An illustrative apparatus includes a first substrate and a second substrate. The first substrate includes a first adhesive-receiving face. The first adhesive-receiving face includes a first adhesive-coated region and a first release region. The first substrate also includes a first print receiving face opposite the first adhesive-receiving face. The second substrate includes a second adhesive-receiving face. The second adhesive-receiving face includes a second adhesive-coated region and a second release region. The second substrate also includes a second print receiving face opposite the second adhesive-receiving face. The first adhesive-coated region is releasably adhered the second release region and the second adhesive-coated region is releasably adhered to the first release region.

A manufacturing apparatus of a display device includes a first jig configured to hold a first member; a second jig located under the first jig and coupled to or separated from the first jig such that the first member is locatable between the first jig and the second jig; fixing parts located at both ends of the second jig and configured to hold a second member between the first member and the second jig, the second jig including a pad; and a stage located under the pad and provided with a groove formed therethrough and having an area smaller than an area of the pad when viewed in a plan view, wherein one portion of the pad, which faces the stage, is configured to be within the groove.

A method of stencil printing includes printing a layer of non-sag adhesive onto a first substrate, adding topography to the layer of non-sag adhesive, and contacting the layer of non-sag adhesive with a second substrate. The second substrate initially contacts only about 5% or less of exposed surface area of the layer of non-sag adhesive.

An illustrative apparatus includes a first substrate and a second substrate. The first substrate includes a first adhesive-receiving face. The first adhesive-receiving face includes a first adhesive-coated region and a first release region. The first substrate also includes a first print receiving face opposite the first adhesive-receiving face. The second substrate includes a second adhesive-receiving face. The second adhesive-receiving face includes a second adhesive-coated region and a second release region. The second substrate also includes a second print receiving face opposite the second adhesive-receiving face. The first adhesive-coated region is releasably adhered the second release region and the second adhesive-coated region is releasably adhered to the first release region.

The present invention relates to the display technology field, and provides a backplate, a plastic-iron integrated structure, a backlight unit, and a display device. The backplate is provided with a first through hole, and the first through hole has an inner wall and an outer wall which form a projection structure on the backplate. When the backplate is bonded with a plastic frame to form the plastic-iron integrated structure, the plastic frame not only contacts the inner wall of the first through hole, but also contacts the surface of the projection structure, thus increasing the contact area between the plastic frame and the backplate, and increasing the bonding force between the plastic frame and the backplate. Even when the plastic frame shrinks in case of fluctuations in temperature and/or humidity, the plastic frame is not easily separated from the backplate, and the stability of the formed plastic-iron integrated structure is improved.

An apparatus for receiving, from a wide container stream upstream from the apparatus, single-lane container streams and creating package units of containers includes a separating and/or combining unit, application elements, and a linear transporter. The unit separates and/or combines containers to form partial packaged units that are then combined into a package unit. The application elements are disposed so that at least one container of a package unit has, on a contact surface thereof, adhesive or glue. The linear transporter comprises transport elements circulate along a guide element, and a controllable drive. Each transport element of the linear transporter comprises as many head guides as there are containers in the package unit, each of which is axially movable or rotatable relative to the transport element.

Large area graphene (LAG) sheets can be embedded in a polymer-based material as a mechanical reinforcement or to otherwise enhance the properties of the polymer-based material. The LAG sheets can be nanoperforated and/or functionalized to enhance interaction between the graphene and the polymer. Reactive functional groups can facilitate formation of covalent bonds between the graphene and the polymer so that the LAG sheets become an integral part of the cross-linked structure in curable polymer-based materials. Nanoperforations in the LAG sheets provide useful sites for the functional groups and can allow cross-links to form through the nanoperforations.

A display panel manufacturing method is provided. A display function unit is provided on a surface of a first substrate. Sealing material is provided in a region on the surface of the first substrate that is surrounding the display function unit. Resin is then placed in an inside region of the sealing material over the surface of the first substrate. A total volume amount of the resin placed is greater than a volume capacity of an open space surrounded by the sealing material above the surface of the first substrate. A second substrate is bonded with the first substrate via the sealing material to provide a closed space with the resin being provided in the closed space.

An accessory unit includes a front flap and a rear cover. The rear cover includes a recessed portion that defines a chamber and a lip that extends about an opening of the chamber. The chamber is configured to receive a consumer electronic device, and the lip is configured to hold the consumer electronic device therein. The rear cover can include a shell formed from glass fiber reinforced plastics and a lip formed from a thermoplastic. The front flap may include segments formed from panels with folding regions therebetween, which allow the front flap to fold. Further, an end region of the front flap hingedly couples the front flap to the rear cover, such that the front flap may be moved between open and closed configurations. Methods of manufacturing the accessory unit are also disclosed.

A vehicle cargo construct includes a floor, a plurality of side wall panels extending from the floor, and an end wall panel extending from the floor between the plurality of side wall panels. The floor has an upper surface and an oppositely opposed lower surface. Each of the plurality of side wall panels has an exterior surface and an oppositely opposed interior surface. The end wall panel has an exterior surface and an oppositely opposed interior surface. Each of the floor, the plurality of side wall panels, and the end wall panel being formed of a composite sandwich panel material formed of an open area core defining a plurality of pores, a surface sheet adhered to a first face of the open area core by a first adhesive layer, and a structural skin adhered to a second face of the open area core by a second adhesive layer.