Air stream mixing inner diameter (ID) cavity

The invention claimed is: 1. A method of mixing cooling air within an inner diameter (ID) mixing chamber of a turbine exhaust case (TEC), the method comprising: directing pressurized airflow into the ID mixing chamber; directing cooling airflow radially inward via a tube through the TEC; and expelling the cooling airflow from the tube into the ID mixing chamber in a circumferential direction for mixing with the pressurized airflow, wherein the cooling airflow is expelled into the ID mixing chamber only in a circumferential direction that is the same as a direction of windage created in the ID mixing chamber by rotating components associated with the TEC. 2. The method of claim 1 , wherein the tube includes one or more slots for directing cooling airflow into the ID mixing chamber. 3. The method of claim 1 , wherein the circumferential direction of the expelled cooling airflow is perpendicular to the radially inward direction the cooling airflow is directed within the tube. 4. The method of claim 1 , wherein the cooling airflow and pressurized airflow is mixed in a proportion selected to meet outflow margin requirements. 5. A turbine exhaust case (TEC) comprising: a frame portion that includes an outer ring, an inner ring disposed radially inward of the outer ring, and a plurality of hollow struts connecting the outer ring to the inner ring, wherein an inner diameter (ID) cavity is formed between the inner ring and a bearing compartment disposed radially inward of the inner ring; a tube located within at least one hollow strut that directs cooling airflow radially inward from outside the TEC to the ID cavity, wherein the tube includes a slot positioned to direct cooling airflow circumferentially into the ID cavity, wherein the cooling airflow is directed only in a circumferential direction that is the same as a direction of windage created in the ID cavity by rotating components associated with the TEC; and a passage located radially inward of the ID cavity that directs pressurized airflow into the ID cavity for mixing with the cooling airflow. 6. The turbine exhaust case of claim 5 wherein the circumferential direction of the cooling airflow expelled from the slot is perpendicular to the radially inward direction the cooling airflow is directed within the tube. 7. The turbine exhaust case of claim 5 , wherein the tube is secured to a bearing assembly. 8. The turbine exhaust case of claim 5 , wherein the pressurized airflow is bleed air from a compressor stage. 9. The turbine exhaust case of claim 5 wherein the ID cavity extends circumferentially around a bearing assembly. 10. The turbine exhaust case of claim 5 , wherein a tube providing cooling airflow is provided in each of the plurality of hollow struts and wherein the plurality of hollow struts are circumferentially spaced from one another. 11. The turbine exhaust case of claim 5 , wherein the slot has a size selected to adjust a proportion of mixing of the cooling airflow with the pressurized airflow to meet outflow requirements. 12. A mixing architecture for a turbine exhaust case, the mixing architecture comprising: a bearing assembly extending circumferentially around a centerline axis; a frame inner ring extending circumferentially around a centerline axis and located radially outward of the bearing assembly; an inner diameter (ID) mixing chamber located between the bearing assembly and the frame inner ring; a passage for providing pressurized airflow to the ID mixing chamber; a tube connected to the bearing assembly for providing cooling airflow radially inward to the ID cavity, wherein the tube includes a slot positioned to expel cooling airflow circumferentially into the ID cavity, wherein the cooling airflow is directed only in circumferential direction that is the same as a direction of windage created in the ID cavity by rotating components associated with the bearing assembly. 13. The mixing architecture of claim 12 , wherein the slot has a size selected to meet desired outflow requirements. 14. The mixing architecture of claim 12 , wherein the circumferential direction of the expelled cooling airflow is perpendicular to the radially inward direction the cooling airflow is directed within the tube. 15. The mixing architecture of claim 12 , wherein the pressurized airflow is bleed air from a compressor stage.