A method and apparatus for a reinforced bladder are provided. The reinforced bladder comprises a bladder with a cross-sectional shape formed of a polymeric material and a number of reinforcements. Each of the number of reinforcements covers only a portion of the cross-sectional shape such that part of the cross-sectional shape remains uncovered by the number of reinforcements.

Systems and methods are provided for enhancing edge breathers for composite manufacturing. One exemplary embodiment is an apparatus that includes an edge breather to facilitate manufacturing of a composite part. The edge breather includes a body, ridges disposed along a length of the body that each define an arc which is perpendicular to a lengthwise axis of the body, and openings disposed along the body that enable air to enter a hollow interior that runs along the length of the body. The arcs defined by the ridges resist compressive loads applied to the edge breather and prevent the hollow interior from collapsing under pressure applied to the edge breather by a vacuum bag during manufacturing of the composite part.

Devices, systems, and methods of improving heat transfer between a composite wind turbine blade surface are provided to reduce cure time. The assembly includes molds having heating wires disposed proximate the mold surface for delivering heat to the composite blade during layup and/or resin cure. Additionally, the vacuum bag disposed on top of the composite part includes a plurality of fluid channels for distributing a thermal fluid (e.g. heated/cooled water, air or oil) across the composite surface (opposite the mold surface).

A composite part manufacturing method comprising the following consecutive steps: providing a manufacturing tooling, providing a composite laminate on the manufacturing tooling, providing a release film covering the composite laminate, providing a breather fabric covering the release film, providing a vacuum bag film covering the composite laminate, the release film and the breather fabric, sealing the vacuum bag film to the manufacturing tooling, curing the composite laminate, unsealing the vacuum bag film from the manufacturing tooling, removing the vacuum bag film, removing the breather fabric, inspecting the breather fabric to detect resin residues, removing any detected resin residues from the breather fabric, transporting the removed breather fabric to a manufacturing process of another composite part.

A core (20) and a bag (22, 24) are provided which are used to shape an FRP structure (10; 30). The bag (22, 24) has a core bag section (24) which covers the outer circumference of the core (20), and a coverture bag section (22) which covers a plurality of fiber components (12, 14; 12, 14, 16).

A tensioning system that can be used with a heater blanket and a vacuum bag for heating a workpiece can include a tensioner including at least one flexible rod. The tensioner can further include an end cap positioned on one or both ends of the flexible rod. The tensioner can be inserted through one or more sleeves attached to the vacuum bag, and each end of the flexible rod can be positioned within a pocket and thereby attached to the vacuum bag. In one implementation, the flexible rod can be rotated relative to the one or more end caps to decrease or increase a length of the tensioner, and the length of the tensioner is thereby adjustable. The tension applied to the vacuum bag can mitigate sealing of a seal of the vacuum bag with a layup mandrel.

A method is provided for facilitating a vacuum bagging operation during fabrication of a composite laminate. The method comprises applying a vacuum bag over a composite part to fabricate the composite laminate from the composite part. The method also comprises drawing a vacuum in the vacuum bag, and monitoring one or more portions of the vacuum bag for strain within the vacuum bag when the vacuum is drawn. The method further comprises manipulating the vacuum bag to even out strain within the vacuum bag.

A pliable structure includes a first impermeable layer, a second impermeable layer opposed from the first impermeable layer to at least partially define an internal volume between the first impermeable layer and the second impermeable layer, and a flow media layer disposed in the internal volume.

A system for manufacturing a thermoplastic part from a blank part having a first moulding member and a second moulding member which are configured to cooperate together. A first heating body configured to heat the first moulding member and conductively heat the blank part. Two thermal insulation members are configured to cooperatively define a closed cavity in which at least the moulding members and the first heating body are arranged. A casing defining an internal volume in which at least the moulding members, the first heating body and the thermal insulation members are arranged, and a suction member is configured to lower the internal pressure in the internal volume to compress the preform part between the moulding members.

A method of removing a vacuum bag from a composite mold. Removable strips are placed around the perimeter of the component parts and across the parts to create natural break points in the consumable materials used during manufacture of a composite product, e.g. wind turbine blade. The vacuum bag, and other consumable layers, are placed over the removable strip such that when the strips are pulled, the strip tears, in a controlled and complete manner, through each layer of consumables. This eliminates the need to use a knife/scissor to remove the finished product, thereby avoiding risk of injury.