In industrial production, many materials need to operate in high-temperature environments. Ordinary coatings often struggle to withstand high temperatures, easily cracking, peeling, or developing other issues that shorten the service life of equipment. However, the emergence of IOTA 9150 Organopolysilazane has opened up new possibilities for material protection in high-temperature settings.
This product exhibits excellent high-temperature resistance depending on its application form. For clear coatings, the recommended service temperature is below 500°C; for formula-based coatings, the service temperature can even be below 1000°C—an outstanding performance among similar products. Whether applied to the surface of industrial equipment subjected to high-temperature baking or special components that need to withstand high temperatures, it can function stably and provide reliable protection for materials.
However, there is a small detail to note when using it in high-temperature environments: coating thickness affects its performance. A thicker coating offers better protective performance but is relatively more prone to cracking under high temperatures. Therefore, in practical applications, it is necessary to reasonably control the coating thickness based on specific temperature conditions and protection requirements to achieve the best results.
Beyond high-temperature resistance, IOTA 9150 also excels in other properties. Its curing methods are highly flexible: it can be cured at room temperature without a catalyst, with complete curing taking just over 24 hours. If you want to speed up the curing process, after the coating surface dries, you can dry it at 120-180°C for 2-6 hours to finish curing. Alternatively, it can be directly heat-cured by baking at 200-250°C for 10-20 minutes, followed by cooling and standing at room temperature for more than 12 hours. These diverse curing methods allow it to adapt to different production rhythms and scenario requirements.
At the same time, the coating formed after curing has excellent chemical barrier properties, effectively blocking the penetration of gases such as oxygen and water. This prevents gas erosion of the substrate in high-temperature environments, further extending the service life of materials and equipment. In industries with frequent high-temperature operations, such as electric power, metallurgy, and chemical engineering, IOTA 9150 is undoubtedly an ideal choice for material protection.
