Radial vibration dampers for rotating shafts

What is claimed is: 1. A radial vibration damper comprising: a first inertia member and a second inertia member fixedly connected to one another to define an annular channel having a radially facing, open side; a spring damper material seated in the annular channel in axial compression between the first inertia member and the second inertia member; wherein the spring damper material has a compressible portion thereof protruding from the annular channel through the radially facing, open side and the compressible portion is exposed for contact in radial compression against a shaft; wherein the compressible portion exposed for contact in radial compression against the shaft defines a gap separating the shaft a distance apart from the first and second inertia members. 2. The radial vibration damper of claim 1 , further comprising a fastener connecting the first inertia member to the second inertia member. 3. The radial vibration damper of claim 1 , wherein the spring damper material includes a first rib protruding therefrom compressed by contact with the first inertia member and a second rib protruding therefrom compressed by contact with the second inertia member. 4. The radial vibration damper of claim 3 , wherein the first inertia member and the second inertia member each include a groove shaped and sized to receive the first rib and the second rib, respectively, of the spring damper material. 5. The radial vibration damper of claim 3 , wherein the spring damper material includes a main body between the first rib and the second rib that includes a stiffness portion and the compressible portion, wherein the compressible portion is more proximal to the radially facing, open side of the annular channel than the stiffness portion, and the stiffness portion has a higher modulus than the compressible portion. 6. The radial vibration damper of claim 5 , wherein the spring damper material includes a compressible material in at least the first rib, the second rib, and the compressible portion. 7. The radial vibration damper of claim 6 , wherein the compressible material includes one or more of an elastomeric material, a hyperfoam material, and a nylon. 8. The radial vibration damper of claim 7 , wherein the stiffness portion includes one or more of the same materials as the compressible portion. 9. The radial vibration damper of claim 5 , wherein the spring damper material is a monolithic body. 10. The radial vibration damper of claim 1 , wherein the first inertia member and the second inertia member each include an alignment fixture to hold the spring damper material in its position. 11. The radial vibration damper of claim 1 , wherein the spring damper material comprises a main body defined by a first ring of a compressible material in contact with a surface of the shaft and a second ring of a stiffness material seated adjacent to the first ring, a third ring compressed between the main body and the first inertia member, and a fourth ring compressed between the main body and the second inertia member. 12. The radial vibration damper of claim 1 , wherein finite element modeling demonstrates that the radial vibration damper has a first mode of vibration that is radial in shape. 13. The radial vibration damper of claim 12 , wherein finite element modeling demonstrates that the radial vibration damper has a second mode of vibration that is axial. 14. The radial vibration damper of claim 1 , wherein the shaft is hollow and the radial vibration damper is press-fittable inside the shaft with the compressible portion of the spring damper material compressed against an inner surface of the shaft. 15. The radial vibration damper of claim 1 , wherein the radial vibration damper is press-fittable over the shaft with the compressible portion of the spring damper material compressed against an exterior surface of the shaft. 16. A system comprising a shaft having press-fit thereto a radial vibration damper according to claim 1 . 17. A radial vibration damper comprising: a first inertia member and a second inertia member fixedly connected to one another to define an annular channel having a radially facing, open side; a spring damper material seated in the annular channel in axial compression between the first inertia member and the second inertia member; wherein the spring damper material has a compressible portion thereof protruding from the annular channel through the radially facing, open side and the compressible portion is exposed for contact in radial compression against a shaft, the spring damper material defines a gap between the shaft and the first and second inertia members; wherein the spring damper material includes a first rib protruding therefrom compressed by contact with the first inertia member and a second rib protruding therefrom compressed by contact with the second inertia member, and includes a main body between the first rib and the second rib that includes a stiffness portion and the compressible portion; wherein the compressible portion is more proximal to the radially facing, open side of the annular channel, and the stiffness portion is stiffer than the compressible portion. 18. The radial vibration damper of claim 17 , wherein the spring damper material includes a compressible material in at least the first rib, the second rib, and the compressible portion. 19. The radial vibration damper of claim 17 , wherein the spring damper material is a monolithic body. 20. A radial vibration damper comprising: a first inertia member and a second inertia member fixedly connected to one another to define an annular channel having a radially facing, open side; a spring damper material seated in the annular channel in axial compression between the first inertia member and the second inertia member; wherein the spring damper material has a compressible portion thereof protruding from the annular channel through the radially facing, open side and the compressible portion is exposed for contact in radial compression against a shaft, the spring damper material defines a gap between the shaft and the first and second inertia members; wherein the spring damper material comprises a main body defined by a first ring of a compressible material in contact with a surface of the shaft and a second ring of a stiffness material seated adjacent to the first ring, a third ring compressed between the main body and the first inertia member, and a fourth ring compressed between the main body and the second inertia member.