Rotation transmission device

What is claimed is: 1. A rotation transmission device comprising: an input shaft extending in an axial direction, an output shaft arranged coaxial with the input shaft, a two-way clutch configured to selectively transmit torque 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 includes: an outer ring at an end of the output shaft and having an end surface at an opening of the outer ring; an inner ring at an end of the input shaft; a control retainer including a first annular flange and first bars on a surface of the first annular flange at an outer peripheral portion of the first annular flange; a rotary retainer including a second annular flange and second bars on a surface of the second annular flange at an outer peripheral portion of the second annular flange, the first bars and second bars being disposed between an inner periphery of the outer ring and an outer periphery of the inner ring and arranged such that the first bars circumferentially alternate with respective second bars such that pockets are defined between each pair of adjacent first bars and second bars, the first annular flange facing the end surface of the outer ring in the axial direction, and the second annular flange being disposed between the first annular flange and the electromagnetic clutch in the axial direction; a plurality of pairs of engaging elements, each pair of the engaging elements being mounted 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 mounted in the respective pockets and configured to bias the respective pairs of engaging elements away from each other, wherein the electromagnetic clutch comprises an armature coupled to the control retainer, a rotor facing the armature in the axial direction, and an electromagnet facing the rotor in the axial direction and configured to attract the armature against the rotor, thereby moving the control retainer in the axial direction toward the rotor, upon energization of the electromagnet, wherein the two-way clutch further comprises a motion converter mechanism comprising a torque cam configured to convert the axial movement of the control retainer toward the rotor to relative rotation between the control retainer and the rotary retainer in a direction in which circumferential widths of the pockets decrease so as to allow the engaging elements to disengage from the inner periphery of the outer ring, and wherein the rotation transmission device further comprises an anti-rotation arrangement including surface engagement elements disposed directly between the end surface of the outer ring and the first annular flange of the control retainer and configured to prevent relative rotation between the outer ring and the control retainer while the electromagnet is de-energized and the two-way clutch is engaged. 2. The rotation transmission device of claim 1 , wherein the anti-rotation arrangement comprises protrusions formed on one of the end surface of the outer ring and an opposed surface of the first annular flange facing the end surface of the outer ring, and recesses formed in the other of the end surface and the opposed surface, wherein each of the recesses has two circumferentially opposed end surfaces, and wherein the protrusions and the recesses are configured such that when the protrusions are received in at least one of the recesses, at least two of the protrusions can engage two of the end surfaces of the recesses, thereby preventing relative rotation between the outer ring and the control retainer. 3. The rotation transmission device of claim 2 , wherein the recesses are circumferentially elongated, circular arc-shaped recesses, and wherein a quantity of the recesses is larger than a quantity of the protrusions. 4. The rotation transmission device of claim 2 , wherein the protrusions are directly formed on one of the end surface of the outer ring and the first annular flange of the control retainer, and wherein recesses are directly formed in the other of the end surface of the outer ring and the first annular flange of the control retainer. 5. The rotation transmission device of claim 2 , wherein the protrusions are formed on one of two rings fixedly fitted on the end surface of the outer ring and the first annular flange of the control retainer, respectively, and wherein the recesses are formed in the other of the two rings. 6. The rotation transmission device of claim 2 , wherein the torque cam includes opposed pairs of cam grooves formed in respective opposed surfaces of the first annular flange of the control retainer and the second annular flange of the rotary retainer, wherein each of the cam grooves is deepest at a circumferential center of the cam groove, and a depth of the cam groove gradually decreases toward respective circumferential ends of the cam groove, and balls mounted between the respective opposed pairs of cam grooves, whereby the torque cam is configured to rotate the control retainer and the rotary retainer relative to each other in the direction in which the circumferential widths of the pockets decrease when the control retainer is moved in the axial direction toward the rotor, wherein each of the protrusions of the anti-rotation arrangement has a leading end surface and a trailing end surface with respect to a normal rotational direction of the outer ring, wherein the trailing end surface and one of the two end surfaces of each of the recesses for facing the trailing end surface are tapered surfaces, and wherein inclination angles of the respective tapered surfaces with respect to the end surface of the outer ring are smaller than inclination angles of the respective cam grooves with respect to the end surface of the outer ring. 7. The rotation transmission device of claim 6 , wherein each of the respective cam grooves has a hardened surface layer higher in hardness than an internal portion of the respective cam groove, and wherein the hardened surface layer is formed by subjecting only surfaces of the cam grooves to heat treatment. 8. The rotation transmission device of claim 7 , wherein a depth of the hardened surface layer of each of the cam grooves is within a range of 0.3 mm to 0.8 mm. 9. The rotation transmission device of claim 1 , wherein the anti-rotation arrangement comprises a pin on one of the end surface of the outer ring and an opposed surface of the first annular flange facing the end surface, and a pin hole formed in the other of the end surface and the opposed surface such that the pin is engageable in the pin hole. 10. The rotation transmission device of claim 1 , wherein the anti-rotation arrangement comprises friction members fixed to the end surface of the outer ring and a surface of the first annular flange facing the end surface, respectively. 11. The rotation transmission device of claim 1 , wherein the anti-rotation arrangement comprises rough surfaces formed on the end surface of the outer ring and a surface of the first annular flange facing the end surface, respectively. 12. The rotation transmission device of claim 1 , wherein the control retainer has a weight reducing hole or recess in at least one of a radially outer surface and a side surface of the control retainer. 13. The rotation transmission device of claim 1 , wherein the control retainer and the rotary retainer are arranged such that only the first bars of the control retainer and the second bars of the rotary retainer are disposed between the inner ring and the outer ring, with the first ann