Axial engagement-controlled variable damper systems and methods

What is claimed is: 1. An axial engagement-controlled variable damper comprising: a rotor assembly coupled to a rotor shaft and disposed about an axis of rotation; a stator, coaxially aligned with, and disposed radially inward of, the rotor assembly; and a flux sleeve, axially movable relative to the rotor assembly between at least a first position and a second position and having a circumferential flange portion disposed radially inward of the rotor assembly and radially outward of the stator, the flux sleeve being configured to alter magnetic coupling between the stator and the rotor assembly in response to being moved axially, the axial-engagement controlled variable damper being configured to generate a first drag torque in response to the flux sleeve being in the first position and a second drag torque in response to the flux sleeve being in the second position. 2. The axial engagement-controlled variable damper of claim 1 , wherein at least one of the first drag torque and the second drag torque is continuously variable. 3. The axial engagement-controlled variable damper of claim 1 , further comprising: an additional flux sleeve being axially movable relative to the rotor assembly and having an additional circumferential flange portion disposed radially inward of the rotor assembly and radially outward of the stator. 4. The axial engagement-controlled variable damper of claim 3 , further comprising at least one flux sleeve actuator configured to move at least one of the flux sleeve and the additional flux sleeve. 5. The axial engagement-controlled variable damper of claim 4 , wherein the at least one flux sleeve actuator comprises a passive actuator. 6. The axial engagement-controlled variable damper of claim 4 , wherein the at least one flux sleeve actuator comprises a hydraulic actuator. 7. The axial engagement-controlled variable damper of claim 6 , further comprising a rotor hub. 8. The axial engagement-controlled variable damper of claim 3 , wherein the stator comprises at least one of a plurality of laminations or a conductive winding. 9. An axial engagement-controlled variable damper comprising: a stator disposed about an axis of rotation; a rotor assembly, coaxially aligned with, and disposed about, the stator, the rotor assembly being axially movable relative to the stator between at least a first position and a second position, the axial engagement-controlled variable damper being configured to generate a first drag torque in response to magnetic coupling between the stator and the rotor assembly when the rotor assembly is in the first position and to generate a second drag torque in response to the rotor assembly being in the second position. 10. The axial engagement-controlled variable damper of claim 9 , wherein the rotor assembly comprises a first rotor portion and a second rotor portion. 11. The axial engagement-controlled variable damper of claim 10 , further comprising at least one rotor actuator. 12. The axial engagement-controlled variable damper of claim 11 , wherein the rotor actuator comprises a passive actuator. 13. The axial engagement-controlled variable damper of claim 11 , wherein the rotor actuator comprises a hydraulic actuator. 14. The axial engagement-controlled variable damper of claim 13 , further comprising a rotor hub. 15. The axial engagement-controlled variable damper of claim 11 , wherein the stator comprises at least one of a plurality of laminations or a conductive winding. 16. A method comprising: moving at least one of a flux sleeve and at least a portion of a rotor assembly between a first position and a second position relative to a stator of an axial engagement-controlled variable damper; and generating a first drag torque in response to the at least one of the flux sleeve and at least a portion of the rotor assembly being in the first position and a second drag torque in response to the at least one of the flux sleeve and at least a portion of the rotor assembly being in the second position; wherein the axial engagement-controlled variable damper being configured to generate the first drag torque and the second drag torque. 17. The method of claim 16 , wherein, in response to the moving increasing axial engagement between the stator and at least a portion of the rotor assembly, the first drag torque is greater than the second drag torque. 18. The method of claim 16 , wherein, in response to the moving decreasing axial engagement between the stator and at least a portion of the rotor assembly, the first drag torque is less than the second drag torque. 19. The method of claim 16 , wherein the axial engagement-controlled variable damper comprises: the rotor assembly coupled to a rotor shaft and disposed about an axis of rotation; a stator, coaxially aligned with, and disposed radially inward of, the rotor assembly; and the flux sleeve, axially movable relative to the rotor assembly between at least the first position and the second position and having a circumferential flange portion disposed radially inward of the rotor assembly and radially outward of the stator, the flux sleeve being configured to alter magnetic coupling between the stator with the rotor assembly in response being moved axially, the axial-engagement controlled variable damper being configured to generate the first drag torque in response to the flux sleeve being in the first position and the second drag torque in response to the flux sleeve being in the second position. 20. The method of claim 16 , wherein the axial engagement-controlled variable damper comprises: a stator disposed about an axis of rotation; the rotor assembly, coaxially aligned with, and disposed about, the stator, the rotor assembly being axially movable relative to the stator between at least the first position and the second position, the axial engagement-controlled variable damper being configured to generate the first drag torque in response to magnetic coupling between the stator and the rotor assembly when the rotor assembly is in the first position and to generate the second drag torque in response to the rotor assembly being in the second position.