High performance disc brake rotor

The invention claimed is: 1. A method for making a disc brake rotor for a vehicle comprising: forming two separate aluminum ceramic composite friction rings, where each of the friction rings has radially extending projections that are angularly spaced from one another relative to a rotational axis of the disc brake rotor; placing a sand core between the friction rings, wherein the projections of one of the friction plates are angularly aligned with and axially spaced from the projections of the other of the friction plates; injecting an aluminum alloy that fills a space between the friction rings to form an aluminum alloy core, the core forming a mechanical interlock with the projections provided on the respective friction rings; and shaking out the sand core, wherein a resulting product is the aluminum alloy core having the friction plated secured thereto, wherein forming the core includes forming a hat-shaped section having a generally cylindrical wall, an annular first mounting plate for securement one of the friction plates, and an annular second mounting plate axially spaced from and connected to the first mounting plate for securement of the other of the friction plates, wherein forming the core further includes forming radially extending fins in a space defined by the first and second mounting plates, the fins are angularly spaced from one another relative to the rotational axis, are angularly spaced from each of the aligned projections relative to the rotational axis, and directly interconnect the first and second mounting plates, and further including positioning each of the aligned projections between immediately adjacent fins. 2. The method of claim 1 , including positioning at least two fins between adjacent aligned projections. 3. The method of claim 1 , including forming radially extending slots on the first mounting plate for receiving the projections of the friction plate secured thereto, wherein each of the slots includes closed first and second ends. 4. The method of claim 3 , including forming radially extending slots on the second mounting plate for receiving the projections of the friction plate secured thereto, wherein each of the slots includes a closed first end and an open second end. 5. The method of claim 1 , including spacing the first and second mounting plates from one another so that a portion of each projection of the respective friction plates is located in a space defined by the first and second mounting plates and has an axial dimension less than half an axial dimension of the space. 6. The method of claim 1 , including forming each of the projections of the frictions plates substantially T-shaped in cross-section. 7. A method for making a disc brake rotor comprising: forming two separate aluminum ceramic composite friction rings, where each of the friction rings has radially extending projections that are angularly spaced from one another relative to a rotational axis of the disc brake rotor; placing a sand core between the friction rings; injecting an aluminum alloy that fills a space between the friction rings to form an aluminum alloy core, the core formed with axially spaced annular mounting plates and radially extending fins located in a space defined by the mounting plates for directly interconnecting the mounting plate, each of the mounting plates forming a mechanical interlock with the projections provided on the respective friction rings, and the mounting plates are spaced from one another so that a portion of each projection of the respective friction plates is located in the space defined by the mounting plates and has an axial dimension less than half an axial dimension of the space; and shaking out the sand core, wherein a resulting product is the aluminum alloy core having the friction plated secured thereto. 8. The method of claim 7 , including positioning the friction plates so that the projections of one of the friction plates are angularly aligned with and axially spaced from the projections of the other of the friction plates. 9. The method of claim 8 , including positioning at least two fins between adjacent aligned projections of the respective friction plates. 10. The method of claim 7 , including forming radially extending slots on one of the mounting plates for receiving the projections of the friction plate secured thereto, wherein each of the slots includes closed first and second ends. 11. The method of claim 10 , including forming radially extending slots on the other of the mounting plates for receiving the projections of the friction plate secured thereto, wherein each of the slots includes a closed first end and an open second end.