Synthesis of Hydrophobic Nanosized Silicon Dioxide with a Spherical Particle Shape and Its Application in Fire-Extinguishing Powder Compositions Based on Struvite

Textural and morphological features of hydrophobic silicon dioxide, obtained by the hydrolysis of tetraethoxysilane in an ammonia medium followed by modification of a spherical SiO2 particles surface with a hydrophobic polymethylhydrosiloxane, were studied in this work. The size of silicon dioxide particles was controlled during preparation based on the Stober process by variation of the amount of water (mol) in relation to other components. The ratio of components, synthesis time and amount of the hydrophobizing agent were determined to obtain superhydrophobic monodisperse silicon dioxide with a spherical particle size of 50-400 nm and a contact angle of more than 150 degrees. In the case of the struvite example, it was demonstrated that the application of spherical-shaped hydrophobic silicon dioxide particles in powder compounds significantly improves the flowability of crystalline hydrates. The functional additive based on the developed silicon dioxide particles makes it possible to implement the use of crystalline hydrates in fire-extinguishing powders, preventing agglomeration and caking processes. The high fire-extinguishing efficiency of the powder composition based on struvite and the developed functional additive has been proven by using thermal analysis methods (TGA/DSC).

Automated summary

In this study, the textural and morphological features of hydrophobic silicon dioxide obtained through hydrolysis and modification were investigated. The size of the particles was controlled by varying the amount of water in the preparation process. The application of spherical-shaped hydrophobic silicon dioxide particles significantly improved the flowability of crystalline hydrates in powder compounds. The developed functional additive based on silicon dioxide particles prevented agglomeration and caking processes, making it suitable for fire-extinguishing powders.