Rotational tooling apparatus for layup and cure of composite stringers

What is claimed is: 1. A tooling apparatus, comprising: a pair of elongated tooling dies independently rotatable about a common central axis; each tooling die having a layup surface including a web layup surface and at least one flange layup surface oriented non-parallel to the web layup surface and configured to receive at least one composite ply to form a stringer layup half having a web and at least one flange; the tooling dies being rotatable into side-by-side relation causing the webs of the stringer layup halves to be positioned in back-to-back mating contact with one another; and a tool seal extending along a lengthwise direction of the tooling dies and configured to be compressed between the tooling dies when the tooling dies are rotated into side-by-side relation to each other. 2. The tooling apparatus of claim 1 , wherein: the layup surface of at least one of the tooling dies includes the web layup surface and a single flange layup surface for respectively laying up a web and a single flange of a stringer layup half having an L-section. 3. The tooling apparatus of claim 1 , wherein: the layup surface of at least one of the tooling dies includes the web layup surface interconnecting an opposing pair of flange layup surfaces for respectively laying up a web and a pair of flanges of a stringer layup half having a C-section. 4. The tooling apparatus of claim 1 , further including: a compression device configured to force the tooling dies toward one another when the webs are in back-to-back contact with one another. 5. The tooling apparatus of claim 1 , further including: an end plate mounted on each one of opposing tooling die ends of each one of the tooling dies. 6. The tooling apparatus of claim 1 , further including: a vacuum plate configured to releasably retain a base charge during installation of the base charge onto the flanges of the back-to-back stringer layup halves. 7. The tooling apparatus of claim 1 , further including: at least one support arm rotatable about the central axis and supporting a tooling die; and a counterbalance mounted on an end of the at least one of the support arm, the counterbalance located on a side of the central axis opposite the layup surface and configured to balance a mass of the tooling die. 8. The tooling apparatus of claim 1 , wherein: at least one of the tooling dies has a rotational mechanism for rotating the tooling die independent of the opposing tooling die, the rotational mechanism comprising: a motor; a shaft extending at least partially along a length of each tooling die and having shaft teeth; and a radial gear fixedly coupled to a support arm supporting a tooling die and, the radial gear having gear teeth engaged to the shaft teeth such that actuation of the motor causes rotation of the support arm for angular positioning of the tooling dies relative to one another. 9. A tooling apparatus, comprising: a pair of elongated tooling dies independently rotatable about a common central axle; each one of the tooling dies being supported by at least one support arm rotatably coupled to the central axle, each tooling die having a layup surface including a web layup surface and at least one flange layup surface oriented non-parallel to the web layup surface and configured to receive at least one composite ply to form a stringer layup half having a web and at least one flange interconnected by a bend radius; tooling dies being rotatable about the central axis toward one another into indexed side-by-side relation causing the webs of the stringer layup halves to be positioned in back-to-back mating contact with one another and the flanges of the stringer layup halves pointing in opposite directions such that the stringer layup halves collectively form a composite stringer layup; and a tool seal extending along a lengthwise direction of the tooling dies and configured to be compressed between the tooling dies when the tooling dies are rotated into side-by-side relation to each other. 10. The tooling apparatus of claim 1 , wherein: the tool seal is held in fixed position relative to at least one of the tooling dies. 11. The tooling apparatus of claim 1 , further including: a seal mounting block coupled to the web layup surface of one of the tooling dies and extending along a lengthwise direction of at least one of the tooling dies, the seal mounting block having a seal groove configured to receive the tool seal. 12. A method of manufacturing a composite stringer, comprising the steps of: laying up one or more composite plies on a layup surface of each one of a pair of elongated tooling dies rotatable about a common central axis and extending along a lengthwise direction parallel to the central axis, the layup surface of the tooling dies including a web layup surface and at least one flange layup surface oriented non-parallel to the web layup surface and configured to receive at least one composite ply to form a stringer layup half having a web and at least one flange; rotating the tooling dies about the central axis toward one another into side-by-side relation until the webs of the stringer layup halves are in back-to-back mating contact with one another and the flanges of the stringer layup halves point in opposite directions such that the stringer layup halves collectively form a composite stringer layup; and sealing, using a tool seal extending along a lengthwise direction of the tooling dies by compressing the tool seal between the tooling dies, a gap between the web layup surfaces of the tooling dies when the tooling dies are rotated into side-by-side relation. 13. The method of claim 12 , wherein the step of laying up one or more composite plies includes: laying up one or more prepreg composite plies. 14. The method of claim 12 , further including: sealing the gap between the web layup surfaces of the tooling dies together when the webs are in back-to-back contact with each other. 15. The method of claim 12 , wherein a compression step is the step of compressing the webs together includes: forcing, using a compression device, the side-by-side tooling dies toward one another when the webs are in back-to-back contact with one another to compress the webs together. 16. The method of claim 15 , wherein the compression device is a compression locking pin. 17. The method of claim 12 , further including: vacuum bagging the composite stringer layup to the layup surfaces of the side-by-side tooling dies. 18. The method of claim 17 , wherein the step of vacuum bagging the composite stringer layup to the layup surfaces comprises: sealing opposing ends of the vacuum bag to the tool seal extending lengthwise between the web layup surfaces. 19. The method of claim 18 , wherein the step of sealing opposing ends of the vacuum bag to the tool seal includes: sealing opposing ends of the vacuum bag to ends plates located at each one of tooling die ends of each one of the tooling dies. 20. The method of claim 12 , further including: rotating the tooling dies away from one another to a layup position wherein the web layup surface of at least one of the tooling dies is oriented non-parallel to a vertical centerline. 21. The method of claim 12 , further including: balancing at least a portion of a mass of at least one of the tooling dies using a counterbalance mounted on an end of a support arm, the counterbalance located on a side of the central axis opposite the layup surface. 22. The method o