Preforms for open structured (lattice) composite tubular members manufactured from large (i.e. high filament count) prepreg yarns on a conventional maypole braiding machine, and subsequently cured to produce fiber reinforced composites of high strength and light weight.

Preforms for open structured (lattice) composite tubular members manufactured from large (i.e. high filament count) prepreg yarns on a conventional maypole braiding machine, and subsequently cured to produce fiber reinforced composites of high strength and light weight.

According to one implementation, a prepreg lamination apparatus includes first and second rollers, a table, and a feed structure. The first roller sends out a first prepreg tape which is a part of material of an FRP. The second roller sends out a second prepreg tape which is another part of the material of the FRP. The table is for laminating the first and second prepreg tapes directly or indirectly. The feed structure is adapted to feed out the first and second prepreg tapes in a feeding direction by moving the first and second rollers relatively to the table while performing at least one of movement of the first roller relatively to the second roller, and rotation of at least one of the first and second rollers relatively to the table around an axis which is not parallel to each of rotation axes of the first and second rollers.

A reinforcement sheet has a composite layer including fibres and a polymer A and a coating layer including polymer B, each polymer having at least 65 mol % of a repeat unit of formula:

##STR00001##

wherein for each polymer A and B, t1, and w1 independently represent 0 or 1 and v1 represents 0, 1 or 2. A method of forming the reinforcement sheet is also disclosed, in addition to a method for forming an article comprising a laminate of the reinforcement sheets and the article comprising such a laminate. The repeat unit may be ether-ether-ketone.

A thermal insulated composite wall panel for use in insulated trailers, containers and insulated compartments, including a first liner panel, a second liner panel having a layer of fibers and at least one structural polymer resin layer disposed coplanar to and bonded with the layer of fibers, thereby forming a laminate liner panel, and an insulated core layer disposed intermediate to and bonded with the first and the second liner panels. The layer of fibers is adjacent the insulated core layer and is lofted prior to being bonded to the insulated core layer.

A method of manufacturing a radius filler may include providing a plurality of fibers, braiding the plurality of fibers into a braided preform, shaping the braided preform into a braided radius filler, and cutting the braided radius filler to a desired length.

Disclosed is a method for producing components from fiber-reinforced thermoplastic. The method involves manufacturing a multitude of semifinished products, each of which includes a plurality of impregnated fabric layers that are joined to one another only locally, as well as a frame structure having at least one cutout. The semifinished products are consolidated using a consolidation device, an inlay element being placed in each cutout before the semifinished products are consolidated.

A process arrangement for producing a fiber-reinforced plastic component comprises a stacking station in which pre-impregnated textile semi-finished products can be stacked, and an assembly station in which the semi-finished products can be further processed to form the layered packet. The forming of the fiber-reinforced plastic component is subsequently carried out in the press. According to the invention, the stacking station is assigned at least one transport and/or storage container in which the semi-finished products can be stored air-tight, light-proof, and/or moisture-tight shielding and can be transported to the assembly station.

A process arrangement for producing a fiber-reinforced plastic component comprises a stacking station in which pre-impregnated textile semi-finished products can be stacked, and an assembly station in which the semi-finished products can be further processed to form the layered packet. The forming of the fiber-reinforced plastic component is subsequently carried out in the press. According to the invention, the stacking station is assigned at least one transport and/or storage container in which the semi-finished products can be stored air-tight, light-proof, and/or moisture-tight shielding and can be transported to the assembly station.

A method for manufacturing a reinforcing fiber base material includes a placement step of placing a sheet-shaped reinforcing fiber material piece, in which reinforcing fibers are arranged so as to extend in one direction and bound together with a thermoplastic resin, on a table so that the orientation direction of the reinforcing fibers is at an angle with respect to a longitudinal direction of the reinforcing fiber base material, and a welding step in which, in a state in which a previously placed reinforcing fiber material piece and the reinforcing fiber material piece placed subsequent thereto are abutted against each other in the longitudinal direction, adjoining edges of the two reinforcing fiber material pieces are welded together to form a continuous sheet shape.