A method of applying an alignment film on a substrate of a liquid crystal panel, the method includes: forming a surface having high wettability and a surface having low wettability, with respect to a material of the alignment film; bringing uniformly the material of the alignment film into contact with the surface having high wettability and the surface having low wettability when the material of the alignment film on the substrate is applied by using a transfer plate; and separating the transfer plate and the surface of the substrate such that the material of the alignment film is left on the surface having high wettability and the material of the alignment film is not left on the surface having low wettability.

The present invention relates to a method for manufacturing and painting characters press formed on license plates and to a tubular thermal-transfer film for carrying out said method which comprises: a step of press forming identifying characters (2) on an aluminum plate (1) with a reflective film (3), including a perimetral edge (4) or not, by means of using a hand- or motor-operated press forming machine or device; and a step of thermal stamping for painting the press formed characters (2) by means of thermal-transfer ink impregnated in a thermal-transfer film with a thermal stamping machine (6) which in turn comprises: introducing the plate (1) in a tubular thermal-transfer film (5), closing the open end or ends (5d) of said tubular film (5), introducing the assembly (5, 1) in the thermal stamping machine (6), and removing the finished plate (1) from inside the tubular film (5).

The present invention generally relates to a method for creating a chemically structured surface with structural elements as small as 1 nm, on a material that does not itself display a high degree of ordering, using thin molecular layers that minimize the material added through the coating. In particular, the present invention discloses a method for assembling a chemical pattern on a surface, comprising pattern elements with scales that can be as small as 1 nm, and then transferring that pattern to another substrate, on which the pattern would not form natively. In the described method, the patterned monolayer is comprised of polymerizable amphiphiles such as diyne phospholipids or diynoic acids, which are transferred from the ordering substrate using a transferring material such as poly(dimethylsiloxane).

A drug transfer device and a method for forming a drug layer are disclosed, which can quickly and easily provide an appropriate amount of a drug on a surface of a medical instrument. The drug transfer device is configured to transfer a drug to a surface of a balloon, the drug transfer device including a heat-shrinkable tube, and a drug layer provided on an inner surface of the heat-shrinkable tube.

The present disclosure is directed to components of articles that include an optical element that imparts structural color to the component. The present disclosure is also directed to methods of making the components including the optical element, and methods of using the components such as to make an article of manufacture.

One or more aspects of the present disclosure provide optical element transfer structures that include an optical element releasably coupled with a transfer medium and methods of making and using the optical element transfer structures. The optical element transfer structures can be used to dispose an optical element onto an article, whereby the optical element imparts a structural color to the article.

One or more aspects of the present disclosure are directed to bladders that incorporate a multi-layer optical film that impart a structural color to the bladder. The present disclosure is also directed to articles including the bladders having a multi-layer optical film, and methods for making articles and bladders having a multi-layer optical film.

A non-impact printing device (301) comprising: a coating material (237) being curable and comprising a resin; the coating material comprising an amorphous resin portion in an amount of at least 30 w-% based on the overall amount of resin and comprising with respect to the entire amount of coating material less than 0.5 w-% of flow additive; a printing unit, in particular an electrophotographic printing unit, being configured for printing the coating material (237) so as to form a coating layer, wherein the coating layer forms at least part of a layer package comprising at least one layer; the non-impact printing device being configured for providing the layer package so as to define a surface structure with the layer package; wherein the surface structure is defined by a thickness variation of the layer package; wherein the thickness variation is in a range between 1 m and 1000 m, in particular in a range between 1 and 300 m, and is in particular more than 1 m, in particular more than 5 m, in particular more than 10 m and in particular more than 20 m.

One or more aspects of the present disclosure are directed to bladders that incorporate a multi-layer optical film that impart a structural color to the bladder. The present disclosure is also directed to articles including the bladders having a multi-layer optical film, and methods for making articles and bladders having a multi-layer optical film.

One or more aspects of the present disclosure are directed to bladders that incorporate a multi-layer optical film that impart a structural color to the bladder. The present disclosure is also directed to articles including the bladders having a multi-layer optical film, and methods for making articles and bladders having a multi-layer optical film.