Damper device

What is claimed is: 1. A damper device for a vehicle transmitting a torque from a drive source to an output side therethrough, the damper device comprising: an input-side rotor; an output-side rotor rotatable relative to the input-side rotor; a damper part adapted to elastically couple the input-side rotor and the output-side rotor in a rotational direction; a first friction mechanism adapted to generate a first hysteresis torque in relative rotation between the input-side rotor and the output-side rotor; and a friction control mechanism adapted to control actuation of the first friction mechanism, wherein in a positive-side torsional region in which the torque is transmitted from the drive source, when the relative rotation is performed until reaching a maximum torsion angle from a neutral position without the relative rotation, the friction control mechanism deactivates the first friction mechanism until the relative rotation reaches a first torsion angle from the neutral position, the friction control mechanism activating the first friction mechanism until the relative rotation reaches the maximum torsion angle from the first torsion angle, and when the relative rotation is performed until reaching the neutral position from the maximum torsion angle, the friction control mechanism deactivates the first friction mechanism until the relative rotation reaches a second torsion angle less than the first torsion angle from the maximum torsion angle, the friction control mechanism activating the first friction mechanism until the relative rotation reaches the neutral position from the second torsion angle. 2. The damper device according to claim 1 , wherein a deactivation angular range from the neutral position to the first torsion angle and a deactivation angular range from the maximum torsion angle to the second torsion angle are equal in magnitude. 3. The damper device according to claim 2 , wherein each of the deactivation angular ranges is wider than each of an activation angular range from the first torsion angle to the maximum torsion angle and an activation angular range from the second torsion angle to the neutral position. 4. The damper device according to claim 2 , wherein the friction control mechanism deactivates the first friction mechanism within a range that fluctuations in the torque transmitted from the drive source correspond to the deactivation angular ranges in an entire angular range between the neutral position and the maximum torsion angle. 5. The damper device according to claim 1 , further comprising: a second friction mechanism adapted to generate a second hysteresis torque less than the first hysteresis torque in an entire angular range in which the relative rotation between the input-side rotor and the output-side rotor is performed. 6. The damper device according to claim 1 , wherein in a negative-side torsional region in which a torque is transmitted from the output side, when the relative rotation is performed until reaching a maximum torsion angle from the neutral position, the friction control mechanism deactivates the first friction mechanism until the relative rotation reaches a third torsion angle from the neutral position, the friction control mechanism activating the first friction mechanism until the relative rotation reaches the maximum torsion angle from the third torsion angle, and when the relative rotation is performed until reaching the neutral position from the maximum torsion angle, the friction control mechanism deactivates the first friction mechanism until the relative rotation reaches a fourth torsion angle greater than the third torsion angle from the maximum torsion angle, the friction control mechanism activating the first friction mechanism until the relative rotation reaches the neutral position from the fourth torsion angle. 7. The damper device according to claim 1 , wherein the drive source is an engine, and an electric motor for starting the engine and driving the vehicle is disposed on the output side. 8. The damper device according to claim 1 , wherein the input-side rotor includes a first plate and a second plate, the first and second plates disposed in axial opposition to each other at a predetermined interval, the first and second plates fixed to each other so as to be axially immovable from each other and be non-rotatable relative to each other, the output-side rotor includes a flange, the flange being disposed to be interposed between the first and second plates, and the first friction mechanism is disposed axially between the flange and at least one of the first and second plates. 9. The damper device according to claim 1 , wherein the first friction mechanism includes a friction plate rotated together with the output-side rotor within a predetermined angular range, the friction plate capable of making contact by friction with the input-side rotor, and an urging member adapted to cause the friction plate and the input-side rotor to be pressed in contact with each other. 10. The damper device according to claim 9 , wherein the friction control mechanism includes a cutout provided in one of the output-side rotor and the friction plate, the cutout extending within a predetermined angular range in a circumferential direction, and a contact portion provided in the other of the output-side rotor and the friction plate, the contact portion disposed in the cutout at a predetermined gap therefrom, and the friction plate is rotatable relative to the output-side rotor within a range of the predetermined gap. 11. A damper device for a vehicle transmitting a torque from a drive source to an output side therethrough, the damper device comprising: an input-side rotor; an output-side rotor rotatable relative to the input-side rotor; a contact member attached to the input-side rotor; a damper part adapted to elastically couple the input-side rotor and the output-side rotor in a rotational direction; and a friction mechanism adapted to generate a hysteresis torque in relative rotation between the input-side rotor and the output-side rotor, wherein the friction mechanism includes a first friction mechanism and a second friction mechanism, the second friction mechanism adapted to generate a second hysteresis torque, the first friction mechanism generating a first hysteresis torque greater than the second hysteresis torque, in a positive-side torsional region in which the torque is transmitted from the drive source, the second friction mechanism generates the second hysteresis torque within a first angular range in which the relative rotation is performed until reaching a first torsion angle from a neutral position without the relative rotation, and in the positive-side torsional region, the first friction mechanism generates the first hysteresis torque greater than the second hysteresis torque in a state where the first friction mechanism contacts the contact member and the second friction mechanism contacts the input-side rotor within a second angular range in which the relative rotation is performed until reaching a maximum torsion angle from the first torsion angle, the second angular range narrower than the first angular range. 12. The damper device according to claim 11 , wherein in a negative-side torsional region in which a torque is transmitted from the output side, the second friction mechanism generates the second hysteresis torque within a third angular range in which the relative rotation is performed until reaching a third torsion angle from the neutral position, and in the negative-side torsional region in which the torque is transmitted from the output side, the first friction mec