The present invention is directed to a bag of polymeric film and a method to make the bag. The bag can be comprised of a front panel and a rear panel. The front and rear panels can each be comprised of multiple layers of film. The bag can be formed from a collapsed bubble of polymeric film that has been folded in half so that opposing edges of the collapsed bubble form an opening of the bag. One of the layers of the folded bubble can be split adjacent to an edge of the collapsed bubble and a draw tape film can be inserted between the layers of the folded and collapsed bubble. The collapsed bubble can further be embossed by a pattern that can provide enhanced properties to bags formed from the folded bubble.

There is provided an embossed film in which the frequency of loss of concavities is smaller, the embossed film including: a film main body; and a plurality of concavities formed on a surface of the film main body. A diameter of an opening surface of the concavity is larger than a visible light wavelength, an arrangement pattern of the concavities has periodicity along a length direction of the film main body, and the difference between the rate of loss of concavities in one end portion of the film main body and the rate of loss of concavities in the other end portion of the film main body is 10 ppm or less.

To provide a resin molded product having a desired surface shape, a resin molding mold which can manufacture the resin molded product and a method of manufacturing the same, and a resin molding mold manufacturing system to achieve manufacturing of the resin molding mold, a resin molding mold according to the present invention includes a molding mold main body and a resin layer exposedly formed on a mold surface side of the molding mold main body, made of a heat-resistant complex material containing a synthetic resin, and a ceramic powder particle, and having a thickness of 50 to 800 μm. The resin molding mold according to the present invention includes the molding mold main body and the resin layer exposedly formed on the mold surface side of the molding mold main body and made of the heat-resistant composite materials including a synthetic resin, and the ceramic powder particle, and recesses and projections are formed on the resin layer by excavating a portion of the resin layer.

A method for nanoimprinting a pattern on an organic polymer substrate, comprising: (a) preparing a soft operational mold, the operational mold comprising a pattern to be replicated to the substrate; (b) soaking the operational mold in a solvent to produce diffusion of solvent to the mold; (c) removing the operational mold from the solvent, and placing it on a surface of the organic polymer substrate to form a structure, and simultaneously (i) heating the structure to a temperature T<Tg, where Tg is the glass transition temperature of the organic polymer; and (ii) applying controlled pressure in a range of 20-300 psi on the mold to effect a penetration into the surface of the organic polymer substrate, thereby to replicate the pattern of the mold to the surface of the substrate; and (d) separating the operational mold from the patterned substrate.

A decorative sheet includes a base material and a plurality of concave portions. The plurality of concave portions are provided on a front face of the base material. In the concave portion, a depth direction coincides with a thickness direction of the base material. The plurality of concave portions includes a first concave portion and a second concave portion. The first concave portion includes a first concavo-convex pattern on a first inner surface of the first concave portion. The second concave portion does not include the first concavo-convex pattern on a second inner surface of the second concave portion.

Curing processing for curing a curable composite is performed in a state where a mold held by a mold holding unit and a substrate held by a substrate holding unit are in contact with each other through a curable composite, and mold release processing of the mold from the substrate is performed after the curing processing. In a case where the mold release processing fails, additional curing processing is performed. This enables releasing the mold even without performing recovery processing by an operator, thereby making it possible to provide a molding apparatus that is beneficial in productivity.

An article including a composite including a subsurface structure and a second phase of material forming a coating on the subsurface structure. The coating includes a first region defining a first plurality of microtextures in an outer surface of the coating, where the first plurality of microtextures include an average bore width of less than about 250 micrometers (μm) and a first average bore depth, and a second region positioned adjacent to the first region wherein the coating defines a second plurality of microtextures on the outer surface of the coating, where the second plurality of microtextures include an average bore width of less than about 250 μm and a second average bore depth less than the first average bore depth.

Seal member arrangements having at least one seal plate are disposed over stringer receiving recesses in ribs of an aircraft. A tool for locating a seal member arrangement over a stringer-receiving recess in a rib of an aircraft assembly. The tool system has a holder configured to hold the seal member arrangement over the recess. A biasing arrangement is configured to act on the holder to bias the seal member arrangement into an aligned position with a stringer received in the recess. A fixing arrangement is configured to act on the seal member arrangement to fix the seal member arrangement in the aligned position. A sealing kit, an aircraft assembly, a method of fixing a seal member arrangement over a stringer-receiving recess in a rib of an aircraft are also disclosed.

Described herein is a process for producing a structured article (A1M1) in which a material (M1) including at least one micro- and/or nanostructured surface (SU1) containing a plurality of micro-scale and/or nano-scale surface elements is covered with an at least partially cured coating layer (C2) to provide a composite (M1C2), said composite (M1C2) is attached to an object (A1) and the coating layer (C2) is at least partially peeled off to provide the structured article (A1M1). Also described herein is a composite (M1C2) in which the surface elements of the material (M1) are covered by a protective coating layer (C2).

The present invention provides a metal mold and the method of making the metal mold for casting directional gecko-inspired adhesives that require deep, slanted features and an undercut wedge structure. The durable metal mold can be used for high quantities. In one example, compression molding is used to mass produce the adhesives. What normally takes 24 hours to produce now with compressing molding takes 5 minutes. Compression molding allows us to increase daily production from 1 adhesive patch to thousands per day.