experiment and 3D modelling considering a dynamic heat source. Ceram Int 2022;48(3):3515–26.

Crossref Google Scholar

Liu YC, He YR, Tian FL, et al. Thermal shock damage behavior of CVD ZnS by oxygen propane flame: a numerical and experimental study. Chin J Aeronaut 2014;27(2):266–71.

Crossref Google Scholar

Chinese Journal of Aeronautics

Volume 37 Issue 8,
August 2024

Pages 470-485

DOI: 10.1016/j.cja.2024.05.042

Cite this article:

BI R, SHEN P, ZHU L, et al. Laser ablation mechanism and performance of glass fiber-reinforced phenolic composites: An experimental study and dual-scale modelling. Chinese Journal of Aeronautics, 2024, 37(8): 470-485. https://doi.org/10.1016/j.cja.2024.05.042

Views

Crossref

Web of Science

Scopus

Google Scholar
Citation

Altmetrics

Received: 22 August 2023

Revised: 15 September 2023

Accepted: 11 March 2024

Published: 03 June 2024

This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/).