Abstract
In order to obtain the effect of porosity on the dynamic mechanical properties and impact response characteristics of high aluminum content PTFE/Al energetic materials, PTFE/Al specimens with porosities of 1.2%, 10%, 20%, and 30% were prepared by adding additives. The dynamic compression properties and impact response characteristics of high aluminum content PTFE/Al energetic materials with porosity were studied by using a split Hopkinson pressure bar (SHPB) impact loading experimental system. Based on the one-dimensional viscoplastic hole collapse model, an impact temperature rise analysis model including melting effects was used, and corresponding calculation analysis was performed. The results show that with the increase of porosity, the yield strength and compressive strength of the material will decrease. Under dynamic loading, the reaction duration of PTFE/Al energetic materials with different porosities generally shows a tendency to become shorter as the porosity increases, while the ignition delay time is basically unchanged. In this experiment, the material response has the optimal porosity with the lowest critical strain rate, the optimal porosity for PTFE/Al energetic materials with different porosity and high aluminum content (50/50 mass ratio, size of specimens Φ8 × 5 mm) is 10%. The research results can provide an important reference for the engineering application of PTFE/Al energetic materials.
Highlights
Metal and fluoropolymer composites are energetic materials that can initiate chemical reactions when impacted
Taylor bar impact experiments to study the law of deformation and ignition time of PTFE/Ti energetic materials caused by the impact of the material ratio and the impact speed of the bar
A split Hopkinson pressure bar (SHPB) experimental test system will be used to conduct research on the effect of porosity on the dynamic mechanical properties and reaction characteristics of high aluminum content PTFE/Al energetic materials, in order to provide an important reference for the engineering application of high aluminum content PTFE/Al energetic materials
Summary
Metal and fluoropolymer composites are energetic materials that can initiate chemical reactions when impacted. Previous researchers have carried out much research work on the component ratio, particle size, density, and material reaction characteristics of PTFE-based energetic materials. In view of the previous studies on the effects of porosity on the dynamic mechanical properties and impact response characteristics of PTFE/Al energetic materials, there is little research, especially for high aluminum content PTFE/Al (mass ratio 50/50) energetic materials. A split Hopkinson pressure bar (SHPB) experimental test system will be used to conduct research on the effect of porosity on the dynamic mechanical properties and reaction characteristics of high aluminum content PTFE/Al energetic materials, in order to provide an important reference for the engineering application of high aluminum content PTFE/Al energetic materials
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