An assembly for forming a gas turbine engine according to an example of the present disclosure includes, among other things, a layup tool including a main body extending along a longitudinal axis and a flange extending radially from the main body, the flange defining an edge face slopes towards the main body to an axial face. At least one compression tool has a tool body having a first tool section and a second tool section extending transversely from the first tool section. The first tool section is translatable along a retention member in a first direction substantially perpendicular to the edge face such that relative movement causes the second tool section to apply a first compressive force on a composite article trapped between the axial face of the flange and the second tool section. A method of forming a gas turbine engine component is also disclosed.

A molding jig for molding a laminate, which includes reinforced fiber sheets laminated on each other, extends in the length direction, and has a cross-sectional shape having a curved portion in a cross section obtained by cutting the laminate on a plane orthogonal to the length direction, into a three-dimensional shape having a bent portion in the length direction. The molding jig includes a female die for forming the bent portion, a male die for engaging with the female die with the laminate therebetween for forming the bent portion, and a stretchable supporting member between the female die and the laminate. The laminate comes in contact with the male die on both length-direction sides of the molded bent portion, and the supporting member is over a region including the female-side molding surface.

A molding jig for molding a laminate, which includes reinforced fiber sheets laminated on each other, extends in the length direction, and has a cross-sectional shape having a curved portion in a cross section obtained by cutting the laminate on a plane orthogonal to the length direction, into a three-dimensional shape having a bent portion in the length direction. The molding jig includes a female die for forming the bent portion, a male die for engaging with the female die with the laminate therebetween for forming the bent portion, and a stretchable supporting member between the female die and the laminate. The laminate comes in contact with the male die on both length-direction sides of the molded bent portion, and the supporting member is over a region including the female-side molding surface.

Thermoelastic constants of cellular and lattice materials are tailored with pre-stress using four configurations. First, a tube-core composite uses lightweight materials as a core. A screw cap is used to adjust the pressure on the lightweight material core, tailoring the thermoelastic constants of the overall composite. Second, pre-tensioned fibers or metal wires are embedded in the lightweight material during the fabrication and curing process to form a composite. After the lightweight material is solidified, the pre-tension is released from the frame and transferred to the composite. Third, the lightweight material is fabricated in a mold with fiber or wire reinforcements, where the ends extend beyond the lightweight material and are coupled to bolts. Post-tension is applied by adjusting the bolts. Fourth, the ends of the fiber are coupled to a spool. Post-tension is applied to the fibers or wires by turning the spool using a single screw bolt.

Thermoelastic constants of cellular and lattice materials are tailored with pre-stress using four configurations. First, a tube-core composite uses lightweight materials as a core. A screw cap is used to adjust the pressure on the lightweight material core, tailoring the thermoelastic constants of the overall composite. Second, pre-tensioned fibers or metal wires are embedded in the lightweight material during the fabrication and curing process to form a composite. After the lightweight material is solidified, the pre-tension is released from the frame and transferred to the composite. Third, the lightweight material is fabricated in a mold with fiber or wire reinforcements, where the ends extend beyond the lightweight material and are coupled to bolts. Post-tension is applied by adjusting the bolts. Fourth, the ends of the fiber are coupled to a spool. Post-tension is applied to the fibers or wires by turning the spool using a single screw bolt.

A composite forming apparatus includes an end effector and a forming feature that is coupled to the end effector. The end effector moves the forming feature relative to a forming tool to form a composite ply over a forming surface of the forming tool or over previously formed composite material on the forming surface of the forming tool. The composite forming apparatus further includes a positioning member engaged with the forming feature. The engagement between the positioning member and the forming feature facilitates a position between the forming feature and the composite ply to promote uniform application of compaction force over the forming surface of the forming tool.

A method for forming a composite part includes positioning a composite ply over a forming surface of a forming tool, moving a forming feature into engagement with the composite ply to yield a formed ply, and, after the moving, securing the formed ply relative to the forming tool.

A composite forming apparatus includes an end effector, a forming feature that is coupled to the end effector, and a heating element that is coupled to the forming feature to heat the forming feature. The end effector moves the forming feature relative to a composite ply to form the composite ply over a forming tool or over a prior formed composite ply. The forming feature heats the composite ply via conduction.

A composite forming apparatus includes an end effector, a forming feature, and a non-contact heater. The forming feature is coupled to the end effector. The end effector moves the forming feature relative to a composite ply to form the composite ply over a forming tool or a prior formed composite ply. The non-contact heater heats to a portion of the composite ply before the portion of the composite ply is formed over the forming tool or the prior formed composite ply.

A lamination head for laying up a composite laminate includes a material supply drum supporting roll of layup material backed by a backing layer, a first and second separation device respectively having a first and second horn, and a first and second compaction device. When the first separation device is extended, the first horn is in close proximity to the first compaction device, causing a layup material to separate from the backing layer and move underneath the first compaction device as the lamination head moves along a first direction of travel. When the second separation device is extended, the second horn is in close proximity to the second compaction device, causing the layup material to separate from the backing layer and move underneath the second compaction device as the lamination head moves along a second direction of travel opposite the first direction of travel.