Abstract:Aluminum/polytetrafluoroethylene (Al/PTFE) composites are a promising category of reactive structural materials. In order to improve the mechanical properties and reactivity, Fe particles were introduced into Al/PTFE. Quasi-static and dynamic compression tests for Al/PTFE/Fe reactive materials were conducted, and significant strain and strain rate hardening phenomena were observed. The compression strength of Al/PTFE with Fe content of 30 wt.% reached 191.8 MPa at the strain rate of 5000 s^-1, increased by 39% compared to Al/PTFE. The oriented PTFE nano-fibers could effectively prevent the propagation of micro-cracks. The impact reaction processes under SHPB and drop-weight conditions were observed by high-speed photography technology, and the reactivity was qualitatively characterized by a newly-designed device. Based on the results of TG-DSC and XRD analyses, the reaction involving Al/PTFE and Al/Fe was clarified. The Johnson-Cook constitutive model was established and the model results agreed well with experimental data. Under impact loading, the reactivity was speculated to be the result of multiple actions.

Key words: reactive materials; Al/PTFE/Fe; mechanical behavior; energy release characteristics; impact initiation mechanism