How does scratch-resistant Fvilm UV Varnish achieve super wear resistance?
Release Time : 2025-02-07
The reason why scratch-resistant Fvilm UV Varnish can achieve super wear resistance is mainly due to its unique formula, advanced production process and targeted performance optimization measures.
1. Unique formula
Addition of wear-resistant inorganic fillers: FVilm UV varnish adds wear-resistant inorganic fillers, such as nano-scale materials such as fumed silica powder and alumina powder. These fillers can significantly improve the hardness and wear resistance of the coating, so that it can maintain the integrity of the coating when facing external forces such as scratches.
Selection of high wear-resistant resin: Select main resins with strong wear resistance and scratch resistance, such as aliphatic polyurethane acrylate, polyester acrylate, etc. These resins themselves have good wear resistance and can form a hard coating after curing, which effectively resists scratches and wear.
Addition of special additives: In order to further improve the wear resistance, special additives such as coupling agents, hard wax, fluorinated surfactants, and modified polysiloxanes may also be added to FVilm UV varnish. These additives can improve the dispersion, stability, and wear resistance of the coating, thereby improving the overall performance of the coating.
2. Advanced production technology
Fine grinding and dispersion: During the production process, a high-speed disperser is used to finely grind and disperse the coating to ensure that raw materials such as fillers and resins can be evenly distributed in the coating. This helps to improve the uniformity and stability of the coating, thereby enhancing the wear resistance.
Strict quality control: Strict quality control measures are also implemented in the production process of FVilm UV varnish, including raw material inspection, production process monitoring, and finished product testing. These measures can ensure that each batch of coating meets the quality standards, thereby ensuring the stability of its wear resistance.
3. Performance optimization measures
Formula adjustment and optimization: According to actual application requirements and test results, the formula of FVilm UV varnish is adjusted and optimized. The wear resistance and comprehensive performance of the coating can be further improved by changing factors such as filler type, resin ratio and additive addition.
Coating structure design: A special coating structure design, such as microphase separation structure, is used to improve the balance between hardness and flexibility of the coating. This structural design enables the coating to better disperse stress when subjected to external forces, thereby avoiding cracking or peeling of the coating.
Curing process optimization: The curing degree and cross-linking density of FVilm UV varnish can be further improved by optimizing light curing process parameters (such as light intensity, curing time, etc.). This helps to enhance the hardness and wear resistance of the coating while maintaining its good flexibility and adhesion.
In summary, scratch-resistant FVilm UV varnish achieves super wear resistance through unique formula design, advanced production technology and targeted performance optimization measures. These measures work together in the production and application process of the coating to ensure that the coating can maintain excellent wear resistance and integrity when facing external forces such as scratches.
1. Unique formula
Addition of wear-resistant inorganic fillers: FVilm UV varnish adds wear-resistant inorganic fillers, such as nano-scale materials such as fumed silica powder and alumina powder. These fillers can significantly improve the hardness and wear resistance of the coating, so that it can maintain the integrity of the coating when facing external forces such as scratches.
Selection of high wear-resistant resin: Select main resins with strong wear resistance and scratch resistance, such as aliphatic polyurethane acrylate, polyester acrylate, etc. These resins themselves have good wear resistance and can form a hard coating after curing, which effectively resists scratches and wear.
Addition of special additives: In order to further improve the wear resistance, special additives such as coupling agents, hard wax, fluorinated surfactants, and modified polysiloxanes may also be added to FVilm UV varnish. These additives can improve the dispersion, stability, and wear resistance of the coating, thereby improving the overall performance of the coating.
2. Advanced production technology
Fine grinding and dispersion: During the production process, a high-speed disperser is used to finely grind and disperse the coating to ensure that raw materials such as fillers and resins can be evenly distributed in the coating. This helps to improve the uniformity and stability of the coating, thereby enhancing the wear resistance.
Strict quality control: Strict quality control measures are also implemented in the production process of FVilm UV varnish, including raw material inspection, production process monitoring, and finished product testing. These measures can ensure that each batch of coating meets the quality standards, thereby ensuring the stability of its wear resistance.
3. Performance optimization measures
Formula adjustment and optimization: According to actual application requirements and test results, the formula of FVilm UV varnish is adjusted and optimized. The wear resistance and comprehensive performance of the coating can be further improved by changing factors such as filler type, resin ratio and additive addition.
Coating structure design: A special coating structure design, such as microphase separation structure, is used to improve the balance between hardness and flexibility of the coating. This structural design enables the coating to better disperse stress when subjected to external forces, thereby avoiding cracking or peeling of the coating.
Curing process optimization: The curing degree and cross-linking density of FVilm UV varnish can be further improved by optimizing light curing process parameters (such as light intensity, curing time, etc.). This helps to enhance the hardness and wear resistance of the coating while maintaining its good flexibility and adhesion.
In summary, scratch-resistant FVilm UV varnish achieves super wear resistance through unique formula design, advanced production technology and targeted performance optimization measures. These measures work together in the production and application process of the coating to ensure that the coating can maintain excellent wear resistance and integrity when facing external forces such as scratches.