The technology described herein relates to breathable, vented, and insulating garments. More particularly, the technology described herein relates to articles with a plurality of interconnected chambers that are configured to retain a thermally insulating fill material such as down or synthetic fibers. The plurality of interconnected chambers are formed between at least two layers of material and between a plurality of seams. The plurality of seams are configured to join the at least two layers of material together. In one aspect, each seam of the plurality of seams is angularly oriented with respect to an adjacent or neighboring seam of the plurality of seams. One or more openings or perforations may be formed on one or more seams of the plurality of seams forming the plurality of interconnected chambers. The one or more openings may achieve evaporation of moisture and/or air transfer from an interior environment of the garment to an exterior environment.

A process of manufacturing a waterproof enclosure and sealing the waterproof enclosure includes the steps of forming a rectangular waterproof upper member and a rectangular waterproof lower member; forming four rectangular adhesive members; securing the adhesive members to the lower member by pressing and heating; securing three edges of the upper member to the lower member by pressing and heating to form a partially open enclosure having an open edge; punching a plurality of positioning holes on a periphery of the partially open enclosure; placing an article in the partially open enclosure by inserting the article through the open edge of the partially open enclosure; sealing the open edge of the partially open enclosure by pressing and heating to form a sealed enclosure; and cutting the periphery having the positioning holes to finish a waterproof enclosure.

According to an embodiment of the present disclosure, a method for manufacturing a 3D structure includes: making a plurality of single piece molds having a same surface shape as a portion of a surface of the 3D structure; making a plurality of exterior members having the same surface as the portion of the surface of the 3D structure by using the respective single piece molds; and forming the 3D structure by connecting the plurality of exterior members.

The invention relates to an apparatus (10) for embedding a continuous elastic cord (11) along an edge of a continuous plastic sheet (12). The apparatus comprises an adhesive applicator device operable to apply an adhesive (16) along the edge of the plastic sheet, a folder device (18, 20, 34) operable to provide a folded edge of the plastic sheet (12) so that the adhesive is within the folded edge, and a feed device (24) having a tension device (30) operable to feed the elastic cord (11) in tension into the folded edge so that the elastic cord (11) is in contact with the adhesive of the edge. A bonding device (38) is operable to activate the adhesive of the folded edge to bond the elastic cord (11) in tension to the adhesive within the folded edge and to bond the folded edge to the plastic sheet (12). The invention also relates to a plastic sheet having an elastic cord at an edge thereof, a method for manufacture of said plastic sheet, and products or covers made from said plastic sheet such as oversleeves, overshoes, hair nets or bin liners etc.

In an example, a method is described. The method comprises placing a repair patch over a repair area of a structure, the repair patch comprising a repair-patch hole. The method also comprises sealing the repair patch and repair area with a vacuum bag having a seal ring around a periphery of the vacuum bag. The method also comprises evacuating, via an adhesive injection apparatus attached to the repair-patch hole and the seal ring of the vacuum bag, the repair area and an injection channel of the adhesive injection apparatus. The method also comprises forcing adhesive through the evacuated injection channel and into the evacuated repair area.

The present invention is directed to a method of forming a bottom-gusseted package, wherein each package includes an inwardly-extending, pleat-like gusset at the bottom of the package. To permit heat-sealing formation of each package, the sleeve from which each gusset is formed comprises a lamination of two differing polymeric materials, a sealant layer and a non-sealant layer, so that only an exterior surface of each sleeve, at which the sealant layer is positioned, exhibits the desired heat-sealing characteristics. To facilitate package formation, the sleeves from which the bottom gussets are formed are maintained in a closed or sealed configuration during package formation by providing a heat-sealed bond at the edge of each sleeve. In one embodiment, portions of the non-sealant layer are vaporized to provide sealable surface regions of the sealant layer. In an alternative embodiment, a lamination of the sealant and non-sealant layers is formed such that the sealant layer extends laterally beyond the non-sealant layer, to thereby provide sealable surface regions of the sealant layer.

Provided are stiffened stringer panels with integrated shim structures. An example composite panel comprises a skin member having an inner surface, and a stringer positioned on the inner surface. The stringer comprises a first flange portion and a second flange portion with the first flange portion and the second flange portion contacting the inner surface. The composite panel further comprises an integrated shim positioned on the first flange portion. The integrated shim may comprise a sacrificial material configured to be trimmed to the desired geometry. The sacrificial material may comprise a glass fiber reinforced plastic fabric pre-impregnated with resin. The integrated shim may be configured to interface with internal support structures of a wing assembly. The integrated shim may be configured to he machined to fit dimensions and measurements corresponding to the internal support structures of the wing assembly.

A method for making labels comprising providing a plastic substrate layer and a paper substrate layer. The paper substrate layer comprises a printed display information sheet, wherein the printed display information sheet comprises a plurality of display information tags arranged in an array. The plastic substrate layer is coupled to each of the rows of display information tags within a first portion of the display information tags to form a composite substrate row. A first line of perforations is cut into a width of the composite substrate at one or more first spaced intervals, a length of the first spaced intervals being defined by a length of the display information tags. A second line of perforations is cut into a width of the composite substrate at one or more second spaced intervals, a length of the second spaced intervals being defined by a height of the display information tags.

A container blank having an article handling feature for handling the container blank as well as the flexible packages made therefrom during manufacture, and method of making flexible packages using such a feature are described herein. Also described herein is an array of flexible packages containing a common article handling feature provided by such a method.

At least one of a horn or an anvil includes protrusions that protrude from a facing surface thereof. Two panel parts and a gusset part folded and interposed between the panel parts are sandwiched and compressed by the horn and the anvil. Two portions of the gusset part are welded to each other by ultrasonic vibration of the horn during the sandwiching and compressing.