Electric phaser coupling method

What is claimed is: 1. A coupling assembly ( 20 , 120 , 220 ) for transmitting torque between a first rotatable shaft ( 54 ) having a longitudinal primary axis to a second rotatable shaft ( 24 ) having a longitudinal secondary axis comprising: a first rotatable member ( 22 , 122 , 222 ) having a plurality of external load-bearing surfaces ( 32 , 132 , 232 ); a second rotatable member ( 26 , 126 , 226 ) defining a cylindrical hub encircling the first rotatable member ( 22 , 122 , 222 ), the second rotatable member ( 26 , 126 , 226 ) having an interior surface ( 28 ) radially spaced outwardly from the load-bearing surfaces ( 32 , 132 , 232 ) of the first rotatable member ( 22 , 122 , 222 ), an interstitial space defined between the plurality of load-bearing surfaces ( 32 , 132 , 232 ) and the interior surface ( 28 , 30 ) providing radial clearances ( 34 , 36 , 134 , 136 , 234 ) between the first rotatable member ( 22 , 122 , 222 ) and the second rotatable member ( 26 , 126 , 226 ) to accommodate axial misalignment and build up of manufacturing and assembly tolerances; and a plurality of springs ( 42 , 142 , 242 ) extending within the interstitial space defined between the first rotatable member ( 22 , 122 , 222 ) and the second rotatable member ( 26 , 126 , 226 ), each of the plurality of springs ( 42 , 142 , 242 ) directly contacting the plurality of external load-bearing surfaces ( 32 , 132 , 232 ) and the interior surface ( 28 ) for transferring rotational torque between the first rotatable member ( 22 , 122 , 222 ) and the second rotatable member ( 26 , 126 , 226 ). 2. The coupling assembly ( 20 ) of claim 1 , wherein the first rotatable member ( 22 ) includes a first end ( 56 ) and a second end ( 58 ), the plurality of load-bearing surfaces ( 32 ) extending axially between the first end ( 56 ) and the second end ( 58 ), the first end ( 56 ) having an enlarged flange with a plurality of radially spaced peripheral surfaces ( 60 ) positioned radially outwardly with respect to the plurality of load-bearing surfaces ( 32 ), the plurality of load-bearing surfaces ( 32 ) defining a first radial clearance ( 34 ) between the interior surface ( 28 ) of the second rotatable member( 26 ) and the first rotatable member ( 22 ), the plurality of radially spaced peripheral surfaces ( 60 ) defining a second radial clearance ( 36 ) smaller than the first radial clearance ( 34 ) between the surface ( 30 ) of the second rotatable member ( 26 ) and the first rotatable member ( 22 ). 3. The coupling assembly ( 20 ) of claim 2 , wherein each of the plurality of springs ( 42 ) further comprises: a leaf spring having a flexible rectangular portion ( 48 , 148 , 248 ), a first contact point ( 46 a ) and a second contact point ( 46 b ), the first contact point ( 46 a ) located at the first end ( 56 ) of the first rotatable member ( 22 ) adjacent the enlarged flange having the plurality of radially spaced peripheral surfaces ( 60 ), the second contact point ( 46 b ) located adjacent the second end ( 58 ) of the first rotatable member ( 22 ), the flexible rectangular portion ( 48 ) of each of the plurality of springs ( 42 ) extending between the first and second contact point ( 46 a , 46 b ). 4. The coupling assembly ( 20 ) of claim 2 further comprising: a retaining ring ( 66 ) secured adjacent the second end ( 58 ) of the first rotatable member ( 22 ) via a plurality of grooves ( 68 ) disposed about a periphery of the second end ( 58 ), the retaining ring ( 66 ) preventing axial movement of the plurality of springs ( 42 ); and a retainer clip ( 70 ) anchoring each of the plurality of springs ( 42 ) to one of the plurality of load-bearing surfaces ( 32 ). 5. The coupling assembly ( 20 ) of claim 1 , wherein the second rotatable member ( 26 ) further comprises: a first interior surface portion ( 28 ) and a second interior surface portion ( 30 ) longitudinally adjacent to one another, the first interior surface portion ( 28 ) complementarily in shape with respect to an enlarged flange portion of the first rotatable member ( 22 ), the second interior surface portion ( 30 ) sheathing an end portion of the second rotatable shaft ( 24 ). 6. The coupling assembly ( 120 ) of claim 1 further comprising: the first rotatable member ( 122 ) having a first inner surface ( 152 a ), a second inner surface ( 152 b ) for receiving the first rotatable shaft ( 54 ); and a plurality of locking members ( 82 ) interposed between the second rotatable member ( 126 ) and the first rotatable member ( 122 ), each of the plurality of locking members ( 82 ) engageable with one of the plurality of load-bearing surfaces ( 132 ). 7. The coupling assembly ( 120 ) of claim 6 further comprising: a central hub ( 84 ) operably associated with the plurality of locking members ( 82 ) and received within the first inner surface ( 152 a ) of the first rotatable member ( 122 ). 8. The coupling assembly ( 120 ) of claim 6 further comprising: a retaining ring ( 66 ) securing each of the plurality of springs ( 142 ) to the corresponding one of the plurality of load-bearing surfaces ( 132 ) at a second contact point ( 146 b ), each of the plurality of springs ( 142 ) cantilevered radially outwardly to support one of the plurality of locking members ( 82 ) with respect to the first rotatable member ( 122 ). 9. In an electrically driven phaser ( 92 ) for varying a phase relationship between a camshaft ( 24 ) driven by a crankshaft of an internal combustion engine, the electrically driven phaser including a gear assembly located between an electric motor and the camshaft ( 24 ) for transferring rotational torque from the electric motor to the camshaft ( 24 ), and a coupling assembly ( 20 , 120 , 220 ) located between the electric motor and the camshaft ( 24 ), the improvement of the coupling assembly ( 20 , 120 , 220 ) comprising: a first rotatable member ( 22 , 122 , 222 ) having a plurality of external load-bearing surfaces ( 32 , 132 , 232 ); a second rotatable member ( 26 , 126 , 226 ) defining a cylindrical hub encircling the first rotatable member ( 22 , 122 , 222 ), the second rotatable member ( 26 , 126 , 226 ) having an interior surface ( 28 , 30 ) radially spaced outwardly from the load-bearing surfaces ( 32 , 132 , 232 ) of the first rotatable member ( 22 , 122 , 222 ), an interstitial space defined between the plurality of load-bearing surfaces ( 32 , 132 , 232 ) and the interior surface ( 28 , 30 ) providing radial clearances ( 34 , 36 , 134 , 136 , 234 ) between the first rotatable member ( 22 , 122 , 222 ) and the second rotatable member ( 26 , 126 , 226 ) to accommodate axial misalignment and build up of manufacturing and assembly tolerances; and a plurality of springs ( 42 , 142 , 242 ) extending within the interstitial space defined between the first rotatable member ( 22 , 122 , 222 ) and the second rotatable member ( 26 , 126 , 226 ), each of the plurality of springs ( 42 , 142 , 242 ) for transferring rotational torque between the first rotatable member ( 22 , 122 , 222 ) and the second rotatable member ( 26 , 126 , 226 ). 10. The improvement of claim 9 , wherein the plurality of springs further comprises: the plurality of springs ( 42 , 142 , 242 ) interposed between the second rotatable member ( 26 , 126 , 226 ) and the first rotatable member ( 22 , 122 , 222 ), each of the plurality of springs ( 42 , 142 , 242 ) having a first contact point ( 46 a , 146 a , 246 a ) and a second contact point ( 46 b , 146 b , 246 b ) and a flexible rectangular portion ( 48 , 148 , 248 )extending between the first and second contact points ( 46 a ,