Tapered roller drive for electric VCT phaser

What is claimed is: 1. An electric phaser for dynamically adjusting a rotational relationship of a camshaft with respect to a crankshaft of an internal combustion engine, the electric phaser comprising: an electric motor; and a split ring tapered roller drive comprising: a sun driven to rotate around a sun axis by the electric motor, the sun having a sun contact surface having a circular cross section without teeth and tapering with respect to the sun axis; a carrier rotatable around the sun axis; a plurality of rollers arranged around the sun, each roller rotatable on a roller axis at a roller angle with respect to the sun axis, each roller having a roller contact surface without teeth in rolling engagement with the sun contact surface, wherein the rollers are rotatably mounted on the carrier to rotate on the roller axes; a sprocket ring driven by the crankshaft, the sprocket ring having a sprocket ring contact surface without teeth in rolling engagement with the roller contact surfaces and defining a first circular cross sectional interior space; a camshaft ring rotatable with the camshaft, the camshaft ring having a camshaft ring contact surface without teeth in rolling engagement with the roller contact surfaces and defining a second circular cross sectional interior space; and a load generator applying an axial load to maintain the plurality of rollers in rolling engagement with the sun and the ring; wherein the electric motor is driven at a motor speed to dynamically maintain or adjust the rotational relationship of the camshaft with respect to the crankshaft. 2. The electric phaser of claim 1 , wherein the plurality of rollers comprises three rollers. 3. The electric phaser of claim 1 , wherein the load generator is a plurality of disc springs. 4. The electric phaser of claim 1 further comprising a friction oil on the roller contact surfaces reducing slip between the roller contact surfaces and the sun contact surface, the sprocket ring contact surface, and the camshaft ring contact surface. 5. The electric phaser of claim 1 , wherein the roller angle is selected such that transfer of torque between the sun and the rollers, between the rollers and the sprocket ring, and between the rollers and the camshaft ring is optimized. 6. The electric phaser of claim 1 , wherein when a diameter of the sprocket ring contact surface is greater than a diameter of the camshaft ring contact surface: rotation of the sun by the electric motor at a nominal speed nominally faster than a speed of rotation of the camshaft to compensate only for slippage between the rollers and the camshaft ring maintains a current phasing between the camshaft and the crankshaft; rotation of the sun by the electric motor at an advancing speed greater than the nominal speed adjusts the phaser in an advancing direction; and rotation of the sun by the electric motor at a retarding speed less than or in the opposite direction to the nominal speed adjusts the phaser in a retarding direction. 7. The electric phaser of claim 1 , wherein when a diameter of the camshaft ring contact surface is greater than a diameter of the sprocket ring contact surface: rotation of the sun by the electric motor at a nominal speed nominally faster than a speed of rotation of the camshaft to compensate only for slippage between the rollers and the camshaft ring maintains a current phasing between the camshaft and the crankshaft; rotation of the sun by the electric motor at a retarding speed greater than the nominal speed adjusts the phaser in a retarding direction; and rotation of the sun by the electric motor at an advancing speed less than or in the opposite direction to the nominal speed adjusts the phaser in an advancing direction. 8. A method of dynamically adjusting a rotational relationship of a camshaft with respect to a crankshaft of an internal combustion engine using an electric phaser comprising an electric motor; and a split ring tapered roller drive comprising a sun driven to rotate around a sun axis by the electric motor, the sun having a sun contact surface having a circular cross section without teeth and tapering with respect to the sun axis; a carrier rotatable around the sun axis; a plurality of rollers arranged around the sun, each roller rotatable on a roller axis at a roller angle with respect to the sun axis, each roller having a roller contact surface without teeth in rolling engagement with the sun contact surface, wherein the rollers are rotatably mounted on the carrier to rotate on the roller axes; a sprocket ring driven by the crankshaft, the sprocket ring having a sprocket ring contact surface without teeth in rolling engagement with the roller contact surfaces and defining a first circular cross sectional interior space and a camshaft ring rotatable with the camshaft, the camshaft ring having a camshaft ring contact surface without teeth in rolling engagement with the roller contact surfaces and defining a second circular cross sectional interior space, the method comprising: applying an axial load to maintain the sun, the plurality of rollers, and the ring in rolling engagement; and dynamically selecting a motor speed of the electric motor and adjusting the electric motor to the motor speed to dynamically adjust the rotational relationship of the camshaft with respect to the crankshaft. 9. The method of claim 8 , wherein: a diameter of the sprocket ring contact surface is greater than a diameter of the camshaft ring contact surface; rotation of the sun by the electric motor at a nominal speed nominally faster than a speed of rotation of the camshaft to compensate only for slippage between the rollers and the camshaft ring maintains a current phasing between the camshaft and the crankshaft; rotation of the sun by the electric motor at an advancing speed greater than the nominal speed adjusts the phaser in an advancing direction; and rotation of the sun by the electric motor at a retarding speed less than or in the opposite direction to the nominal speed adjusts the phaser in a retarding direction.