Main centres: | 1-3 business days |
Regional areas: | 3-4 business days |
Remote areas: | 3-5 business days |
TRAINING Intended use: Training and weapons testing
Duke Training Inert Projectiles are filled with talc powder (Talc, or talcum, is a clay mineral, composed of hydrated magnesium silicate with the chemical formula Mg3Si4O10(OH)2. Talc in powdered form, often combined with corn starch, is used as baby powder). This projectile will burst upon impact to simulate our irritant cloud dispersal.
Duke Training Inert Projectiles have been meticulously designed to serve the specific purpose of training and weapons testing. These projectiles are engineered to burst upon impact releasing talc powder into the surrounding area, simulating an irritant cloud dispersal. This realistic simulation enables individuals and organizations to effectively prepare and train for scenarios involving irritant dispersion without the need for live agents or hazardous materials.
Duke Training Inert Projectiles offer a safe and controlled means of conducting training exercises and weapons testing involving irritant cloud dispersal.
Filled with inert fillers, including aluminium hydroxide and talcum, these projectiles closely mimic the behaviour of live irritant dispersal devices, providing a highly realistic training experience.
The use of talc powder as the burst material ensures that these projectiles are non-toxic and non-lethal, promoting safety during training and testing.
Duke Training Inert Projectiles offer a reliable and safe solution for professionals and organizations seeking to enhance their preparedness for irritant cloud dispersal scenarios. Whether for law enforcement, military, or security personnel, these projectiles facilitate realistic training and testing without compromising safety.
Please ensure responsible and lawful use of these training projectiles, following all relevant regulations and safety protocols. Duke Training Inert Projectiles are your trusted partner in honing the skills needed for effective irritant dispersal response.