Evaluation of graphene-ferrocene nanocomposite as multifunctional combustion catalyst in AP-HTPB propellant

[Display omitted] •A novel graphene-ferrocene nanocomposite G-792-Fe was designed and fabricated successfully.•Anchoring on graphene surface can effectively inhibited the migration and volatilization of ferrocene compounds.•The AP-HTPB propellant with excellent combustion, anti-migration, safety and...

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Bibliographic Details
Published in:Fuel (Guildford) 2021-10, Vol.302, p.121229, Article 121229
Main Authors: Zhang, Ming, Zhao, Fengqi, Wang, Ying, Chen, Xueli, Pei, Qing, Xu, Huixiang, Hao, Haixia, Yang, Yanjing, Li, Hui
Format: Article
Language:English
Subjects:
Ammonium
Ammonium perchlorates
Burning
Burning rate
Catalysts
Combustion
Combustion mechanism
Functional material
Graphene
HTPB propellants
Iron
Mechanical properties
Nanocomposite
Nanocomposites
Perchlorate
Perchloric acid
Polybutadiene
Propellant combustion
Redox reactions
Safety
Solid propellant
Tensile strength
Volatilization
X ray photoelectron spectroscopy
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Summary:[Display omitted] •A novel graphene-ferrocene nanocomposite G-792-Fe was designed and fabricated successfully.•Anchoring on graphene surface can effectively inhibited the migration and volatilization of ferrocene compounds.•The AP-HTPB propellant with excellent combustion, anti-migration, safety and mechanical performances was obtained.•The performance and mechanism of G-792-Fe in AP-HTPB propellant were analyzed. A novel graphene-ferrocene nanocomposite (G-792-Fe) was designed, prepared and characterized systemically using SEM, EDS, FTIR, XPS and RAMAN methods. The as-synthesized G-792-Fe was used as a multifunctional combustion catalyst in ammonium perchlorate-hydroxyl terminated polybutadiene (AP-HTPB) propellant, and the combustion, anti-migration, safety and mechanical performances of AP-HTPB propellant were revealed. The results showed that anchoring on the surface of graphene can effectively inhibit the migration and volatilization of ferrocene compounds in AP-HTPB propellant. The excellent combustion catalytic performance of G-792-Fe on AP-HTPB propellant (burning rate of AP-HTPB propellant containing G-792-Fe increases from 13.87 mm·s−1 to 17.28 mm·s−1 at 15 MPa) is attributed to its positive effect on AP decomposition, which generates more gas-phase products beneficial to the combustion surface thermal feedback and the gaseous REDOX reaction. Additionally, the G-792-Fe presents positive effects on reducing the electrostatic sensitivity and improving the mechanical properties of AP-HTPB propellant. The ignition energy (E50) and the maximum tensile strength (σm) of AP-HTPB propellant containing G-792-Fe were increased by 24.4 mJ and 0.75 MPa respectively, compared with AP-HTPB propellant containing catocene (156.8 mJ and 1.26 MPa). The positive effects of G-792-Fe on safety and mechanical performances of AP-HTPB propellant can be due the outstanding electrical and mechanical properties of graphene-based material. Results of this study have implications concerning design and application of multifunctional combustion catalyst, which can improve the combustion performance, anti-migration performance, safety performance and mechanical properties of AP-HTPB propellant.
ISSN:0016-2361
1873-7153
DOI:10.1016/j.fuel.2021.121229