A consumable material for use in an extrusion-based digital manufacturing system, the consumable material comprising a length and a cross-sectional profile of at least a portion of the length that is axially asymmetric. The cross-sectional profile is configured to provide a response time with a non-cylindrical liquefier of the extrusion-based digital manufacturing system that is faster than a response time achievable with a cylindrical filament in a cylindrical liquefier for a same thermally limited, maximum volumetric flow rate.

An insulating glazing includes two glass sheets spaced apart by at least one air- or gas-filled cavity, at least one transparent spacer made of glass, which is arranged at a periphery of the glass sheets and which keeps the two glass sheets spaced apart, and a transparent fastening system to fasten by adhesive bonding, which fastens the spacer to each glass sheet via two opposite fastening faces of the spacer, wherein the spacer made of glass is obtained by the cutting of glass sheet in a raw state, and is joined to the glass sheets directly in the raw state, and wherein the fastening system to fasten by adhesive bonding consist of a transparent material having been placed at an external junction of the spacer and of the glass sheets and having flowed into asperities of the glass of the fastening faces of the spacer.

A laminated surface covering including a facing material made of vinyl and a backing material comprising a rubber component. The rubber component comprising at least a matrix of bonded rubber granules. A bonding material disposed between the facing material and the backing material. The facing material configured to melt at a temperature between 165 F. and 248 F. infiltrating the backing material thereby essentially encasing the rubber granules of the matrix and providing fire retardation and smoke suppression qualities.

The invention relates to an intermediate material (132) for the manufacture of composite components, having a prepreg layer (116) and an interleaving layer (120) made up of at least two sections of thermally joined thermoplastic interleaving material sections (120a, 120b). The invention also relates to a method of manufacture of such an intermediate material.

The present invention relates to a composite container comprising a bottom film layer and a top film layer at least partially adhered to the bottom film layer. The top film layer is scored to form at least one resealable flap and at least one pull tab which is not adhered to the bottom film layer. The bottom film layer comprises at least one cavity opening. A cardboard layer is adhered on its lower surface to the upper surface of the top film layer, wherein the cardboard layer has at least one cavity opening which is substantially aligned with the scoring of the top film layer resealable flap and the cardboard layer is perforated to define a perimeter of at least one pull tab which is substantially aligned with and adhered, on its underside, to the upper surface of the top film layer pull tab.

A tag is configured to be inserted into a product. The tag includes a label portion and an insertion portion. The label portion has a first width. The insertion portion extends from the label portion, has a second width that is less than the first width, and has a length. An elongated wire extends along the length of the insertion portion to at least a part of the label portion. The tag has sufficient rigidity to enable a user to hold the label portion and force the insertion portion into the product. In another aspect, a method of attaching a tag to a product is described. The method includes holding the label portion and forcing the insertion portion into the product.

A multilayered sheet assembly includes a carrier layer on which a sign layer is arranged on a first side via a first adhesive layer. The sheet assembly further includes a strip layer which is arranged via a second adhesive layer in adhesively separable manner on a second side of the carrier layer. A further includes arranging the multilayered sheet assembly on a cutting device, arranging a peripheral cut in the sheet assembly along an outer periphery of a sign, arranging an inner cut in the sheet assembly along a peripheral line of at least one enclosed surface area not forming part of the sign, separating the strip layer with adhesive retention of the at least one enclosed surface area not forming part of the sign, and separating the sign layer from the carrier layer.

A method includes dicing a wafer to form discrete components; transferring the discrete components onto a transparent carrier, including adhering the discrete component to a carrier release layer on the transparent carrier; and releasing one of the discrete components from the transparent carrier, the one of the discrete components being deposited onto a device substrate after the releasing.

A sealing element of flexible foam which includes at least three sealing tape sections which are arranged next to each other in a functional direction of the sealing element. At least one first barrier layer section and at least one second barrier layer section are each accommodated between two adjacent sealing tape sections. The barrier layer sections connect the adjacent sealing tape sections to each other. The first barrier layer section forms a loop in an area of the bottom surface of the sealing element and the second barrier layer section forms a loop in an area of the top surface of the sealing element.

A sandwich structure includes two cover layers and a core arranged therebetween, and at least one connecting element for connection to further components. The connecting element has an insert, which is embedded into the sandwich structure at a cover layer of the two cover layers. An embedding depth of the insert is less than a thickness of the core. The connecting element is finished flush with an outer side of the cover layer via which the connecting element is embedded or protrudes from the cover layer.