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Experimental and theoretical investigation of dry-water containing phosphoric acid for new fire suppressant

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Abstract To overcome the shortcomings of phosphorus-containing compounds (PCCs, not widely used) in fire suppression, the dry water powder containing phosphoric acid was analyzed for a new fire suppressant (SiO2-P).… Click to show full abstract

Abstract To overcome the shortcomings of phosphorus-containing compounds (PCCs, not widely used) in fire suppression, the dry water powder containing phosphoric acid was analyzed for a new fire suppressant (SiO2-P). First, the fine conditions (solid-to-liquid ratio, stirring time and stirring speed) were determined to prepare the new powder. The particle size distributions and XPS of SiO2-P powder were analyzed. The TG tests were conducted to study the decomposition of powder, and there was a major decomposition peak. Second, the extinguishing time of SiO2-P powder was tested, which showed that the SiO2-P powder containing phosphorus species could significantly improve the fire suppression ability. In addition, the kinetic parameters of powder decomposition reaction were determined by genetic algorithm based on TG results. Last, based on the decomposition products and kinetic parameters, the burning velocity and mass fraction of free radicals of CH4/air flame with SiO2-P powder addition were studied theoretically. The results indicated that SiO2-P powder had great ability of reducing the burning velocity and scavenging free radicals. Furthermore, the suppression effects were analyzed, which indicated that the cooperation of H2O and P suppression effect dominated the suppression mechanism and resulted in the good suppression efficiency.

Keywords: sio2 powder; dry water; containing phosphoric; powder; fire; suppression

Journal Title: Journal of Loss Prevention in The Process Industries
Year Published: 2021

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