Chuck with automatic jaw adjustment

What is claimed is: 1. A chuck for use with a power driver having a rotatable drive spindle, the chuck comprising: a plurality of jaws disposed at a forward end of the chuck, the jaws defining a jaw opening between the jaws for receiving a working bit; a body, wherein the plurality of jaws are disposed in respective passageways in the body and configured to rotate with the body about a center axis of the chuck; a push plate operably coupled to each of the jaws, wherein the jaws are configured to translate forward in the respective passageways to close the jaw opening in response to the push plate translating axially forward; a jaw spring configured to apply a forward directed force to urge the push plate forward; a sleeve; and a nut having nut teeth configured to be engagable in a helically threaded coupling, the nut being configured to translate axially when the helically threaded coupling is disengaged; wherein the sleeve is configured to cause the nut to rotate in a tightening direction in response to the sleeve being rotated in the tightening direction and the nut being rotationally engaged with the sleeve; and wherein the nut is configured to cause the jaws to translate forward and clamp onto the working bit in response to the nut being rotated in the tightening direction. 2. The chuck of claim 1 , wherein the nut teeth are engaged in the helically threaded coupling with body teeth disposed on the body, and wherein, the nut is operably coupled to the push plate such that rotation of the nut in the tightening direction causes the push plate to translate axially forward thereby causing the jaws to translate forward to clamp the jaws onto the working bit. 3. The chuck of claim 1 , wherein the nut teeth are configured to be engaged in the helically threaded coupling with body teeth disposed on the body in response to rotation of the nut in the tightening direction, wherein the nut further comprises a nut teeth channel extending parallel to the center axis and disposed between groupings of the nut teeth that extend parallel to the center axis, wherein the body further comprises a body teeth channel extending parallel to the center axis and disposed between groupings of the body teeth that extend parallel to the center axis. 4. The chuck of claim 3 , wherein the nut is operably coupled to the push plate; and wherein the jaw spring is configured to apply the forward directed force on the nut to cause the nut and the push plate to translate axially forward when the nut teeth channel is aligned with a grouping of the body teeth and the body teeth channel is aligned with a grouping of the nut teeth. 5. The chuck of claim 1 , further comprising: a ratchet member comprising ratchet teeth, the ratchet member being rotationally coupled with the body such that the ratchet member rotates with the body; and a lock spring pawl operably coupled to the nut such that the lock spring pawl translates axially with the nut and rotates with the nut; wherein the sleeve further comprises an unlock recess; wherein the sleeve is configured to, when the nut is rotationally engaged with the sleeve and the sleeve is rotated in the tightening direction, cause rotation of the nut and the lock spring pawl such that the lock spring pawl moves out of the unlock recess in the sleeve and deflects inward to engage at least one of the ratchet teeth to thereby lock the jaws onto the working bit. 6. The chuck of claim 1 , wherein the nut is configured to translate axially in response to axial translation of the sleeve between a disengaged position and an engaged position; and wherein, in the disengaged position, the nut teeth are disengaged from the jaw teeth to permit the jaws to translate forward and close the jaw opening in response to the forward directed force applied by the jaw spring on the push plate, and wherein, in the engaged position, the nut teeth are engaged with jaw teeth such that rotation of the nut in the tightening direction causes the jaws to translate forward and clamp onto the working bit. 7. The chuck of claim 6 , further comprising a nut spring configured to apply a second forward directed force on the nut to urge the nut into the disengaged position. 8. The chuck of claim 7 , further comprising a guide ring that is operably coupled to the nut and the sleeve, such that when the sleeve is rotated in the tightening direction, the guide ring rotates and, via camming action, causes axial translation of the nut into the engaged position. 9. The chuck of claim 6 , further comprising a nut spring configured to apply a rearward directed force on the nut to urge the nut into the engaged position. 10. The chuck of claim 1 , wherein the nut moves axially with the sleeve. 11. The chuck of claim 1 , wherein the nut has a rigid, continuous ring-shape. 12. A chuck for use with a power driver having a rotatable drive spindle, the chuck comprising: a plurality of jaws disposed at a forward end of the chuck, the jaws defining a jaw opening between the jaws for receiving a working bit; a body, wherein the plurality of jaws are disposed in respective passageways in the body and configured to rotate with the body about a center axis of the chuck; a push plate operably coupled to each of the jaws, wherein the jaws are configured to translate forward in the respective passageways to close the jaw opening in response to the push plate translating axially forward; a jaw spring configured to apply a forward directed force to urge the push plate forward; a sleeve; and a nut having nut teeth configured to be engageable in a helically threaded coupling; wherein the sleeve is configured to cause the nut to rotate in a tightening direction in response to the sleeve being rotated in the tightening direction and the nut being rotationally engaged with the sleeve; wherein the nut is configured to cause the jaws to translate forward and clamp onto the working bit in response to the nut being rotated in the tightening direction; and wherein the sleeve nests within a dust cover, and the sleeve is configured to translate axially relative to the dust cover. 13. The chuck of claim 1 , wherein each jaw operably couples to the push plate via a respective push plate slot. 14. The chuck of claim 13 , wherein each jaw is configured to move within the respective push plate slot to change a size of the jaw opening. 15. A chuck for use with a power driver having a rotatable drive spindle, the chuck comprising: a plurality of jaws disposed at a forward end of the chuck, the jaws defining a jaw opening between the jaws for receiving a working bit, each jaw comprising jaw teeth; a body, wherein the plurality of jaws are disposed in respective passageways in the body and configured to rotate with the body about a center axis of the chuck; a push plate operably coupled to each of the jaws, wherein the jaws are configured to translate forward in the respective passageways of the body to close the jaw opening in response to the push plate translating axially forward; a jaw spring configured to apply a forward directed force to urge the push plate forward; and a nut having nut teeth, the nut being configured to translate axially between a disengaged position where the nut is not engaged with the plurality of jaws and an engaged position where the nut is engaged with the plurality of jaws; wherein, in the disengaged position, the nut teeth are disengaged from the jaw teeth to permit the jaws to translate forward and close the jaw opening in response to the forward directed force applied by the jaw spring on the push plate, and wherein, in the engaged position, t