A method for manufacturing a panel made of composite material incorporating a lightning protection arrangement which comprises strips with a conductive layer. The method comprises a step of laying the strips in an automated manner, the strips having a width of less than 20 mm and being distributed in a first set of mutually parallel strips that are laid in a first laying direction and a second set of mutually parallel strips that are laid in a second laying direction that intersects the first laying direction. A panel made of composite material manufactured by way of this method is also disclosed.

An embedded light source in a composite panel. A first electrode and a second electrode are associated with a first layer of material. A light source is positioned in electrical communication with the first electrode and the second electrode. An assembly comprising the first layer of material, the first electrode, the second electrode, and the light source is processed to form a multilayer panel with an embedded light source.

A method is provided for manufacturing during which a first duct section is formed with a tubular first sidewall. A first opening extends through the tubular first sidewall. The forming of the first duct section includes disposing a first woven fiber sleeve over a first mandrel and disposing a polymer material with the first woven fiber sleeve. A second duct section is disposed with a tubular second sidewall. The forming of the second duct section includes disposing a second woven fiber sleeve over a second mandrel and disposing the polymer material with the second woven fiber sleeve. The second duct section is arranged with the first duct section. The second duct section engages the tubular first sidewall. The tubular second sidewall is located at and extends circumferentially around the first opening. A duct structure is formed by attaching the second duct section to the first duct section.

A method is provided for manufacturing. During this method, a first woven fiber sleeve is disposed over a first mandrel to provide a first overbraided mandrel. The first woven fiber sleeve is wrapped circumferentially around the first mandrel. An opening is formed through a side of the first woven fiber sleeve. A second woven fiber sleeve is disposed over a second mandrel to provide a second overbraided mandrel. The second woven fiber sleeve is wrapped circumferentially around the second mandrel. The second overbraided mandrel is arranged with the first overbraided mandrel. The second woven fiber sleeve engages the side of the first woven fiber sleeve. A second overbraid first end is disposed at and extends circumferentially around the opening. A polymer material is disposed with the first woven fiber sleeve and the second woven fiber sleeve to provide a duct structure.

A shield cap for protecting an electronic component includes a cap member having a side wall portion and a ceiling portion, a conductive film formed on the cap member such that the conductive film is formed to shield electromagnetic waves, and a metal layer formed on a portion of the side wall portion such that the metal layer is interposed between the conductive film and the portion of the side wall portion. The side wall and ceiling portions are forming an accommodation space to accommodate an electronic component, and the metal layer is formed on a surface of the side wall portion on the opposite side of a surface of the side wall portion facing the ceiling portion and interposed between the conductive film and the side wall portion.

A spar cap for a rotor blade of a wind power installation, having a longitudinal extent from a first end to a second end, a transverse extent orthogonal to the longitudinal extent, and a thickness orthogonal to the longitudinal extent and to the transverse extent. A method for producing a spar cap as mentioned at the outset. The spar cap has a longitudinal extent from a first end to a second end, a transverse extent orthogonal to the longitudinal extent, and a thickness orthogonal to the longitudinal extent and to the transverse extent, at least two tiers of a first fiber composite material, and at least one tier of a second fiber composite material, wherein the first fiber composite material has a matrix material and/or fibers which is/are different from that/those of the second fiber composite material, the second fiber composite material is disposed in a portion adjacent to the second end, in the direction of the thickness between the at least two tiers of the first fiber composite material, and the at least one tier of the second fiber composite material terminates ahead of the second end.

Semi-finished product made from composite material comprising a thermoplastic or thermosetting matrix and reinforcement fillers. The semi-finished product comprises an electromagnetic shielding film positioned in the thickness of the semi-finished product, the electromagnetic shielding film comprising holes.

Provided is a electroconductive resin body formed of fiber-reinforced resin including resin and a plurality of fiber strings formed of at least one selected from carbon fiber, high-strength fiber and glass fiber, the resin impregnating between the fiber strings, wherein the fiber strings are metal-plated. In the vehicle grounding structure, while the electroconductive resin body is used as a vehicle body, the minus terminals of vehicle-mounted devices VD and of a vehicle battery B are electrically connected to locations in the electroconductive resin body that have the metal-plated fiber strings arranged therein.

A structure formed from composite material and method of forming a structure composite material is disclosed in which one or more metal layers are disposed on the composite material.

A multi-functional composite system generally comprises a core, a plurality of structural composite fiber layers, a matrix material, a connector configured to interface with one or more electrical devices and a composite conductor assembly, the composite conductor assembly having one or more conductors disposed between two or more insulating layers.