Method for forming and applying composite layups having complex geometries

What is claimed: 1. An apparatus for applying composite layups on a contoured substrate, comprising: a tool adapted to be mounted on a manipulator for moving the tool into proximity to the substrate, the tool including a contoured tool face substantially matching the contour of the substrate; a bladder on the tool for compacting a layup onto the substrate, the bladder covering the tool face and adapted to have a composite layup placed thereon; a vacuum bag covering both the tool and the bladder; and means for controlling the bladder and the vacuum bag, the means for controlling including a pressure source, a vacuum source, control valves, and a controller for selectively pressurizing and depressurizing the bladder and the vacuum bag using the pressure source and the vacuum source together with the control valves in order to separately pressurize and deflate the bladder and the vacuum bag. 2. An apparatus for forming and applying composite layups on a part having a surface that is multi-contoured, comprising: a tool having a face that is multi-contoured to substantially match contours of the surface; a bladder on the tool covering and conforming to the contours of the face, the bladder being adapted to have a layup placed thereon and pressurized to compact the layup against the surface; a vacuum bag covering both the bladder and the tool; and a pressure source, a vacuum source, control valves, and a controller for selectively pressurizing and depressurizing the bladder and the vacuum bag using the pressure source and the vacuum source together with the control valves in order to separately pressurize and deflate the bladder and the vacuum bag; a manipulator for manipulating the tool into proximity to the part and placing the layup on the surface, wherein the controller also controls the manipulator. 3. The apparatus of claim 2 , wherein the tool is a structural foam. 4. An apparatus for forming and applying composite layups on a part having a multi-contoured surface, comprising: a tool having a multi-contoured face substantially matching the contours of the multi-contoured surface; a bag and a bladder on the tool, the bag covering both the bladder and the tool; means for separately inflating and deflating each of the bag and the bladder, including a valve system having control valves for selectively coupling a pressure source and a vacuum source with the bag and the bladder; a robotic manipulator having the tool mounted thereon for manipulating the tool; an automatic composite fiber placement machine including a fiber placement head for forming a multi-ply composite layup on the multi-contoured face; a locator system for generating a set of location data that locates the fiber placement head, the multi-contoured face and the multi-contoured surface relative to each other on a common spatial reference system; control means for controlling operation of the manipulator, the automatic fiber placement machine, the bag, and the bladder, based on the location data. 5. The apparatus of claim 4 , wherein the bladder covers the multi-contoured face, the bladder being adapted to be pressurized to force the layup against the part surface. 6. The apparatus of claim 5 , wherein the bladder is disposed between the multi-contoured face and the bag for applying compaction pressure to the layup through the bladder. 7. An apparatus for forming and applying composite doublers on a composite aircraft part having a multi-contoured surface, comprising: a structural foam tool having a multi-contoured face substantially matching contours of the multi-contoured surface; a robotic manipulator for manipulating the structural foam tool; a mounting adaptor for releaseably mounting the structural foam tool on the robotic manipulator and allowing change-out of the structural foam tool on the robotic manipulator; an automatic composite fiber placement machine including a fiber placement head for forming a multi-ply composite layup on the multi-contoured face; a locator system for generating a set of location data that locates the fiber placement head, the multi-contoured face and the multi-contoured surface in a common spatial reference system; an inflatable bag covering the multi-contoured face and sealed to the structural foam tool for compacting the multi-ply composite layup against the multi-contoured surface; an inflatable bladder on the multi-contoured face and inside the inflatable bag for compacting the multi-ply composite layup against the multi-contoured surface; a pressure source; a vacuum source; means for separately inflating and deflating each of the inflatable bag and the inflatable bladder, including a valve system for selectively coupling each of the pressure source and the vacuum source with the inflatable bag and the inflatable bladder; and a controller for coordinating and controlling operation of the robotic manipulator, the automatic fiber placement machine, and the valve system.