Clutched vacuum pump system

The invention claimed is: 1. A vacuum generating assembly, comprising: a rotary input member connectable to an engine rotary power takeoff; a vacuum pump having a rotor that is rotatable to generate a vacuum; a wrap spring clutch coupling the rotary input member and the vacuum pump rotor, wherein the wrap spring clutch is positionable in an engaged position, in which the wrap spring clutch operatively connects the rotary input member and the vacuum pump rotor, and a disengaged position, in which the wrap spring clutch operatively disconnects the rotary input member and the vacuum pump rotor; and a vacuum actuator including a vacuum actuator housing, a movable separation wall in the vacuum actuator housing, and an actuator rod that mechanically operatively connects the movable separation wall to a brake, wherein the housing is connectable to a vacuum conduit, wherein the brake is connectable to a clutch control member that is operatively connected to the wrap spring clutch, wherein the movable separation wall is movable, based on air pressure in the vacuum conduit, to move the vacuum actuator between a low-pressure position in which the actuator rod moves the brake to position the wrap spring clutch in the disengaged position, and a high-pressure position in which the actuator rod moves the brake to position the wrap spring clutch in the engaged position, and wherein the brake is biased to a non-braking position. 2. An assembly according to claim 1 , wherein the wrap spring clutch is biased towards the engaged position. 3. An assembly according to claim 1 , wherein the rotary power take-off is a camshaft. 4. An assembly according to claim 1 , further comprising: the clutch control member connected to the wrap spring clutch; and wherein the brake is positionable in a non-braking position in which the brake permits the clutch control member to be driven by the rotary power takeoff, thereby permitting the wrap spring clutch to remain in the engaged position, and in a braking position in which the brake retards rotation of the clutch control member relative to the rotary power takeoff, bringing the wrap spring clutch to the disengaged position, wherein movement of the vacuum actuator to the low-pressure position positions the brake in the non-braking position, and movement of the vacuum actuator to the high-pressure position positions the brake in the braking position. 5. An assembly according to claim 4 , wherein the brake includes a leadscrew and a crank connected to rotate the leadscrew, wherein the vacuum actuator rotates the crank through a selected arc. 6. An assembly according to claim 4 , including means for providing the assembly with setpoint hysteresis. 7. An assembly according to claim 6 , wherein the hysteresis means is provided by provisioning a lobe on the clutch control member which interacts with the brake. 8. An assembly according to claim 6 , wherein the hysteresis means is provided by a bistable spring band which interacts with the brake. 9. An assembly according to claim 6 , including a vacuum conduit connecting the vacuum actuator to a vacuum reservoir, wherein the hysteresis means is provided by installing a restrictor and a check valve in parallel in the vacuum conduit. 10. An assembly according to claim 1 , including means for limiting transfer of torque from the rotary power take-off to the vacuum pump rotor. 11. An assembly according to claim 10 , where the torque-limiting means is provided by a helical coil disposed between the wrap spring clutch and the vacuum rotor, wherein the helical coil is preloaded onto a rotor shaft and applying a torque to an end of the helical coil greater than the preload amount causes the helical coil to slip relative to the rotor shaft. 12. A pump assembly, comprising: a rotary input member connectable to an engine rotary power takeoff; a pump having a rotor that is rotatable to generate suction; a clutch coupling the rotary input member and the pump rotor, wherein the clutch is positionable in an engaged position, in which the clutch operatively connects the rotary input member and the pump rotor, and a disengaged position, in which the clutch operatively disconnects the rotary input member and the pump rotor; and an actuator operatively connected to the clutch, wherein the actuator is movable, between a first position in which the actuator positions the clutch in the disengaged position, and a second position in which the actuator positions the clutch in the engaged position; means for providing the assembly with setpoint hysteresis; and a torque limiting clutch that limits torque transfer to the rotor when the clutch operatively connects the rotary input member to the rotor. 13. An assembly according to claim 12 , wherein the rotary power take-off is a camshaft and the clutch is a wrap spring clutch biased towards the engaged position, and further including a clutch control member that holds an end of the wrap spring clutch, and a brake that is positionable in a non-braking position in which the brake permits the clutch control member to be driven by the camshaft, thereby permitting the wrap spring clutch to remain in the engaged position, and in a braking position in which the brake retards rotation of the clutch control member relative to the camshaft, bringing the wrap spring clutch to the disengaged position, wherein the brake includes a leadscrew and a crank connected to rotate the leadscrew, wherein the actuator rotates the crank through a selected arc. 14. An assembly according to claim 13 , including a driver that transfers torque between the camshaft and the rotor, wherein the driver includes a first driver portion and a second driver portion, wherein the torque limiting clutch is the wrap spring clutch having at least one coil having a first helical end, and wherein the first driver portion has a torque limiting clutch engagement surface thereon that extends radially and axially and that engages the first helical end, and wherein the torque limiting clutch has a radially inner or outer surface that is engaged with a complementary radially inner or outer surface on the second driver portion with a selected preload and wherein increasing torque transfer to the first helical end of the torque limiting clutch drives movement of the first helical end in a direction that reduces the preload until the radially inner or outer surface slips on the complementary radially inner or outer surface. 15. A method of operating a vacuum system with an internal combustion engine, wherein the vacuum system includes an engine intake manifold connected to a vacuum reservoir, an oil-supplied vacuum pump having a rotor and which is connected to the vacuum reservoir, and a clutch connected between a rotary power take-off of the engine and the vacuum pump for selectively turning-on and turning-off of the vacuum pump, the method comprising: operating the engine to generate vacuum via the intake manifold; engaging the clutch to turn on the vacuum pump when the pressure in a vacuum conduit is above a first pressure setpoint; disengaging the clutch to turn off the vacuum pump when the pressure in the vacuum conduit is below a second pressure setpoint that is different than the first pressure setpoint; and limiting torque applied to the vacuum pump by the rotary power take-off when the clutch is engaged by transferring torque to the vacuum pump through a torque limiting clutch, wherein the vacuum system includes a driver that transfers torque between the rotary power take-off and the rotor, wherein the driver includes a first driver portion and a second driver portion tha