Drill attachment for cannulated surgical drills

What is claimed is: 1. A quick-release mechanism for a collet, the mechanism comprising: a socket configured to receive the collet in a collet lumen, the socket comprising: a proximal socket flange, and a distal socket flange distal to the proximal socket flange; a socket seater comprising: a socket lumen configured to receive the socket, a socket seater flange disposed between the proximal socket flange and the distal socket flange, and a socket seater stub; a return spring disposed on an exterior surface of the socket seater; and a latching arm in contact with the socket seater stub, the latching arm having a first state, a second state, and a third state. 2. The mechanism of claim 1 , wherein the proximal socket flange extends from an exterior surface of the socket, and wherein the distal socket flange extends from the exterior surface of the socket. 3. The mechanism of claim 1 , wherein the socket seater flange is disposed at a distal end of the socket seater and protrudes at least in part into a space bounded at least in part by the proximal socket flange and the distal socket flange. 4. The mechanism of claim 1 , wherein the socket seater stub protrudes from the exterior surface of the socket seater. 5. The mechanism of claim 1 , wherein the latching arm in the first state is configured to contact a proximal face of the socket seater flange to a distal face of the proximal socket flange, thereby transferring a proximal force to the proximal socket flange, wherein the socket seater flange, when the latching arm is placed in the first state, is configured to move the proximal socket flange in a proximal direction, thereby securing an exterior surface of the collet against an inner surface of the collet lumen; wherein the return spring is compressed when the proximal socket flange is moved in the proximal direction. 6. The mechanism of claim 1 , wherein the latching arm in the second state is configured to position the socket seater flange such that the socket seater flange makes no contact with the proximal socket flange or with the distal socket flange. 7. The mechanism of claim 1 , wherein the latching arm in the third state is configured to contact a distal face of the socket seater flange to a proximal face of the distal socket flange, thereby transferring a distal force to the distal socket flange, wherein the socket seater flange, when the latching arm is placed in the third state, is configured to move the distal socket flange in a distal direction, thereby releasing an exterior surface of the collet from an inner surface of the collet lumen. 8. The mechanism of claim 1 , further comprising: a handle in contact with the latching arm at a first end of the latching arm; and a mechanical switch in contact with the latching arm at a second end of the latching arm. 9. The mechanism of claim 8 , wherein the mechanical switch having a first stable state, a second stable state, a first transitory state, and a second transitory state. 10. The mechanism of claim 9 , wherein the first stable state places the latching arm stably in the second latching arm state, and the second stable state places the latching arm stably in the third latching arm state, and wherein the first transitory state and the second transitory state place the latching arm transiently in the first latching arm state. 11. The mechanism of claim 10 , wherein the distal toothed plate is configured to axially receive a collet in a distal central structure thereof. 12. The mechanism of claim 11 , further comprising a compliant spring disposed around the distal central structure and contacting a distal side of the distal toothed plate on a first compliant spring side and an inner surface of the housing on a second compliant spring side. 13. The mechanism of claim 8 , wherein the mechanical switch comprises a pin and a closed-loop track, wherein the track is configured to receive a first end of the pin, and wherein the latching arm is configured to receive a second end of the pin. 14. The mechanism of claim 13 , wherein the closed-loop track comprises a plurality of track segments, each of the plurality of track segments independently chosen from a straight segment and a curved segment, wherein at least one of the plurality of track segments comprises a rising ramp on which the pin is configured to move in an orthogonal direction to a plane defined by the closed-loop track. 15. The mechanism of claim 13 , further comprising a torsional return spring in contact with a latching arm axle configured to apply a rotational force to the latching arm, and further comprising a leaf spring releasably in contact with at least a portion of a surface of the latching arm and configured to apply a restoring force to the latching arm, wherein the restoring force is greater than the rotational force applied by the torsional return spring to the latching arm through the latching arm axle. 16. The mechanism of claim 1 , wherein the socket further comprises a cable lumen co-axial with the collet lumen. 17. A transmission mechanism, comprising: a housing, a proximal toothed plate disposed within the housing and comprising a body having a distal side comprising a plurality of teeth; a distal toothed plate disposed within the housing and comprising a body having a proximal side comprising a plurality of teeth configurable to engage the plurality of teeth of the proximal toothed plate, wherein: the housing axially constrains the distal toothed plate, each tooth of the proximal toothed plate and each tooth of the distal toothed plate comprises a riser side and a ramp side, a rotation of the proximal toothed plate in a first direction engages the plurality of teeth of the proximal toothed plate with the plurality of teeth of the distal toothed plate, thereby imparting a rotational force to the distal toothed plate, and a rotation of the proximal toothed plate in a second direction disengages the plurality of teeth of the proximal toothed plate from the plurality of teeth of the distal toothed plate and rotationally slides the plurality of teeth of the proximal toothed plate with respect to the plurality of teeth of the distal toothed plate, thereby imparting an axial impact force to the distal toothed plate, a lengthwise adapter having a distal end configured to engage the proximal toothed plate body and impart a rotational motion thereto, a proximal end configured to engage a chuck of a drill, and a hammer spring disposed around an outer surface of the lengthwise adapter and engaging a proximal surface of the proximal toothed plate, the hammer spring being configured to compress when the proximal toothed plate disengages the plurality of teeth of the proximal toothed plate from the plurality of teeth of the distal toothed plate during a rotation in the second direction, and configured to expand to deliver a percussive axial force to the distal toothed plate when the plurality of teeth of the proximal toothed plate re-engages the plurality of teeth of the distal toothed plate. 18. A drill attachment for a bi-directional drill, the attachment comprising: a housing; a lengthwise adapter comprising a proximal end configured to engage a chuck of the bi-directional drill; a transmission mechanism configured to engage a distal end of the lengthwise adapter, comprising: a proximal toothed plate disposed within the housing and comprising a body having a distal side thereof comprising a plurality of teeth, and a distal toothed plate disposed within and axially constrained by the housing and comprising a