Rotation transmission device

What is claimed is: 1. A rotation transmission device comprising an input shaft, an output shaft positioned coaxially with the input shaft, a two-way clutch configured to selectively transmit rotation between the input shaft and the output shaft, and an electromagnetic clutch configured to selectively engage and disengage the two-way clutch, wherein the two-way clutch comprises an outer ring positioned at an end of the output shaft and having an inner periphery, an inner ring positioned at an end of the input shaft and having an outer periphery, a control retainer including first bars, a rotary retainer including second bars, wherein the first bars and the second bars are received between the inner periphery of the outer ring and the outer periphery of the inner ring, and positioned such that the first bars alternate with the second bars in a circumferential direction, with pockets defined between respective adjacent pairs of first and second bars, a plurality of pairs of engaging elements, each pair of the engaging elements being received in one of the pockets so as to be engageable with the inner periphery of the outer ring and the outer periphery of the inner ring, and elastic member, each of the elastic members being received in one of the pockets and being configured to bias the pair of the engaging elements received in the one of the pockets away from each other, wherein the electromagnetic clutch comprises an armature coupled to the control retainer, a rotor spaced apart from, and facing, the armature in an axial direction, and an electromagnet supported by a stationary member so as to face the rotor in the axial direction, and configured to apply a magnetic attraction force to the armature such that the armature is attracted toward the rotor when the electromagnet is energized, wherein the rotation transmission device is configured such that when the electromagnet is energized, the control retainer is moved in the axial direction toward the rotor, together with the armature, and wherein the rotation transmission device further comprises a motion converter mechanism configured to convert the axial movement of the control retainer toward the rotor to a relative rotation between the control retainer and the rotary retainer in a direction in which circumferential widths of the pockets decrease, thereby disengaging the engaging elements, wherein a shock absorbing member for absorbing an impact force when the armature is attracted to the rotor is provided positioned on one of an opposed surface of the armature facing the rotor and an opposed surface of the rotor facing the armature, wherein the shock absorbing member comprises a metal ring comprising an annular plate portion and a cylindrical portion configured at an outer periphery of the annular plate portion, and an elastic protrusion adhesively bonded to an inner surface of the annular plate portion, wherein the shock absorbing member is mounted such that the cylindrical portion is fitted on an outer periphery of the one of the armature and the rotor on which the shock absorbing member is positioned, the annular plate portion faces an axial end surface of an annular recess defined in the one of the opposed surface of the armature facing the rotor and the opposed surface of the rotor facing the armature at an outer peripheral portion of the one of the opposed surface of the armature facing the rotor and the opposed surface of the rotor facing the armature, the elastic protrusion is supported by the axial end surface of the annular recess, and the annular plate portion has an outer surface protruding from the one of the opposed surface of the armature facing the rotor and the opposed surface of the rotor facing the armature, and wherein the elastic protrusion is between the annular plate portion and the axial end surface. 2. A rotation transmission device comprising an input shaft, an output shaft positioned coaxially with the input shaft, a two-way clutch configured to selectively transmit rotation between the input shaft and the output shaft, and an electromagnetic clutch configured to selectively engage and disengage the two-way clutch, wherein the two-way clutch comprises an outer ring positioned at an end of the output shaft and having an inner periphery, an inner ring positioned at an end of the input shaft and having an outer periphery, a control retainer including first bars, a rotary retainer including second bars, wherein the first bars and the second bars are received between the inner periphery of the outer ring and the outer periphery of the inner ring, and positioned such that the first bars alternate with the second bars in a circumferential direction, with pockets defined between respective adjacent pairs of first and second bars, a plurality of pairs of engaging elements, each pair of the engaging elements being received in one of the pockets so as to be engageable with the inner periphery of the outer ring and the outer periphery of the inner ring, and elastic members, each of the elastic members being received in one of the pockets and being configured to bias the pair of the engaging elements received in the one of the pockets away from each other, wherein the electromagnetic clutch comprises an armature coupled to the control retainer, a rotor spaced apart from, and facing, the armature in an axial direction, and an electromagnet supported by a stationary member so as to face the rotor in the axial direction, and configured to apply a magnetic attraction force to the armature such that the armature is attracted toward the rotor when the electromagnet is energized, wherein the rotation transmission device is configured such that when the electromagnet is energized, the control retainer is moved in the axial direction toward the rotor, together with the armature, and wherein the rotation transmission device further comprises a motion converter mechanism configured to convert the axial movement of the control retainer toward the rotor to a relative rotation between the control retainer and the rotary retainer in a direction in which circumferential widths of the pockets decrease, thereby disengaging the engaging elements, wherein a shock absorbing member for absorbing an impact force when the armature is attracted to the rotor is positioned on one of an opposed surface of the armature facing the rotor and an opposed surface of the rotor facing the armature, wherein the shock absorbing member comprises a metal ring comprising an annular plate portion and a cylindrical portion configured at an outer periphery of the annular plate portion, and an elastic protrusion adhesively bonded to an inner surface of the annular plate portion, wherein the shock absorbing member is mounted such that the cylindrical portion is fitted on an outer periphery of the one of the armature and the rotor on which the shock absorbing member is positioned, the annular plate portion faces an axial end surface of an annular recess defined in the one of the opposed surface of the armature facing the rotor and the opposed surface of the rotor facing the armature at an outer peripheral portion of the one of the opposed surface of the armature facing the rotor and the opposed surface of the rotor facing the armature, the elastic protrusion is supported by the axial end surface of the annular recess, and the annular plate portion has an outer surface protruding from the one of the opposed surface of the armature facing the rotor and the opposed surface of the rotor facing the armature, and wherein the cylindrical portion has a radially inner surface configured with a plurality of circumferentially spaced apart projections fitted in an annular groove defined in the outer periphery of the one of the armature and the rotor on which the shock absorbing member is positioned, and in engagement with an end wall of the annular groove on a side of the one of the