Electromagnetic support tooling for composite part curing

What is claimed is: 1. A method comprising: providing an elastomeric housing having ferromagnetic components; operating one or more electro-magnetic coils in the elastomeric housing to generate a first magnetic field to repel the ferromagnetic components of the elastomeric housing from the one or more electro-magnetic coils and to generate a second magnetic field to attract the ferromagnetic components of the elastomeric housing to the one or more electro-magnetic coils, wherein when the ferromagnetic components of the elastomeric housing are repelled by the one or more electro-magnetic coils the elastomeric housing has a rigid surface state and when the ferromagnetic components of the elastomeric housing are attracted to the one or more electro-magnetic coils the elastomeric housing is collapsed; and providing a plurality of tool segments within the elastomeric housing and coupled in a sequential manner, wherein the one or more electro-magnetic coils comprise a plurality of electro-magnetic coils within the plurality of tool segments, and wherein the plurality of tool segments are positioned inside the elastomeric housing; and providing joint linkages coupling each adjacent tool segment of the plurality of tool segments to each other, wherein the joint linkages enable flexibility of the plurality of tool segments and provide separation between each of the plurality of tool segments. 2. The method of claim 1 , further comprising: providing a plurality of power cables positioned through each of the plurality of tool segments and attached to respective joint linkages. 3. The method of claim 1 , further comprising: inserting the elastomeric housing into an internal cavity of a composite part being cured; operating the one or more electro-magnetic coils in a progression through more than one energized cycle during curing of the composite part. 4. The method of claim 1 , further comprising: inserting the elastomeric housing into an internal cavity of a composite part; operating the one or more electro-magnetic coils such that the elastomeric housing has the rigid surface state. 5. The method of claim 1 , further comprising: inserting the elastomeric housing into an internal cavity of a composite part being cured; operating the one or more electro-magnetic coils such that the elastomeric housing is collapsed to be removed from the composite part after curing the composite part. 6. The method of claim 1 , wherein the one or more electro-magnetic coils are operated to generate the first magnetic field by receiving a first current, and wherein the one or more electro-magnetic coils are operated to generate the second magnetic field by receiving a second current that is a direction opposite the first current. 7. The method of claim 1 , further comprising: inserting the elastomeric housing into an internal cavity of a composite part being cured; operating the one or more electro-magnetic coils in the elastomeric housing to generate the first magnetic field to repel the ferromagnetic components of the elastomeric housing by the one or more electro-magnetic coils so as to cause the elastomeric housing to have the rigid surface state; subsequently operating the one or more electro-magnetic coils in the elastomeric housing to generate the second magnetic field to attract the ferromagnetic components of the elastomeric housing to the one or more electro-magnetic coils so as to cause the elastomeric housing to collapse after cure of the composite part; and removing the elastomeric housing from the internal cavity of the composite part. 8. The method of claim 1 , wherein the ferromagnetic components are adhesively fixed on an interior surface of at least one of a plurality of walls of the elastomeric housing using an epoxy. 9. The method of claim 1 , wherein when the ferromagnetic components of the elastomeric housing are attracted to the one or more electro-magnetic coils, an interior surface of a wall of the elastomeric housing is drawn inward. 10. The method of claim 1 , wherein the ferromagnetic components are embedded within at least one of a plurality of walls of the elastomeric housing. 11. The method of claim 1 , wherein the ferromagnetic components are positioned on an interior surface of at least one of a plurality of walls of the elastomeric housing. 12. The method of claim 1 , wherein the ferromagnetic components are positioned on an exterior surface of at least one of a plurality of walls of the elastomeric housing. 13. A mandrel comprising: an elastomeric housing having a polarized magnetic material; one or more electro-magnetic coils positioned within the elastomeric housing and operable to generate a first magnetic field to repel the polarized magnetic material of the elastomeric housing from the one or more electro-magnetic coils and to generate a second magnetic field to attract the polarized magnetic material of the elastomeric housing to the one or more electro-magnetic coils, wherein when the polarized magnetic material of the elastomeric housing is repelled by the one or more electro-magnetic coils the elastomeric housing has a first volume and when the polarized magnetic material of the elastomeric housing is attracted to the one or more electro-magnetic coils the elastomeric housing has a second volume that is smaller than the first volume; a plurality of tool segments within the elastomeric housing and coupled in a sequential manner, wherein the one or more electro-magnetic coils comprise a plurality of electro-magnetic coils within the plurality of tool segments; and joint linkages coupling each adjacent tool segment of the plurality of tool segments to each other, wherein the joint linkages enable flexibility of the plurality of tool segments and provide separation between each of the plurality of tool segments. 14. The mandrel of claim 13 , wherein the polarized magnetic material comprises ferromagnetic components, and wherein the elastomeric housing comprises a mixture of ferromagnetic components and rubber. 15. The mandrel of claim 13 , wherein the polarized magnetic material is positioned on an interior wall or an exterior surface of the elastomeric housing. 16. The mandrel of claim 13 , wherein the polarized magnetic material is positioned laterally along the elastomeric housing so as to be linearly perpendicular to a centerline of the elastomeric housing or longitudinally along the elastomeric housing so as to be linearly parallel to the centerline of the elastomeric housing. 17. The mandrel of claim 13 , wherein the polarized magnetic material is adhesively fixed on an interior surface of at least one of a plurality of walls of the elastomeric housing using an epoxy. 18. The mandrel of claim 13 , further comprising: a plurality of power cables positioned through each of the plurality of tool segments and attached to respective joint linkages. 19. The mandrel of claim 13 , wherein the one or more electro-magnetic coils are operated to generate the first magnetic field by receiving a first current, and wherein the one or more electro-magnetic coils are operated to generate the second magnetic field by receiving a second current that is a direction opposite the first current. 20. The mandrel of claim 13 , wherein when the polarized magnetic material of the elastomeric housing is attracted to the one or more electro-magnetic coils, an interior surface of a wall of the elastomeric housing is drawn inward.