Synthesis and low-temperature curing behavior of weather-resistant saturated polyester resin suitable for coating for thermosensitive substrates

A novel carboxyl-terminated polyester resin was strategically synthesized as an advanced coating matrix for composites. The resin was engineered through high-temperature melt esterification of neopentyl glycol with terephthalic acid, followed by acid-end capping using isophthalic acid and adipic acid, and finally vacuum-assisted polycondensation. Comprehensive characterization via FTIR, XRD, and TGA validated its structural integrity and thermal resistance, exhibiting a glass transition temperature of 52.2 °C and 5 % weight loss at 370 °C. More importantly, as a composite coating material, the resin demonstrated exceptional processing compatibility with thermosensitive PE/wood plastic composites, achieving a durable curing temperature at 140 °C, while maintaining substrate dimensional stability (with length and thickness variations of 0.24 % and 2.89 % respectively). The cured coating exhibited outstanding performances: 95.2 % curing degree, perfect adhesion (Grade 0), and 55.1 % gloss retention after 240-h UV aging, confirming its superior weatherability. Such work establishes a theoretical and experimental foundation for implementing coating in low-temperature-curable composites.