| 摘要 |
<p>The method comprises: depositing a glass layer on a surface of a transparent, thermoplastic shaped body (5); applying an adhesion promoter on the surface of the shaped body; applying a layer made of glass nanoparticles (6) to the surface of the shaped body coated with the adhesion promoter; and locally inputting an energy by a thermal radiation, microwave radiation or laser in a region of the surface of the shaped body, where the glass nanoparticle forms a homogeneous layer. The method further comprises heating the surface of the shaped body in the region of a glass transition temperature. The method comprises: depositing a glass layer on a surface of a transparent, thermoplastic shaped body (5); applying an adhesion promoter on the surface of the shaped body; applying a layer made of glass nanoparticles (6) to the surface of the shaped body coated with the adhesion promoter; and locally inputting an energy by a thermal radiation, microwave radiation or laser in a region of the surface of the shaped body, where the glass nanoparticle forms a homogeneous layer. The method further comprises heating the surface of the shaped body in the region of a glass transition temperature, applying the glass nanoparticles on the heated surface of the shaped body, and imbedding the glass nanoparticle into the surface of the shaped body by a mechanical force. The mechanical force takes place by rolling or pressing (5). The glass layer is applied by a sol-gel process. The step of coating the shaped body is carried out by dipping and pulling at a constant speed from a solution of precursors and then annealing. The shaped body is cooled by a cooling device during coating. An independent claim is included for a transparent, thermoplastic shaped body.</p> |
