A traction-drive system that in one embodiment comprises an idler rotatable about a longitudinal axis, a plurality of rotatable and generally disc-shaped planet rollers each having an inner contact surface, a case contact surface and an idler contact surface, the inner contact surface being of a fir
A traction-drive system that in one embodiment comprises an idler rotatable about a longitudinal axis, a plurality of rotatable and generally disc-shaped planet rollers each having an inner contact surface, a case contact surface and an idler contact surface, the inner contact surface being of a first diameter, the case contact surface being of a second diameter, and the idler contact surface being of a third diameter, the planet rollers distributed about the idler and each planet roller contacting the idler at its respective idler contact surface. The traction drive system of this embodiment also comprises an inner ring rotatable about the longitudinal axis adapted to contact the inner contact surface of each of the planet rollers, and a case ring adapted to contact the case contact surface of each of the planet rollers. In some embodiments, the inner contact surface of each roller only contacts the inner ring, the case contact surface of each roller only contacts the case ring and the idler contact surface of each roller only contacts the idler.
대표청구항▼
What is claimed is: 1. A traction-drive system, comprising: a generally tubular idler rotatable about a longitudinal axis; a plurality of rotatable and generally disc-shaped planet rollers each having a first contact surface, a second contact surface and a third contact surface, the first contact s
What is claimed is: 1. A traction-drive system, comprising: a generally tubular idler rotatable about a longitudinal axis; a plurality of rotatable and generally disc-shaped planet rollers each having a first contact surface, a second contact surface and a third contact surface, the first contact surface being of a first diameter, the second contact surface being of a second diameter, and the third contact surface being of a third diameter, the planet rollers distributed about the idler and each planet roller contacting the idler at its respective third contact surface, wherein the first, second, and third diameters are all different sizes from each other; an inner ring rotatable about the longitudinal axis and in contact with the first contact surface of each of the planet rollers; and a case ring in contact with the second contact surface of each of the planet rollers. 2. The fraction-drive system of claim 1, wherein the first contact surface of each roller only contacts the inner ring, wherein the second contact surface of each roller only contacts the case ring and wherein the third contact surface of each roller only contacts the idler. 3. The fraction-drive system of claim 1, wherein the first contact surface comprises an inner contact surface. 4. The fraction-drive system of claim 1, wherein the second contact surface comprises a case contact surface. 5. The fraction-drive system of claim 1, wherein the third contact surface comprises a idler contact surface. 6. The fraction-drive system of claim 1, wherein each of the planet rollers is configured to rotate about a generally cylindrical axle that forms a planet axis that is generally parallel to the longitudinal axis, and wherein the first contact surface of each planet roller is angled with respect to its respective planet axis. 7. The fraction-drive system of claim 6, wherein the second contact surface of each planet roller is angled with respect to its respective planet axis. 8. The fraction-drive system of claim 7, wherein the third contact surface of each planet roller is generally parallel to its planet axis. 9. The fraction-drive system of claim 8, further comprising an axial force generator. 10. The traction-drive system of claim 9, wherein the axial force generator comprises: a ramp disc positioned adjacent to the inner ring on a side opposite from the planet rollers and configured to rotate about the longitudinal axis and that has a first side facing the planet rollers and a second side facing away from the planet rollers; a set of ramps distributed about the radially outward edge of the first side of the ramp disc; and a set of ramp bearings, each ramp bearing located between the ramp disc and the inner ring and configured to ride along a respective one of the set of ramps, wherein the set of ramps and the ramp bearings cooperate to convert torque input to the ramp disc into torque and axial force that are both transferred to the inner ring. 11. The traction-drive system of claim 9, wherein the axial force generator comprises at least one spring. 12. The traction-drive system of claim 11, wherein the at least one spring further comprises a Bellville spring. 13. The traction-drive system of claim 1, wherein the case ring is attached to a generally tubular case that at least partially surrounds the remaining components of the traction-drive system. 14. The traction-drive system of claim 13, wherein the case is stationary and does not rotate. 15. A planetary traction-drive system operating about a longitudinal axis, comprising: a generally tubular idler positioned coaxially about the longitudinal axis; a plurality of generally disc-shaped planet rollers distributed about and in contact with the idler, the planet rollers distributed in a plane that is orthogonal to the longitudinal axis, and the planet rollers each rotating about a respective planet axis; an inner ring positioned coaxially about the longitudinal axis and that contacts each of the planet rollers; a tubular case positioned coaxially about the longitudinal axis that at least partially encloses and surrounds the idler, the inner ring and the planet rollers, and that has a case ring on its inner surface that contacts each of the planet rollers; wherein for at least one operating condition the inner ring has a rotational speed about the longitudinal axis that is different from a rotational speed of the case ring about the longitudinal axis; and wherein each of the planet axes are parallel to the longitudinal axis. 16. The planetary traction-drive system of claim 15, wherein the inner ring contacts each of the planet rollers at a first radius from the longitudinal axis, the case ring contacts each of the planet rollers at a second radius from the longitudinal axis, and the idler contacts each of the planet rollers at a third radius from the longitudinal axis. 17. The planetary traction-drive system of claim 16, wherein the first radius, the second radius and the third radius are all different. 18. The planetary traction-drive system of claim 17, wherein the first radius is less than the second radius. 19. The planetary traction-drive system of claim 18, further comprising a cage configured to maintain an axial alignment and radial position of the planet axes. 20. The planetary traction-drive system of claim 19, further comprising a case cap that engages with the case to partially enclose the cage, idler, planet rollers and the inner ring. 21. The planetary fraction-drive system of claim 20, further comprising an axial force generator. 22. The planetary traction-drive system of claim 21, wherein the planet rollers are generally positioned axially between the inner ring and the case ring and wherein the axial force generator comprises: a ramp disc positioned adjacent to the inner ring on a side opposite from the planet rollers and between the inner ring and the case cap, the case ring configured to rotate about the longitudinal axis and having a first side facing the inner ring and a second side facing the case cap; a set of ramps distributed about the radially outward edge of the first side of the ramp disc; and a set of ramps distributed about the radially outward edge of the first side of the ramp disc; and a set of ramp bearings positioned axially between the ramp disc and the inner ring, each of the set of ramp bearings configured to ride along a respective ramp, wherein the set of ramps and the ramp bearings cooperate to convert torque input to the ramp disc into torque and axial force that are both transferred to the inner ring. 23. A method of transmitting rotational energy, comprising: supplying input torque along a longitudinal axis to a ramp disc configured to convert torque into a torque component and a force component; converting the input torque into a rotational torque component and an axial contact force component; transmitting the rotational torque component and the contact force component to an inner ring; distributing the rotational torque component from the inner ring to a plurality of planet rollers via a first contact surface of each of the planet rollers; and distributing a rotational torque from each planet roller to a surrounding case via a second contact surface of each of the planet rollers and to a central idler via a third contact surface of each of the planet rollers, wherein the contact force component aids with the transmission and distribution of the rotational torque. 24. The method of claim 23, wherein the planet rollers contact a stationary case at their respective second contact surfaces and are allowed to orbit the longitudinal axis such that all of the rotational torque of each planet roller is transmitted via its third contact surface.
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