Formulation optimization of a silicon-based fire protective coating in terms of intumescent alkali silicate particles
Aixiao Fu, Hafeez Ahmadi, Burak Ulusoy, Hao Wu, Ander Labaien Etxeberria, Kim Dam‐Johansen
Abstract
Alkali silicate particles suggested efficient expansion capacity due to water release, making them potential candidates as expandable agents in intumescent coatings. Different types of particles with different alkali cations (Na-, K- or Li-) and varied SiO 2 /Na 2 O molar ratios were incorporated into a silicone binder and their fire protection performance was investigated. Among the tested alkali cations, the Na-based system exhibited the best performance with a critical time of 64.3 minutes reaching a failure temperature of the steel of 550 °C, tested under UL 1709 fire scenario. This was attributed to its efficient expansion ratio, while a lower degree of intumescence led to the unsatisfactory performance of K- and Li-based systems. Additionally, the melting behaviour of K-based silicate particles and their pronounced catalytic effect on silicone decomposition were unfavourable for effective heat insulation of the composed coating. An optimal SiO 2 /Na 2 O molar ratio was found to be 4.2 among a lower molar ratio of 3.5 and a higher molar ratio of 4.9. By optimizing the particle size of sodium silicate particles to 125–212 µm, the critical time was further prolonged to 78.6 minutes. These findings underscore the adverse effects of excessive expansion, which results in the formation of large pores that facilitate heat transfer. This conclusion stems from a detailed structural analysis of the selected expanded coatings utilizing X-ray microcomputed tomography (µ-CT). • Different alkali silicates were used as intumescent agents in the silicone binder. • The Na-based system was optimal compared to K- and Li- due to its high expansion. • A good ash structure is also important to ensure a lower thermal conductivity.