Powertrain interface module

The invention claimed is: 1. A torsional damper assembly for use in a vehicle powertrain, the torsional damper assembly comprising: an input-side damper body rotatable about a rotational axis and having a first ramp arrangement, wherein the first ramp arrangement includes a plurality of input lobes and a plurality of input valleys, wherein each input valley is defined between a corresponding pair of the input lobes; an output-side damper body rotatable about the rotational axis and coupled to an output shaft that extends along the rotational axis, the output-side damper body having a second ramp arrangement that includes a plurality of output lobes and a plurality of output valleys, wherein each output valley is defined between a corresponding pair of the output lobes; and an overload clutch arranged axially around at least a portion of the output-side damper body; wherein the output-side damper body is configured to move axially along the rotational axis between (i) a first engagement position at which a crest of each input lobe of the first ramp arrangement is fully received in a corresponding output valley of the second ramp arrangement and a crest of each output lobe of the second ramp arrangement is fully received in a corresponding input valley of the first ramp arrangement and (ii) a second engagement position at which the crest of each input lobe of the first ramp arrangement is only partially received in the corresponding output valley of the second ramp arrangement and the crest of each output lobe of the second ramp arrangement is only partially received in the corresponding input valley of the first ramp arrangement. 2. The torsional damper assembly of claim 1 , wherein each of the input lobes and each of the output valleys have a complementary shape and wherein each of the output lobes and each of the input valleys have a complementary shape. 3. The torsional damper assembly of claim 1 , wherein the plurality of input lobes includes at least three input lobes and the plurality of output lobes includes at least three output lobes. 4. The torsional damper assembly of claim 1 , wherein each of the input lobes and each of the output lobes define a ramp angle between 35 degrees and 45 degrees. 5. The torsional damper assembly of claim 1 , wherein the output-side damper body is configured to move to the second engagement position in response to a predetermined torque differential between an input and the output shaft. 6. The torsional damper assembly of claim 5 , wherein the second ramp arrangement is configured to move axially away from the first ramp arrangement in response to the predetermined torque differential between the input and the output shaft. 7. The torsional damper assembly of claim 1 , wherein the overload clutch comprises an inner clutch plate and an output clutch plate. 8. The torsional damper assembly of claim 7 , wherein the overload clutch comprises a friction clutch. 9. The torsional damper assembly of claim 7 , wherein the overload clutch is operable between a first mode rotatably coupling the input-side damper body to an input drum of the vehicle powertrain and a second mode permitting a relative rotation of the inner and output clutch plates to decouple the input-side damper body from the input drum of the vehicle powertrain. 10. The torsional damper assembly of claim 9 , wherein the overload clutch further includes a clutch biasing member configured to urge the overload clutch into the first mode. 11. The torsional damper assembly of claim 10 , wherein the clutch biasing member comprises at least one disc spring. 12. The torsional damper assembly of claim 7 , wherein the input-side damper body further includes an inner engagement feature and wherein the outer clutch plate includes an outer engagement feature configured for complementary engagement with the inner engagement feature to rotatably couple the input-side damper body to the outer clutch plate. 13. The torsional damper assembly of claim 12 , wherein the inner clutch plate includes inner splined feature configured for complementary engagement with an outer splined feature of a drive hub of the vehicle powertrain to rotatably couple the inner clutch plate to the drive hub. 14. The torsional damper assembly of claim 1 , wherein the output shaft is integrally formed with the output-side damper body. 15. The torsional damper assembly of claim 1 , wherein the input-side damper body further includes a pilot shaft extending along the rotational axis toward the output-side damper body. 16. The torsional damper assembly of claim 15 , wherein the output-side damper body further includes a pilot bushing and wherein the pilot shaft of the input-side damper body is engaged with the pilot bushing of the output-side damper body, and wherein the pilot shaft of the input-side damper body is engaged with the pilot bushing of the output-side damper body in each of the first engagement position and the second engagement position. 17. The torsional damper assembly of claim 1 , wherein the output-side damper body further defines a pocket located on an opposite side relative to the output lobes, wherein the pocket is configured to receive a damper preload member to urges the output-side damper body into the first engagement position. 18. The torsional damper assembly of claim 1 , wherein the output-side damper body is configured to be received into a bore of an input drum of the vehicle powertrain. 19. A torsional damper assembly for use in a vehicle powertrain, the torsional damper assembly comprising: an input-side damper body rotatable about a rotational axis and having a first ramp arrangement, wherein the first ramp arrangement includes a plurality of input lobes and a plurality of input valleys, wherein each input valley is defined between a corresponding pair of the input lobes; and an output-side damper body rotatable about the rotational axis and coupled to an output shaft that extends along the rotational axis, the output-side damper body having a second ramp arrangement that includes a plurality of output lobes and a plurality of output valleys, wherein each output valley is defined between a corresponding pair of the output lobes, wherein the output-side damper body is configured to move axially along the rotational axis between (i) a first engagement position at which a crest of each input lobe of the first ramp arrangement is fully received in a corresponding output valley of the second ramp arrangement and a crest of each output lobe of the second ramp arrangement is fully received in a corresponding input valley of the first ramp arrangement and (ii) a second engagement position at which the crest of each input lobe of the first ramp arrangement is only partially received in the corresponding output valley of the second ramp arrangement and the crest of each output lobe of the second ramp arrangement is only partially received in the corresponding input valley of the first ramp arrangement, and wherein the input-side damper body further includes a pilot shaft extending along the rotational axis toward the output-side damper body and the output-side damper body further includes a pilot bushing and wherein the pilot shaft of the input-side damper body is engaged with the pilot bushing of the output-side damper body. 20. The torsional damper assembly of claim 19 , wherein the pilot shaft of the input-side damper body is engaged with the pilot bushing of the output-side damper body in each of the first engagement position and the second engageme