A new fluorocarbon adhesive: Inhibiting agglomeration during combustion of propellant via efficient F&#8211;Al<sub>2</sub>O<sub>3</sub> preignition reaction

Qifa Yao; Min Xia; Chao Wang; Fanzhi Yang; Wei Yang; Yunjun Luo

doi:10.1002/cey2.467

Carbon Energy ›› 2024, Vol. 6 ›› Issue (6) : 467. DOI: 10.1002/cey2.467

RESEARCH ARTICLE

A new fluorocarbon adhesive: Inhibiting agglomeration during combustion of propellant via efficient F–Al₂O₃ preignition reaction

Qifa Yao¹ ,
Min Xia¹^,² ,
Chao Wang³ ,
Fanzhi Yang⁴ ,
Wei Yang¹ ,
Yunjun Luo¹^,²

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Abstract

Inhibiting the agglomeration of molten aluminum particles packed in the binder network is a promising scheme to achieve efficient combustion of solid propellants. In this investigation, the hydroxyl-terminated structured fluorinated alcohol compound (PFD) was introduced to modify the traditional polyethylene glycol/polytetrahydrofuran block copolymerization (HTPE) binder; that is, a unique fluorinated polyether (FTPE) binder was synthesized by embedding fluorinated organic segments into the HTPE binder via crosslinking curing. The FTPE was applied in aluminum-based propellants for the first time. Due to the complete release of fluorinated organic active segments in the range of 300℃ to 400℃, the burning rate of FTPE-based propellant increased from 4.07 (0% PFD) to 6.36 mm/s (5% PFD), increased by 56.27% under 1 MPa. The reaction heat of FTPE propellants increased from 5.95 (0% PFD) to 7.18 MJ/kg (5% PFD) under 3.0 MPa, indicating that HTPE binder modified with PFD would be conducive to inhibiting the D₉₀ of condensed combustion products (CCPs) dropped by 81.84% from 75.46 (0% PFD) to 13.71 μm (5% PFD) under 3.0 MPa, in consistent with the significant reduction of aluminum agglomerates observed on the quenched burning surface of the propellants. Those results demonstrated that a novel FTPE binder with PFD can release fluorinated organic active segments, which motivate preignition reaction with the alumina shell in the early stage of aluminum combustion, and then enhance the melting diffusion effect of aluminum to inhibit the agglomeration.

Keywords

agglomeration characteristics / aluminum particles / combustion / fluorine alcohol compounds / HTPE propellants

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Qifa Yao, Min Xia, Chao Wang, Fanzhi Yang, Wei Yang, Yunjun Luo. A new fluorocarbon adhesive: Inhibiting agglomeration during combustion of propellant via efficient F–Al₂O₃ preignition reaction. Carbon Energy, 2024, 6(6): 467 https://doi.org/10.1002/cey2.467

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