Torsional vibration absorption system

The invention claimed is: 1. A system for absorbing vibration and transmitting torque from a rotating power source to a rotatable load, the system comprising: a cam plate having an inner periphery defining a first cam surface, a second cam surface circumferentially spaced from the first cam surface, and a shoulder separating the first and second cam surfaces, the cam plate being configured to be rotatable about an axis of rotation with one of the power source or the load; and first and second springs configured to extend lengthwise at least partially in a radial direction relative to the axis of rotation and operatively engage the first and second cam surfaces, respectively, the first and second springs being rotatable with the other of the power source or the load, the shoulder being configured to operatively engage the first and/or second springs to thereby restrict rotation of the first and second springs relative to the cam plate, wherein the first and second springs are configured to be compressed due to the first and second cam surfaces during relative rotation of the power source and the load, the first and second springs having an effective spring rate dependent upon the first and second cam surfaces, and compression of the first and second springs absorbing torsional vibration of the power source. 2. The system of claim 1 , wherein the first and second cam surfaces are configured such that the effective spring rate is linear over a predetermined range of angular rotation of the cam plate relative to the first and second springs. 3. The system of claim 1 , wherein the first and second cam surfaces are configured such that the effective spring rate has: a first value over a first range of angular rotation of the cam plate relative to the first and second springs, a second value over a second range of angular rotation of the cam plate relative to the first and second springs subsequent to the first range of angular rotation, and a third value over a third range of angular rotation of the cam plate relative to the first and second springs subsequent to the second range of angular rotation. 4. The system of claim 3 , wherein the second value is less than at least one of the first value and the third value. 5. The system of claim 1 , further comprising first and second roller elements operatively connected to respective ends of the first and second springs and configured to roll along the first and second cam surfaces, respectively, during rotation of the cam plate about the axis of rotation relative to the first and second springs. 6. The system of claim 5 , further comprising: first and second spring housings rotatable with the other of the power source or the load, the first and second spring housings each forming a respective cavity housing therein one of the first and second springs; and first and second blocks disposed between the first and second roller elements and the first and second springs, respectively, wherein the first and second blocks are configured to interface with the first and second spring housings, respectively, to react a component of force of the first and second cam surfaces on the first and second roller elements that is perpendicular to the radial direction. 7. The system of claim 6 , wherein the ends of the first and second springs to which the first and second roller elements are operatively connected are radially outer ends of the first and second springs, and wherein each of the first and second springs has a radially inner end configured to interface with the respective spring housing. 8. The system of claim 1 , further comprising: a third spring spaced angularly about the axis of rotation from the first spring and configured to extend lengthwise at least partially in a radial direction relative to the axis of rotation and rotatable with the other of the power source or the load, wherein the third spring is configured to be compressed due to the third cam surface during rotation of cam plate about the axis of rotation relative to the third spring to absorb torsional vibration of the power source, the third spring having an effective spring rate dependent upon the third cam surface; and wherein the first spring is substantially identical to the second and third springs, and the first cam surface is substantially identical to the second and third cam surfaces such that the effective spring rate of the first spring is substantially identical to the effective spring rate of the second and third springs. 9. The system of claim 1 , wherein the first and second cam surfaces are configured such that the effective spring rate has: a first value over a first range of angular rotation of the cam plate relative to the first and second springs, and a second value over a second range of angular rotation of the cam plate relative to the first and second springs in a direction of rotation opposite from the first range of angular rotation. 10. The system of claim 1 , further comprising: a rotatable driving member configured to be driven by an output member of the power source to rotate about the axis of rotation; and a rotatable driven member configured to be driven by the driving member via a fluid coupling to rotate about the axis of rotation and transmit torque to an input member of the load, wherein the cam plate is operatively connected to one of the driving member or the driven member for rotation in unison with the one of the driving member or the driven member, and wherein the first and second springs are operatively connected to rotate in unison with the other of the driving member or the driven member. 11. The system of claim 10 , further comprising a clutch selectively engageable to drivingly connect the driving member to the driven member via the cam plate and the springs, thereby providing a torque path from the power source to the load, when the clutch is engaged, that bypasses the fluid coupling. 12. The system of claim 11 , further comprising a cover portion configured to rotate with the driven member, wherein the clutch includes a friction plate splined to the cam plate, and an apply plate that moves axially to engage the friction plate with the cover portion. 13. The system of claim 11 , further comprising an electronic controller operatively connected to the clutch and configured to command engagement of the clutch under one or more predetermined operating conditions. 14. The system of claim 1 , wherein the shoulder includes a rectilinear surface projecting radially inward from the inner periphery of the cam plate. 15. A torque converter assembly for absorbing vibration and transmitting torque from an engine output member to a transmission input member, the torque converter assembly comprising: a pump portion configured to be driven by the engine output member to rotate about an axis of rotation; a turbine portion configured to be driven by the pump portion via a fluid coupling between the pump portion and the turbine portion, to rotate about the axis of rotation and transmit torque from the engine output member to the transmission input member; a cam plate with an inner periphery defining a first cam surface, a second cam surface circumferentially spaced from the first cam surface, and a shoulder separating the first and second cam surfaces, the cam plate being configured to be operatively connectable to the pump portion to rotate in unison with the pump portion; and first and second springs configured to extend lengthwise at least partially in a radial direction relative to the axis of rotation and operatively engage the first and second cam surfaces, respecti