A system for applying materials to components generally includes a tool operable for transferring a portion of a material from a supply of the material to a component. The tool may include a resilient material configured for tamping the portion of the material onto the component and imprinting the portion of the material for release and transfer from the supply.

A fabric (30) includes a first flexible fabric layer (32), having fabric emissivity properties in a visible radiation range that are selected so as to mimic ambient emissivity properties of a deployment environment of the fabric, and at least one second flexible fabric layer (34), which is joined to the first flexible fabric layer, and which is configured to scatter long-wave radiation that is incident on the fabric. The first and second flexible fabric layers are perforated by a non-uniform pattern of perforations (44) extending over at least a part of the fabric.

The present disclosure discloses a support film, an OLED display structure and a manufacturing method thereof. The support film includes a first adhesive material layer and a first base material layer, which are stacked together, and a first release film therebetween.

A method of making the asphalt shingles includes applying a substrate to a layer of shingle-forming material, the substrate having indicators at predetermined spaced-apart distances, with the indicators being sensed as the shingle-forming layer is moved along a predetermined path, with adhesive zones being applied to the shingle such that the application of the adhesive zones is synchronized in response to sensing the locations of the indicators, and with the shingle-forming layer then being cut into individual shingles.

An object with a conductive element on a receiving carrier layer and a roll-to-roll processing method for manufacturing it. The solution is based on the idea of operating systematically with two different types of adhesives in selected stages of the roll-to-roll processing. A very thin layer of conductive material can be accurately and reliably transferred to adhesively attach on a desired carrier surface.

The disclosure provides a method for forming a core layer for a plurality of information carrying cards, a resulting core layer, and a resulting information carrying card. A first portion of a crosslinkable polymer composition is dispensed onto the first thermoplastic layer. A second thermoplastic layer having a plurality of through-holes therein is then applied. A second portion of the crosslinkable polymer composition is dispensed into each through-hole. An inlay layer is placed over the polymer composition inside each through-hole. A third portion of the crosslinkable polymer composition is dispensed over each inlay layer. A third thermoplastic layer or a release film is placed over the third portion of the crosslinkable polymer composition to provide a layered structure. Each respective inlay layer is configured to be movable and/or self-center inside each through-hole in the presence of the crosslinkable polymer composition when the layered structure is pressed on a pressure.

A resin film configured to hold a conductive metallic track against a panel. The resin film partially covers the conductive metallic track, such that the conductive metallic track has at least one region which does not have the resin film, so as to allow an electrical connection by contact. Thus, in the context of assembly on a panel, the metallic track incorporated between the panel and the resin film is protected, thus rendering this technical solution particularly robust. Furthermore, the resin film electrically insulates the metallic track from surrounding elements, and the regions which do not have resin film allow an electrical connection by contact.

The present application relates to athletic field covers with wind-refracting layer.

Disclosed are methods of fabricating an integrated computational element for use in an optical computing device. One method includes providing a substrate that has a first surface and a second surface substantially opposite the first surface, depositing multiple optical thin films on the first and second surfaces of the substrate via a thin film deposition process, and thereby generating a multilayer film stack device, cleaving the substrate to produce at least two optical thin film stacks, and securing one or more of the at least two optical thin film stacks to a secondary optical element for use as an integrated computational element (ICE).

A method of making a cleaning article. The cleaning article has discrete tufts of tow fibers. The discrete tufts are unequally spaced from adjacent tufts, to provide improved collection and retention of debris from a target surface. The cleaning article may be made by cutting a precursor sheet having tufts into discrete portions. The discrete portions are then bonded to a carrier sheet.