The purpose of the present invention is to provide a production method for a fiber reinforced resin sheet material, the method being capable of continuously and stably obtaining the fiber reinforced resin sheet material by using a fiber sheet material and a resin sheet material and melting the resin sheet material and impregnating or semi-impregnating the same into the fiber sheet material. The method includes the steps of: superimposing a fiber sheet material Ts and a resin sheet material Js, sandwiching these materials between conveying belts 7 and conveying the same; heating and pressing these materials between the heating rolls 1; and after the above steps, cooling and pressing the resulting material between cooling rolls 2 and thereby melting and impregnating or semi-impregnating the resin sheet material Js into the fiber sheet material Ts and thereby obtaining a fiber reinforced resin sheet material Ps, in which side end portions 8, 9 of the fiber sheet material Ts are arranged outside side end portions 10, 11 of the resin sheet material Js, respectively, and the fiber sheet material Ts and the resin sheet material Js are superimposed.

The present invention relates to a wind turbine blade comprising a lightning protection system with at least one tip end lightning receptor arranged at an outer surface of the blade and a down conductor extending within the blade. The blade comprises carbon fibre reinforced spar caps, wherein electrically conductive meshes are connected between the respective tip end of each spar cap to the tip end lightning conductor.

An improved sucker rod and the method of making is set forth herein. The improved sucker rod is used in well drilling to connect a pump present at a well casing to a motor and drive for a pump present at a well head. The method of making the improved sucker includes coating strands of sucker rod material with a mixture of epoxy and graphene platelets, bonding them together, and then extruding them through a pultrusion machine. The resulting improved sucker rod has increased flexibility, durability, corrosion resistance, and strength.

A method of and apparatus for extruding an article of uniform cross-section, the article including a thermoplastic material and at least one cable for inhibiting stretch of the article. The cable is supplied to a respective tube and is conveyed between upstream and downstream ends. The thermoplastic material may be supplied to the downstream end of the tube. The thermoplastic material is brought together with the cable to embed the cable within the thermoplastic material, thereby forming a composite extrudate. The tube is configured to at least hinder movement of loose windings of the cable from the downstream end towards the upstream end, which may prevent or at least reduce incidence of birdcaging.

A hollow body composite component is produced by a method using an injection mold, wherein a cavity of the injection mold is filled at least partially with a flowable material by injection of the flowable material, and a mandrel is driven through the flowable material to form a hollow body. Using the mandrel, at least one strip-shaped reinforcing element is introduced into a hollow body interior and is arranged on a surface of the hollow body facing the hollow body interior.

Various embodiments related to three dimensional printers, and reinforced filaments, and their methods of use are described. In one embodiment, a void free reinforced filament is fed into a conduit nozzle. The reinforced filament includes a core, which may be continuous or semi-continuous, and a matrix material surrounding the core. The reinforced filament is heated to a temperature greater than a melting temperature of the matrix material and less than a melting temperature of the core prior to drag the filament from the conduit nozzle.

A thermoplastic composite structure is produced by extruding a bead of composite material to a desired cross sectional shape. An extruder extrudes the polymer bead containing reinforcing fibers, using a low compression first extruder stage where the polymer is mixed and de-gassed, and a high compression second stage where the polymer is consolidated and extruded. The cross sectional profile of the polymer bead may be altered using a variable extruder gate.

A co-formed composite conveyor belt having a flat belt component, a plurality of reinforcing cords, a timing component, and a reinforced netting component, all co-formed together in one integral belt having a single pitch line. The timing component includes first and second adjacent rows of obliquely angled teeth. Additional, optional material layers can be co-formed therewith including for wear resistance and conveying functions. Co-forming apparatus and methods are disclosed.

A thermally conductive rope includes a plurality of tows of crystalline carbon fiber, a plurality of tows of additional fiber, and at least one of a thermoset and thermoplastic.

Provided are composite feedstock strips for additive manufacturing and methods of forming such strips. A strip may include continuous fibers extending parallel to the principal axis of the strip. The cross-sectional distribution of these continuous fibers may be uneven. Specifically, the fibers may be concentrated near the center of the strip and may be positioned away from at least some portions of the strip surface. A strip may be formed by laminating a layup of one or more fiber-containing plies and one or more of resin plies. The position of the different types of plies in the layup is used to control distribution of the fibers and other materials within the strip. The laminated sheet is slit into multiple strips in a direction parallel to the continuous fibers. The cross-sectional profile of the slit strips may be later changed without disturbing orientation of the continuous fibers.