The traditional two-component waterborne polyurethane coating system cannot effectively inhibit the undesirable side reaction between polyisocyanate and water during curing hardening. It is difficult to avoid the microbubbles formed by this reaction during the film formation process, which severely degrades the appearance and decreases the performance of the film. Therefore, the addition of an amphiphilic Linear-Dendritic carbosilane Block Surfactant (LDBS) to the hardener can physically separate the polyisocyanate emulsion from water through self-assembly. The bubble-free film thickness (BFFT) of the two-component waterborne polyurethane coating in this study is approximately 1.5-fold greater than commercial waterborne polyurethane coatings in today’s coating industry. Fourier transform infrared spectroscopy (FT-IR) varied the effectiveness of LDBS for inhibition of the undesirable side reaction. The successful application of the waterborne polyurethane coating with LDBS on the 600 km/h high-speed maglev train provides a technical solution for large-scale industrialization of waterborne polyurethane coating and complete replacement of solvent polyurethane coating.
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机译:传统的双组分水性聚氨酯涂料系统不能在固化硬化过程中有效地抑制多异氰酸酯和水之间的不希望的副反应。在膜形成过程中难以避免通过该反应形成的微泡,这严重降低了外观并降低了膜的性能。因此,两亲性线性 - 树枝状碳硅烷块表面活性剂(LDBS)的添加到所述硬化剂可以物理多异氰酸酯乳液从水通过自组装分离。本研究中双组分水性聚氨酯涂层的无气泡膜厚度(BFFT)比当今涂层工业中的商业水性聚氨酯涂料大约1.5倍。傅里叶变换红外光谱(FT-IR)改变了LDBs以抑制不希望的副反应的有效性。在600 km / h高速Maglev列车上使用LDB进行水性聚氨酯涂层的成功应用为水性聚氨酯涂料的大规模产业化提供了一种技术方案,并完全替代溶剂聚氨酯涂层。
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