Waterborne polyurethane assembly multifunctional coating for hydrophobic and antibacterial fabrics

Surface modification of fabrics is a powerful strategy that can endow fabrics with desired effects while keeping the intrinsic properties. Herein, an ordinary strategy, dipping-drying based layer-by-layer self-assembly (LbL) coating, is reported to functionalize fabrics' surfaces. Firstly, the novel cation waterborne polyurethanes (QAHDPU) and anion waterborne polyurethanes (HDPU) are successfully designed and synthesized. By incorporating targeted molecule, hydantoin diol (HD) and quaternary ammonium salt with long alkyl chain (DOQA), the QAHDPU are antibacterial and hydrophobically functionalized. Taking advantage of strong adhesion, waterborne polyurethanes (WPUs) are physically bonded to surfaces of fabrics to generate durable antibacterial and hydrophobic fabrics. The QAHDPU with long alkyl chain combined with rough and porous fabric surface fabricates hydrophobic fabric surface, which can prevent bacteria from adhering to the fabrics. Furthermore, the coated fabrics present excellent antibacterial properties after chlorination, forming a second barrier against bacteria. The chlorinated coated fabrics, can inactivate 85.0-99.9% of Staphylococcus aureus and 85.0-97.7% of Escherichia coli with contact time of 60 min. The hydrophobic properties of coated fabrics are greatly improved with water contact angles of 122.0 degrees-141.1 degrees. In addition, the proposed method is applicable for a variety of fibers and expected to be used for industrial production.

Automated summary

This study presents a common strategy involving dipping-drying based layer-by-layer self-assembly coating to functionalize fabric surfaces. Novel cation and anion waterborne polyurethanes were successfully designed and synthesized, resulting in antibacterial and hydrophobic properties on the fabric surfaces. The coated fabrics showed excellent antibacterial properties and improved hydrophobicity, making them suitable for industrial production and application on various fibers.