Aspects herein are directed to articles of apparel formed from a base textile and including a plurality of discrete overlay film structures affixed to the base textile at one or more locations on the article of apparel. When exposed to an external stimulus, the film structures undergo an increase in dimension in at least the z-direction and the base textile undergoes a change in dimension in at least the z-direction to produce stand-off nodes.

Technologies are generally described for hybrid acoustic damping materials that may be used in noise, vibration, and harshness mitigation. In some examples, solvated acrylic, silicone, and/or urethane materials may be blended in selected proportions to form a hybrid acoustic damping material. Characteristics of the components of the hybrid acoustic damping material such as viscosity and proportions may be selected for a desired composite loss factor vs. temperature characteristic of the material. In some examples, a broad temperature range of damping or a targeted temperature region may be achieved based on the composition of the hybrid acoustic damping material. To achieve a uniform stable blend with a consistent viscosity, individual component materials may be selected with similar molecular weight/viscosity. Compatible solvents may be added during blending of the components. In various example applications, the hybrid acoustic damping material may be used in vehicle brake applications to reduce brake noise/vibration.

A processing method of a base material sheet includes winding out the base material sheet wound up by a first core and a first porous sheet wound up by a second core, winding up by a third core the base material sheet and the first porous sheet to be overlapped with each other, and processing the base material sheet by a first processing liquid held in the first porous sheet; and winding out the base material sheet and the first porous sheet overlappingly wound up by the third core, winding up the first porous sheet by the second core, and winding up the base material sheet by the first core.

A display device includes a non-transmissive display section and a transmissive display section. The non-transmissive display section includes a base member including a first polyimide. The transmissive display section includes a base member including a second polyimide that has higher transparency than the first polyimide. The base member of the non-transmissive display section and the base member of the transmissive display section are connected in a connecting section. A bending portion is provided in the base member of the non-transmissive display section or the base member of the transmissive display section. The connecting section and the bending portion do not overlap each other.

A developer comprises: at least one carrier; and, in an amount of 10 wt-% or less, a coating material (237), in particular for generating a coating layer by non-impact printing, the coating material being provided in the form of particles and comprising: a curable resin preferably an at least partially thermal curable resin and even more in particular curable by a crosslinking agent able to react with functional groups of the resin, the resin comprising in particular an amorphous resin portion; wherein an average diameter of the particles is in a range between 1 m and 25 m; and wherein the particles have an average sphericity larger than 0.7, in particular larger than 0.8, in particular a sphericity larger than 0.9; wherein, if the coating material is heated from room temperature with a heating rate of 5 K per minute, the coating material upon heating reduces its viscosity down to a minimum viscosity and increases its viscosity upon further increase of the temperature; wherein the minimum viscosity is in a range between 3 Pascal seconds and 20000 Pascal seconds.

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.

Coating material (237) for generating a coating layer by non-impact printing wherein the coating layer represents an image and wherein a resolution of the image is at least 100 DPI, the coating material comprising a curable resin; wherein the coating material (237) exhibits a minimum viscosity when being heated from room temperature with a heating rate of 5 Kelvin per minute up to a temperature where curing of the coating material occurs, wherein the minimum viscosity is in a range between 3 Pascal seconds to 20000 Pascal seconds, in particular in a range between 50 Pascal seconds and 10000 Pascal seconds and further in particular in a range between 250 Pascal seconds and 7000 Pascal seconds; and wherein a pill flow length is below 350 mm at a potential curing temperature which may be used to cure the coating material.

This invention relates generally to flocked articles and methods for making the same, more particularly to flocked products having a silicone adhesive and methods for making and using the same.

One or more aspects of the present disclosure are directed to components having an optical element that imparts structural color to the component or article. The present disclosure is also directed to articles of manufacture including the component having an optical element, and methods for making components and articles having an optical element that imparts structural color.

The present disclosure is to provide a laminated film for decorating a three-dimensional molded product by vacuum forming which has a crack and strain-free uneven design on the clear coating film layer being an outermost layer at the time of use and provide a good design property to a molded product. A laminated film for decorating a three-dimensional molded product by vacuum forming, having a base material film layer (A), a clear coating film layer (B), and a design layer (C), wherein at least one face of the base material film layer (A) bordering the clear coating film layer (B) has an uneven design.