Z-drive shipping lock for storage library robotic assembly

I claim: 1. A locking subsystem of a drive assembly, comprising: a spring-loaded ratchet pawl comprising a portion thereof movable between at least first and second pawl positions, wherein the spring-loaded ratchet pawl ratchet pawl is configured to be disengaged from between adjacent gear teeth of the drive assembly when in the first pawl position to allow rotational movement of the drive assembly in both of first and second opposing rotational directions, wherein the spring-loaded ratchet pawl ratchet pawl is configured to engage between adjacent gear teeth of the drive gear of the drive assembly in the second pawl position to disallow rotational movement of the drive assembly in the first rotational direction and allow rotational movement of the drive assembly in the opposing second rotational direction, wherein the spring-loaded ratchet pawl is in a first state of deflection in the first pawl position, wherein the spring-loaded ratchet pawl is in a second state of deflection in the second pawl position, and wherein the second state of deflection is less than the first state of deflection; a handle movable between at least first and second handle positions; and a cam member rigidly secured to the handle and movable between the first and second handle positions, wherein the cam member urges the spring-loaded ratchet pawl into the first pawl position in the first handle position, and wherein the spring-loaded ratchet pawl moves into the second pawl position in the second handle position. 2. The locking subsystem of claim 1 , wherein the handle comprises a knob that is rotatable about a rotation axis. 3. The locking subsystem of claim 1 , further including: an electric switch movable between at least first and second positions, wherein the cam member moves the electric switch into the second position when the handle is moved into the second handle position, and wherein the electric switch moves into the first position when the handle is moved into the first handle position. 4. The locking subsystem of claim 3 , wherein movement of the electric switch into the second position generates a control signal that is sent to a controller of the drive assembly. 5. The locking subsystem of claim 3 , wherein the cam member comprises first and second opposite portions, wherein the first portion engages the spring-loaded ratchet pawl, and wherein the second portion engages the electric switch. 6. The locking subsystem of claim 5 , wherein engagement between the first portion of the cam member and the spring-loaded ratchet pawl and engagement between the second portion of the cam member and the electric switch are mutually exclusive. 7. The locking subsystem of claim 5 , wherein the cam member includes a first detent that is configured to engage a second detent upon the second portion of the cam member engaging the electric switch. 8. A locking subsystem of a drive assembly, comprising: a spring-loaded ratchet pawl comprising a portion thereof movable between at least first and second pawl positions, wherein the spring-loaded ratchet pawl is configured to be disengaged from between adjacent gear teeth of the drive assembly when in the first pawl position to allow rotational movement of the drive assembly in both of first and second opposing rotational directions, wherein the spring-loaded ratchet pawl ratchet pawl is configured to engage between adjacent gear teeth of the drive gear of the drive assembly in the second pawl position to disallow rotational movement of the drive assembly in the first rotational direction and allow rotational movement of the drive assembly in the opposing second rotational direction; a handle movable between at least first and second handle positions; a cam member rigidly secured to the handle and movable between the first and second handle positions, wherein the cam member urges the spring-loaded ratchet pawl into the first pawl position in the first handle position, and wherein the spring-loaded ratchet pawl moves into the second pawl position in the second handle position; and a transition member rigidly interconnecting the handle and the cam member, wherein the transition member is non-movable relative to the handle and the cam member, and wherein the transition member is configured to travel within a slot to define a range of motion of the handle and cam member.