A parison separation device (30) according to an embodiment includes a cutter (31) with a cutting edge (35), the cutting edge (35) extending in a one direction and facing upward, and a block (33), the cutter being attached to an upper part of the block (33), inclined surfaces (37) being formed on both sides of the block (33) in a thickness direction of the cutting edge (35), each of the inclined surfaces (37) including a component that is inclined increasingly downward as it gets closer to one direction side end, in which the parison separation device (30) is disposed on a discharging direction side of a discharging port of a parison and configured to cut the parison discharged from the discharging port.

A method for use in forming a composite structure that includes dispensing a first sheet of composite material, cutting the first sheet of composite material to form one of a plurality of plies of composite material, and providing the plurality of plies of composite material to a forming tool one at a time in a ply laydown sequence. A first sequential ply in the ply laydown sequence is provided, and then a second sequential ply in the ply laydown sequence is automatically provided after the first sequential ply has been provided.

A rodstock barrel drive having a first and second roller gears, each having a toothed section and a gripping surface section, such that the teeth of the roller gears intermesh, causing rotation of one of roller gear to rotate the other roller gear in the opposite direction, so as to draw a rodstock through a space between the gripping surfaces of the pair of roller gears, a ring gear which engages with one of the pair of roller gears, a drive gear which engages with the ring gear, and one or more idler gears which engage with the ring gear, all within a housing, the drive gear being connected to, and rotated by, a motor, which causes the rodstock to be drawn through the roller gears, wherein all the gears are all positioned within, and oriented parallel to, a common plane.

A rodstock barrel drive having a first and second roller gears, each having a toothed section and a gripping surface section, such that the teeth of the roller gears intermesh, causing rotation of one of roller gear to rotate the other roller gear in the opposite direction, so as to draw a rodstock through a space between the gripping surfaces of the pair of roller gears, a ring gear which engages with one of the pair of roller gears, a drive gear which engages with the ring gear, and one or more idler gears which engage with the ring gear, all within a housing, the drive gear being connected to, and rotated by, a motor, which causes the rodstock to be drawn through the roller gears, wherein all the gears are all positioned within, and oriented parallel to, a common plane.

A manufacturing system includes a stator base, a plurality of movers, one or more end effectors, and a controller. The stator base has a planar stator surface covering an array of electrical coils configured to generate an electromagnetic field. The movers each contain multiple permanent magnets configured to cause the movers to levitate and move relative to the stator surface in response to the electromagnetic field. The end effectors are coupled to the movers, and each end effector perform one or more functions in relation to a material sheet. The controller activates the electrical coils in a manner causing independent, coordinated movement of the movers over the stator surface, and causing the end effectors to engage with and operate on the material sheet.

Systems and methods for manufacturing a composite member. The system and methods are configured to move different types of composite plies from different supply stations. The composite plies are moved along a conveyance member and then with a transfer station to a forming tool. One or more forming members form the composite plies onto the forming tool.

Systems and methods for manufacturing a composite member. The system and methods are configured to move different types of composite plies from different supply stations. The composite plies are moved along a conveyance member and then with a transfer station to a forming tool. One or more forming members form the composite plies onto the forming tool.

A convey device, which conveys an insert member into a die, includes a holding device configured to hold the insert member in an attitude in which a major surface of the insert member is in a substantially gravitational direction; a convey mechanism configured to convey the insert member to the die, while the insert member is being held in the attitude by the holding device; and a heating device configured to heat the insert member. The insert member can be heated by the heating device before the insert member is disposed in the die.

A laying die, for picking up and laying of substrates, comprising an elastically deformable substrate receiving structure providing an engagement surface for releasable receiving of substrates, an attaching element comprising a gas channel for providing positively or negatively pressurized gas for picking up and blowing off the substrates, and a carrier body made from elastically deformable material and sandwiched between the substrate receiving structure and the attaching element which is arranged to distribute the positively or negatively pressurized gas over the carrier body. The carrier body comprises breakthroughs to transfer the pressurized gas from the attaching element to the substrate receiving structure that comprises an elastically deformable distribution plate to distribute the positively or negatively pressurized gas over the engagement surface. Also, a laying device which changes the position and/or orientation of substrates to predetermined values can comprise the laying die and a method for manufacturing the laying die.

A laying die, for picking up and laying of substrates, comprising an elastically deformable substrate receiving structure providing an engagement surface for releasable receiving of substrates, an attaching element comprising a gas channel for providing positively or negatively pressurized gas for picking up and blowing off the substrates, and a carrier body made from elastically deformable material and sandwiched between the substrate receiving structure and the attaching element which is arranged to distribute the positively or negatively pressurized gas over the carrier body. The carrier body comprises breakthroughs to transfer the pressurized gas from the attaching element to the substrate receiving structure that comprises an elastically deformable distribution plate to distribute the positively or negatively pressurized gas over the engagement surface. Also, a laying device which changes the position and/or orientation of substrates to predetermined values can comprise the laying die and a method for manufacturing the laying die.