System for manufacturing monolithic structures using expanding internal tools

What is claimed is: 1. A tooling system, comprising: an outer mold line (OML) tool having an OML tool surface; an inner mold line (IML) tool having an IML tool surface and being receivable within the OML tool, at least a portion of the IML tool being formed of a homogeneous and substantially rigid expandable material that expands when heated to apply an internal compaction pressure to a composite assembly positioned between the OML tool surface and the IML tool surface when the expandable material is heated; and a vacuum bag sealingly covering the IML tool and having one or more pleats configured to accommodate expansion of the expandable material to assist in applying the internal compaction pressure to confined spaces, corners, or relatively small radii in the composite assembly in response to a vacuum pressure drawn on a space between the OML tool surface and the vacuum bag covering the IML tool. 2. The tooling system of claim 1 , wherein: the composite assembly includes an internal component; a plurality of IML tools are receivable within the OML tool; and at least one pair of the IML tools sandwiching the internal component therebetween for applying an internal compaction pressure to the internal component upon expansion of the expandable material. 3. The tooling system of claim 2 , wherein: the internal component comprises a composite layup. 4. The tooling system of claim 1 , wherein: the expandable material has a rate of expansion (CTE) that when contained can generate internal compaction pressure of at least approximately 85 pounds per square inch. 5. The tooling system of claim 4 , wherein: the expandable material is configured to generate the internal compaction pressure of at least approximately 85 pounds per square inch for a duration of not less than approximately 60 minutes. 6. The tooling system of claim 1 , wherein: the expandable material is soluble in water or a polar solvent. 7. The tooling system of claim 1 , wherein: at least a portion of the IML tool surface is substantially covered by a polymer layer. 8. The tooling system of claim 1 , further comprising: a gas flow channel included in the OML tool and extending from the OML tool surface to an exterior of the OML tool. 9. The tooling system of claim 8 , further comprising: a vacuum bag sealingly covering at least a portion of the OML tool and fluidly coupling the gas flow channel to a vacuum source. 10. The tooling system of claim 9 , wherein: the vacuum bag sealingly cover seams in the OML tool. 11. The tooling system of claim 9 , further including: a breather layer included underneath the vacuum bag to provide a continuous path for air, gas, and volatiles. 12. The tooling system of claim 1 , wherein: the OML tool includes a pressure vent for venting a tool interior of the OML tool. 13. The tooling system of claim 1 , further comprising: a locating feature for indexing at least one of the composite assembly and the IML tool relative to the OML tool. 14. The tooling system of claim 1 , wherein: the composite assembly has a three-dimensional configuration. 15. The tooling system of claim 1 , further comprising: one or more thermal sensors mounted to at least one of the OML tool and the IML tool. 16. The tooling system of claim 1 , wherein: the IML, tool contains at least one reinforcing member extending at least partially through the IML tool. 17. The tooling system of claim 1 , wherein: the IML tool includes a hollow internal shell positioned within the IML, tool. 18. The tooling system of claim 17 , wherein: the internal shell forms at least a portion of the IML surface of the IML tool. 19. The tooling system of claim 1 , wherein: the OML tool is comprised of at least two OML tool halves mateable to one another and collectively defining the OML tool surface for encapsulating the IML tool and the composite assembly. 20. A tooling system, comprising: an outer mold line (OML) tool having an OML tool surface; a plurality of inner mold line (IML) tools receivable within the OML tool, each one of the IML, tools having an IML, tool surface and formed at least partially of a homogeneous and substantially rigid expandable material configured to expand when heated to apply an internal compaction pressure to a composite assembly positioned between the OML tool surface and the IML, tool surface when the expandable material is heated, the composite assembly including an internal component; at least one pair of the IML, tools having the internal component interposed therebetween and applying an internal compaction pressure to the internal component upon expansion of the expandable material; and a vacuum bag sealingly covering the IML tool and having one or more pleats configured to accommodate expansion of the expandable material to assist in applying the internal compaction pressure to confined spaces, corners, or relatively small radii in the composite assembly in response to a vacuum pressure drawn on a space between the OML tool surface and the vacuum bag covering the IML tool.