The present disclosure provides a film material and a display device, and relates to the field of display technology. The film material includes a base material and a functional film layer arranged on the base material, in which the base material includes an active region and an auxiliary region surrounding the active region, the functional film layer covering the active region, and not completely covering the auxiliary region. The film material provided by the present disclosure is applied into a display device.

Methods and apparatus for manufacturing a circular laminated component are disclosed herein. In one embodiment, a method comprises stamping an inlet stock of material to form a line of arc segments, the line of arc segments having: a plurality of notches along a first edge; a first longitudinal end; and a second longitudinal end opposite the first longitudinal end; wrapping the line of arc segments to form a circular segment having the first edge along an inner-circumferential diameter of the circular segment; joining the first longitudinal end to the second longitudinal end to form a circular laminate layer; and stacking a plurality of circular laminate layers to form a laminate disc.

A positive transport of carbon fiber bundles, in ribbon form, with in-line manipulation of the fiber bundles (spreading or spreading and volumization with manipulators) during fiber bundle transport to points of fiber bundle deliveries into the circular loom bed plate turntable is described herein. The automated placements of these deliveries of the fiber bundle/tow at selected orientations in the area correspond to the feeding zone of an improved circular loom bed plate turntable.

Systems and methods are provided for laying up laminates. One embodiment is a method that includes laying up a multi-layer laminate of fiber reinforced material onto a surface, by: feeding a tape of fiber reinforced material to tape cutters which cut the tape into pieces, picking up pieces of the fiber reinforced material via pick-and-place devices at each of multiple lamination units that are in sequence in a direction of travel, and placing the pieces of fiber reinforced material via the pick-and-place devices to form a laminate as the surface and the lamination units change position with respect to each other and multiple pieces are laid-up concurrently.

A fluid-filled chamber is provided and includes a first barrier layer, a second barrier layer, a foam structure, and a tensile member. The second barrier layer is secured to the first barrier layer to define an interior void between the first barrier layer and the second barrier layer. The interior void contains a predetermined volume of fluid. The foam structure and the tensile member are disposed within the interior void, whereby the tensile member includes a plurality of fibers extending in a first direction between the first barrier layer and the second barrier layer.

Sheets of a thin film material are attached to a carrier wafer. The carrier wafer and the attached sheets of thin film material are separated to form chiplet carriers. Each chiplet carrier includes a portion of the sheets of thin film material attached to a portion of the carrier wafer. The chiplet carriers are placed on an assembly surface in a random pattern. The chiplet carriers are arranged from the random pattern to a predetermined pattern, and the portions of the thin film material are transferred from the chiplet carriers in parallel to a target substrate.

The method comprises a pre-lamination step wherein a layer is placed in contact at least on one side with a lamination plate having a recess and the layer undergoes lamination such that a raised portion is formed on the layer; an assembling step wherein another layer is placed in contact with the layer, and the raised portion of the layer is at least partially placed in an opening of the other layer and a lamination step wherein said layers are laminated together.

Products having improved ply bonding, moldability and drape and methods for making those products are described. The methods comprise producing a multi-ply adhesively bonded product comprising a pattern of uniformly spaced microembossed elements with a bond area of less than about 0.020 inches/sq. inch.

Disclosed is a board core of an artificial board, the board core comprising a plurality of groups of core strip units (5), wherein each of the core strip units has a multi-layer structure in the lengthwise direction of a board core; each of the core strip units comprises multiple substrates; each of the substrates comprises a vertical pressure-bearing body (2) extending in the thickness direction of the board core, a horizontal pressure-bearing body (1) extending in the lengthwise direction of the board core, an oblique pulling structure (3) obliquely arranged with respect to the horizontal pressure-hearing body and the vertical pressure-hearing body, and a dual-horizontal pressure-bearing body (12) extending, in the lengthwise direction of the board core; and each of the core strip units is formed by means of sequentially arranging the multiple substrates, and different substrates form different core strip unit structures.

A multilayer material is disclosed which consists of polyethylene foam sandwiched between two external layers of high-density polyethylene. A two-step manufacturing process for forming such a multilayer material is disclosed, which consists of (1) thermal bonding of a roll stock of PE foam with a roll stock of HDPE/LDPE laminate, followed by cutting into composites, and (2) thermal bonding of two composites to form a multilayer material.