Power actuator with self disengaging clutch unit

What is claimed is: 1. A power actuator, comprising: a housing; an electric motor supported by said housing, said electric motor having a drive shaft extending along an axis with a screw fixed to said drive shaft for rotation about said axis in response to energization of said electric motor; a clutch plate having a clutch face and being configured for selective rotation; a nut disposed about said screw, said nut having an end face and being configured for selective translation along said screw in response to rotation of said screw, said nut being caused to translate along said screw in response to rotation of said screw when said end face of said nut and said clutch face of said clutch plate are out of driving relation with one another, said nut being caused to rotate conjointly with said screw upon said end face of said nut and said clutch face of said clutch plate being brought into driving relation with one another; and a driven member operably coupled with said clutch plate when said end face of said nut and said clutch face of said clutch plate are brought into driving relation with one another and when said screw rotates about said axis in response to energization of said electric motor. 2. The power actuator of claim 1 , further comprising: a biasing member imparting a bias between said nut and said clutch plate, said bias tending to space said end face out of driving engagement with said clutch face; and a carrier member supported by said housing in coupled relation with said nut, said carrier member imparting a torsional bias on said nut sufficient to cause selective relative rotation between said nut and said screw to cause said nut to translate along said screw in response to rotation of said screw when said end face of said nut and said clutch face of said clutch plate are biased out of driving relation with one another, said torsional bias being overcome upon said end face of said nut and said clutch face of said clutch plate being brought into driving relation with one another, thereby allowing said nut and said carrier member to rotate conjointly with said screw. 3. The power actuator of claim 2 , further including a rotary damper member configured to impart a torsional bias on said carrier member, said torsional bias fixing said carrier member and said nut against rotation with said screw when said end face of said nut and said clutch face of said clutch plate are biased out of driving relation with one another and allowing said carrier member and said nut to rotate with said screw when said end face of said nut and said clutch face of said clutch plate are in driving relation with one another. 4. The power actuator of claim 3 , wherein said rotary damper member includes one of a spring member configured to impart a frictional bias on an outer surface of said carrier member, and a damper gear member configured in meshed engagement with a carrier gear member fixed to said carrier member. 5. The power actuator of claim 2 , wherein one of said nut and said clutch plate has at least one drive lug and the other of said nut and said clutch plate has at least one recessed channel configured for sliding receipt of said at least one drive lug, said at least one drive lug being configured to translate within said at least one recessed channel when said electric motor is energized and when said end face of said nut and said clutch face of said clutch plate are biased out of driving relation with one another and to prevent relative rotation between said carrier member and said nut when said end face of said nut and said clutch face of said clutch plate are in driving relation with one another. 6. The power actuator of claim 1 , wherein said end face of said nut and said clutch face of said clutch plate are maintained in driving relation with one another when electrical energy is supplied to said electric motor. 7. The power actuator of claim 1 , wherein said driven member is operably coupled to said clutch plate to be driven in response to rotation of said clutch plate by a gear assembly. 8. The power actuator of claim 7 , wherein said clutch plate is fixed to an output shaft having a worm gear configured in meshed engagement with said gear assembly. 9. The power actuator of claim 8 , wherein said drive shaft of said electric motor is configured to rotate relative to said output shaft when said end face of said nut and said clutch face of said clutch plate are biased out of driving relation with one another. 10. The power actuator of claim 8 , wherein said drive shaft of said electric motor and said output shaft are configured to co-rotate with one another when said end face of said nut and said clutch face of said clutch plate are in driving relation with one another. 11. The power actuator of claim 1 , wherein said clutch plate and said driven member are fixed to one another. 12. The power actuator of claim 11 , wherein said clutch plate and said driven member are supported by said drive shaft of said electric motor wherein said drive shaft is configured to rotate relative to said clutch plate and said driven member when said end face of said nut and said clutch face of said clutch plate are biased out of driving relation with one another. 13. The power actuator of claim 11 , wherein said clutch plate and said driven member are supported by said drive shaft of said electric motor wherein said clutch plate and said driven member are configured to co-rotate with said drive shaft when said end face of said nut and said clutch face of said clutch plate are in driving relation with one another. 14. The power actuator of claim 1 , further including at least one of a cable and rod configured to operably couple said driven member with a latch. 15. A clutch assembly, comprising: a housing; a screw for rotation about an axis; a clutch plate having a clutch face and being configured for selective rotation; a nut disposed about said screw, said nut having an end face and being configured for selective translation along said screw in response to rotation of said screw, said nut being caused to translate along said screw in response to rotation of said screw when said end face of said nut and said clutch face of said clutch plate are out of driving relation with one another, said nut being caused to rotate conjointly with said screw upon said end face of said nut and said clutch face of said clutch plate being brought into driving relation with one another; and a driven member operably coupled with said clutch plate when said end face of said nut and said clutch face of said clutch plate are brought into driving relation with one another and when said screw rotates about said axis. 16. The clutch assembly of claim 15 , further comprising: a biasing member imparting a bias between said nut and said clutch plate, said bias tending to space said end face out of driving engagement with said clutch face; and a carrier member supported by said housing in coupled relation with said nut, said carrier member imparting a torsional bias on said nut sufficient to cause selective relative rotation between said nut and said screw to cause said nut to translate along said screw in response to rotation of said screw when said end face of said nut and said clutch face of said clutch plate are biased out of driving relation with one another, said torsional bias being overcome upon said end face of said nut and said clutch face of said clutch plate being brought into driving relation with one another, thereby allowing said nut and said carrier member to rotate conjointly with said screw. 17. The clutc